Functional study of protective immunity following DNA vaccination
against viral haemorrhagic septicaemia in rainbow trout
Ph.D. thesis by
Dagoberto Sepúlveda Araneda
November 2015
Supervisor: Professor Niels Lorenzen
Table of Contents
1. Preface ................................................................................................. 1
Acknowledgements .................................................................................. 2
List of original manuscripts ...................................................................... 3
List of abbreviations ................................................................................. 4
Summary .................................................................................................. 6
Sammendrag (Danish Summary) .............................................................. 8
2. Part I: Background ............................................................................... 10
2.1 Aquaculture ........................................................................................... 10
2.2 Aquaculture and infectious diseases ......................................................... 10
2.3 Viral diseases in finfish aquaculture .......................................................... 12
2.4 Viral haemorrhagic septicaemia (VHS) ...................................................... 13
2.5 Viral haemorrhagic septicaemia virus (VHSV) ............................................ 14
2.5.1 VHSV- Infectious cycle .................................................................... 15
2.5.2 VHSV: distribution, diversity, and adaptability ................................... 16
2.6 Control of viral diseases in aquaculture ..................................................... 18
2.7 Fish immune system .............................................................................. 19
2.7.1 Innate immunity ............................................................................ 19
2.7.2 Adaptive immunity ......................................................................... 21
2.8 Vaccines against VHSV ........................................................................... 24
2.9 DNA vaccine against VHSV ...................................................................... 26
2.10 In this thesis ....................................................................................... 32
3. Part II: Hypotheses and objectives .............................................. 34
4. Part III: Publications .................................................................... 36
4.1 Manuscript I .......................................................................................... 36
4.2 Manuscript II ......................................................................................... 65
4.3 Manuscript III ........................................................................................ 85
5. Part IV: General discussion and perspectives ............................... 105
5.1 Section I
5.1 Manuscript I ..................................................................................... 106
5.2 Section II
5.2.1 Manuscript II ................................................................................. 107
5.2.2 Manuscript III ................................................................................ 109
6. Concluding remarks..................................................................... 112
7. References .................................................................................. 115
1
1. Preface
This thesis describes the work carried out at the Section of Fish Health, Department of
Animal Science, Aarhus University, under the supervision of the Professor Niels
Lorenzen.
This Ph.D. project was funded by the Chilean National Scholarship Program for
Graduate Studies (Conicyt) and by the European Commission under the 7th
Framework Programme for Research and Technological Development contract
FP7311993, TargetFish.
This thesis is divided into four parts. Background information is described in Part I.
Hypothesis and objectives are presented in Part II. The major studies are described in
Part III, and are presented in three manuscripts. The Discussion and perspectives are
described in Part IV.
2
Acknowledgment
I would like to thank all the people who contributed in some way to the work described
in this thesis.
First of all, I would like to express my sincere gratitude to my supervisor, Professor
Niels Lorenzen, for his guidance, motivation, and fruitful discussions.
I would like to thank Jesper Skou Rasmussen, Helle Kristiansen, Helle Frank Skall,
Ellen Lorenzen, and those who worked in the lab at the beginning of my project, Katja
Einer-Jensen, Brian Dall Schyth, for the useful feedback and insightful comments on
my work.
My sincere thanks to Inge Marie Jepsen, Hanne Møller Purup, Torben Egil Kjær, Lene
Nørskov, Tommy Hejl, Hanne Bucholtz, Lisbeth Kjær Troels for the skillful support and
helpful assistance, without their effort my job would have undoubtedly been more
difficult.
I thank my fellow lab mates Dennis Bela-ong, Sekar Larashati and Niccoló Vendramin,
for the stimulating discussions at work, but also for sharing social activities out of the
lab that made my stay in Denmark a pleasant time.
Last but not least, I thank my parents, sister, and friends for the love, care and
constant encouragement during this thesis and my life in general.
3
List of original manuscripts
Manuscript I
Dagoberto Sepúlveda, Niels Lorenzen
“Can VHS virus bypass the protective immunity induced by DNA vaccination in
rainbow trout?”
Submitted to PLOs One
Manuscript II
Dagoberto Sepúlveda, Ellen Lorenzen, Jesper Skou Rasmussen, Katja Einer-Jensen,
Bertrand Collet, Chris Secombes, Niels Lorenzen
“Time-course study of the immune protection induced by an interferon-
inducible DNA vaccine against viral haemorrhagic septicaemia virus in
rainbow trout”
Intended for submission to Fish and Shell Fish Immunology
Manuscript III
Dagoberto Sepúlveda, Jesper Skou Rasmussen, David Parra, Niels Lorenzen
“Attempt to mimicking antibody-antigen complexes by DNA vaccination in a
fish virus model”
Intended for submission to Fish and Shell Fish Immunology
4
List of abbreviations
ADCC Antibody-dependent cell-mediated cytotoxicity
APC Antigen presenting cells
Bp Base pair
BF2 Bluegill fry cells
cDNA Complementary deoxyribonucleic
CPE Cytopathic effect
CMV Cytomegalovirus
CTL Cytotoxic T lymphocytes
DNA Deoxyribonucleic acid
EAVR Early antiviral responses
ELISA Enzyme-linked immunosorbent assay
EPC Epithelioma papulosum cyprinid cells
Fc Fragment crystallizable region of Immunoglobulins
G Glycoprotein IFN Interferon
GALT Gut-associated lymphoid tissue
ILT Interbranchial lymphoid tissue
I.M Intramuscular
I.P Intraperitoneal
ISG Interferon stimulated genes
ISRE Interferon-stimulated response element
L Large protein, RNA-dependent RNA polymerase
LAVR Long-term antiviral responses
M Matrix protein
MAb Monoclonal Antibody
MEM Eagle’s minimum essential medium
5
MHC Major Histocompatibility complex
mRNA Messenger RNA
N Nucleoprotein
NV Non-virion protein
P Phosphoprotein
PAMP Pathogen-associated molecular pattern
PRR Pattern recognition receptors
RNA Ribonucleic acid
RT-qPCR Quantitative reverse transcription polymerase chain reaction
SAVR Specific antiviral responses
ssRNA Single-stranded RNA
TCID50 Tissue culture infective dose
VHS Viral haemorrhagic septicaemia
Viruses
IHNV Infectious haematopoietic necrosis virus
ISAV Infectious salmon anaemia virus
HIRRV Hirame rhabdovirus
SAV Salmon alphavirus
VHSV Viral haemorrhagic septicaemia virus
6
Summary
Functional studies of protective immunity related to DNA vaccination of rainbow trout
against viral haemorrhagic septicemia (VHS)
This paper addresses some functional and safety aspects associated with DNA
vaccination of farmed fish. Vaccination against infectious diseases using DNA is a
relatively new approach for disease prevention in husbandry animals and humans. The
concept is based on insertion of the gene encoding a protective antigen of a disease-
causing agent into a eukaryotic expression vector, typically, a plasmid with a strong
cytomegalovirus (CMV) promoter. Upon intramuscular injection of purified vaccine
DNA, some cells in the vaccinated animal will take up the plasmid and express the
vaccine antigen. This will activate the animal's immune system. The principle does not
work for all diseases. In this context, it is interesting that DNA vaccination against the
diseases caused by rhabdoviruses in salmonids has been found to be particularly
efficient. This has led to the commercialization of a DNA vaccine for the Atlantic salmon
in Canada.
In Europe, VHS is one of the most important viral diseases in farmed rainbow trout,
and an experimental DNA vaccine based on the genre of the viral surface glycoprotein
(G) has given promising results under laboratory conditions.
The work in this thesis has aimed to clarify the following questions, all of which are
related to the potential use of DNA vaccination to prevent disease in aquaculture:
I: Would VHS virus be able to bypass the protective immunity induced by DNA
vaccination after a few passages in vaccinated fish?
II: Would a DNA vaccine, in which the CMV promoter is replaced by an interferon-
inducible Mx promoter provide improved safety and practical benefits?
III: Could the combination of the Fc domain of the immunoglobulin molecule with the
vaccine antigen in a fusion protein promote the immunogenicity of the antigen?
Despite the fact that RNA viruses such as VHS virus is known to have a high mutation
rate and thus the ability to adapt to new host conditions, the results showed that the
DNA vaccine induced a robust protection which was not bypassed by the virus during
repeated passaging in vaccinated animals. However, although vaccination protected
against the disease, some of the vaccinated fish still got infected following exposure to
7
VHS virus and were capable of transmitting the infection to non-vaccinated cohabitant
fish.
Use of an interferon-inducible trout Mx promoter in the DNA vaccine gave interesting
results both in terms of consumer safety and understanding of the development of
protective immunity. In contrast to the CMV promoter, the trout Mx promoter was not
active in human cells. On the other hand, a variable protective effect was observed in
fish over time, and the results thereby emphasized the importance of examining the
effect of new vaccines over a prolonged period of time.
A range of DNA vaccine constructs were made, encoding Fc-fusion proteins by
combining the constant Fc domain of the trout antibody molecules with the soluble part
of the viral G protein. None of these induced protection, but since the fusion proteins
were also not secreted from transfected cells, it was not possible to finally answer
question III.
The results are presented in the thesis in the form of three manuscripts for publication
in scientific journals.
8
Sammendrag
Funktionelle undersøgelser af beskyttende immunitet i forbindelse med DNA
vaccination af regnbueørreder mod viral haemorrhagisk septikæmi (VHS).
Denne afhandling adresserer nogle af de fundamentale funktionelle og
sikkerhedsmæssige aspekter i forbindelse med DNA vaccination af opdrætsfisk.
Vaccination mod smitsomme sygdomme ved hjælp af DNA er en relativt ny strategi for
sygdomsforebyggelse i husdyr og mennesker. Konceptet bygger på at genet for et
beskyttende antigen fra det sygdomsfremkaldende agens indsættes i en eukaryot
expressions vektor, typisk i form af et plasmid med en stærk promoter fra
cytomegalovirus (CMV). Ved intramuskulær injektion af oprenset DNA vil plasmidet
optages i nogle få af det vaccinerede dyrs celler. Disse vil udtrykke vaccine-antigenet,
som igen vil aktivere dyrets immunsystem. Princippet fungerer dog ikke lige godt for
alle sygdomme. I den sammenhæng er det interessant, at DNA vaccination mod
sygdomme forsaget af rhabdovirus i laksefisk har vist sig at være særdeles effektiv.
Dette har ført til kommercialisering af en DNA vaccine til Atlantisk laks i Canada. I
Europa er VHS en af de vigtigste virussygdomme i opdræt af regnbueørred og en
eksperimentel DNA vaccine baseret på genet for det virale overflade glykoprotein (G)
har givet lovende resultater under laboratorieforhold.
Arbejdet i denne afhandling har søgt at afklare nedenstående spørgsmål, som alle er
relateret til mulighederne for anvendelse af DNA vaccination til sygdomsforebyggelse i
akvakultur:
I: Vil VHS virus være i stand til at omgå den beskyttende immunitet induceret af DNA
vaccination efter få passager i vaccinerede fisk?
II: Vil en DNA vaccine, hvor CMV promotoren er udskiftet med en interferon inducibel
Mx promoter give sikkerheds- og anvendelsesmæssige fordele?
III: Kan kombination af Fc-delen fra immunglobulin molekylet med vaccineantigenet i
et fusionsprotein fremme immunogeniciteten?
På trods af at RNA virus som VHS virus er kendt for at have en høj mutationsfrekvens
og dermed evne til at tilpasse sig nye vilkår, viste resultaterne at DNA vaccination
inducerede en robust beskyttelse, som virus ikke omgik i løbet af få passager i
vaccinerede dyr. Det var dog også klart at selvom vaccinationen beskyttede mod
9
sygdom, blev en del af fiskene alligevel inficerede og dermed i stand til at overføre
infektionen til ikke vaccinerede dyr.
Anvendelse af en interferon-inducibel ørred Mx-promoter i DNA vaccinen gav
interessante resultater både i forhold til forbrugersikkerhed og forståelse af udvikling
af beskyttende immunitet. I modsætning til CMV-promoteren var ørred Mx-promoteren
ikke aktiv i humane celler. Til gengæld varierede den beskyttende effekt i fisk over tid
og resultaterne understregede dermed vigtigheden i at undersøge effekten af nye
vacciner over et længere tidsrum.
Det viste sig at være vanskeligt at få transfekterede celler til at udskille
fusionsproteiner bestående af den konstante Fc-del af antistofmolekyler og G
proteinet. Det var derfor ikke muligt endegyldigt at besvare spørgsmål III.
Phd-projektets resultater er præsenteret i afhandlingen i form af 3 manuskripter til
publikation i videnskabelige tidsskrifter.
10
2. Part I: Background
2.1 Aquaculture
The aquaculture industry has progressively grown for the last two decades, playing an
increasingly important role in a food supply. This expansion is the result of both,
depleting wild fish stocks by overfishing, and increasing demand for seafood by an
expanding world population (FAO 2014). In the 1990’s, the aquaculture industry
provided only 25% of the total fish consumed. In 2012, the aquaculture industry
represented 42% of the total fish consumed, corresponding to 66.6 million tons fish
production (FAO 2014). Projections indicate that aquaculture will keep developing to
become the largest supplier of consumed fish and fish products (Hall 2011).
Developing a sustainable and fast-growing aquaculture industry has required facing
different types of challenges. One is the technical limitations of upgrading fish farms
from extensive low scale production to intensive high scale production(Brudeseth,
Wiulsrød et al. 2013). Another is the environmental impact of introducing exotic fish
species into new farming areas. However, the major challenge that has constantly
threatened the sustainability of the aquaculture industry is infectious diseases (Leung
and Bates 2013).
2.2 Aquaculture and infectious diseases
Infectious diseases are one of the major causes of economic losses in the aquaculture
industry. The negative effects on fish farming can reduce meat quality or cause high
mortality rates, which in some cases reach up to 100% of the production. The impact
of the infectious diseases in some countries has almost shut down the industry within a
short time, generating economic losses and social problems such as the loss of labor
11
because of reduced production (Grischkowsky and Amend 1976; Olesen 1998; Skall,
Olesen et al. 2005; Kibenge, Godoy et al. 2012).
One study that monitored Norwegian farms for over 14 years showed that the annual
average fish loss was 8.6% of the production, of which 85% (7.31% of total
production) was due to fish deaths, most of them caused by pathogens (Dixon 2012).
In 2007 the global market for finfish aquaculture had a value of US$ 20 billion and the
7.31% loss by pathogens was valued at 1.4 billion dollars (Dixon 2012). Therefore,
reducing losses, which includes controlling the outbreaks of infectious diseases, is a
priority for the aquaculture industry.
Aquacultured fish are highly susceptible to infectious diseases because of the
characteristics of fish farms and aquatic environments, which often provide ideal
conditions for the spread of infectious diseases. First, the aquatic environment often
lacks physical barriers to avoid pathogen transmission between farmed fish and wild
fish reservoirs. Moreover, the pathogens are able to survive a long time outside the
host in this environment, which facilitates the spread of pathogens over long distance
by migratory wild fish or sea currents (Meyer 1991; McCallum, Harvell et al. 2003;
Kurath and Winton 2011; Kibenge, Godoy et al. 2012). Second, fish farming has
intrinsic characteristics that promote pathogen outbreaks, and are not present under
wild conditions. Some of these characteristics are: high-density fish stocks of a single
fish species, stress associated with crowding, handling, continuous production. On top
of this geographical movement of cultured fish promotes the introduction of exotic
pathogens (Kurath and Winton 2011; Kibenge, Godoy et al. 2012). Not only do these
conditions promote disease outbreaks in aquaculture, but they may also favor selection
of pathogens with higher virulence, or pathogens with the capacity to infect new hosts.
12
2.3 Viral diseases in finfish aquaculture
Infectious diseases in finfish aquaculture are caused by different types of
microorganisms. Bacteria are the most prevalent causative disease agent in
aquaculture, responsible for 54.4% of all cases, followed by 22.6% for viruses 19.4%
for parasites and 3.1% for fungi (Kibenge, Godoy et al. 2012). Although bacterial
diseases are the most common, it is possible to control most of them effectively by
using antibiotics and vaccines.
On the contrary, viral diseases have been harder to control, mainly due to the high
susceptibility of aquatic animals at early growth stages, lack of antiviral treatments,
low-efficacy of commercial vaccines, and fast viral spreading (Kibenge, Godoy et al.
2012).
Understanding aquaculture sensitivity and the risk to an expanding global trade in
farmed fish and their products, The World Organization of Animal Health (OIE) has
delineated standards and guidelines to control the risks of spreading diseases. One of
these guidelines is to define a list of aquatic animal diseases, which must be reported
to the authorities in order to take proper contingency measures. The selection of the
diseases in the list follows three main criteria;
If the disease can cause significant production losses at a national or
multinational level,
If there is scientific evidence that the disease causes significant morbidity or
mortality in wild aquatic animal populations
If the agent is of public health concern.
Out of the 10 diseases listed, 8 are caused by a viral etiological agent, an indication of
the international concern about the damages that viral diseases can cause. The listed
viral diseases are: the Epizootic haematopoietic necrosis virus (EHNV), the infectious
13
salmon anaemia virus (ISAV), the salmonid alphavirus (SAV), the infectious
haematopoietic necrosis virus (IHNV), the koi herpes virus disease (KHV), the red sea
bream iridoviral disease (RSIV), the spring viremia of carp (SVCV), and the viral
haemorrhagic septicaemia (VHSV) (OIE 2012).
This work will focus on VHSV, one of the most important viral diseases in the world,
and the one of greatest concern in rainbow trout fish farming in Europe (EURL-FISH
2015).
2.4 Viral haemorrhagic septicaemia (VHS)
Viral haemorrhagic septicaemia was confirmed to be caused by a viral etiological agent
in 1963. At that time, the virus was named Egtved virus, taking the name of the
Danish village close to the isolation area. Currently, it is named viral haemorrhagic
septicaemia virus (VHSV) and has been isolated from over 80 fish species in Asia,
North America, and Europe (Skall, Olesen et al. 2005).
VHS has a high impact on aquaculture, affecting economically important fish species,
such as the rainbow trout and turbot in Europe (Ross, McCarthy et al. 1995; Smail and
Snow 2011), and the Japanese flounder and olive flounder in Japan and Korea,
respectively (Schlotfeldt, Ahne et al. 1991; Isshik, Nishizawa et al. 2001; OIE 2012).
The mortalities in an outbreak can reach up to 100% in rainbow trout fry and 30-70%
in adults. Moreover, massive mortalities by VHS have been registered in marine and
freshwater wild fish species in North America, causing environmental disasters
(Lumsden, Morrison et al. 2007; OIE 2012).
VHSV is transmitted horizontally by direct contact with infected fish or with water
containing virions from infected fish. The major entry portals of the virus are the gills,
skin and fin base (Harmache, LeBerre et al. 2006; Brudeseth, Skall et al. 2008; OIE
2012).
14
The VHS has different variants. The acute form is the most common form of the
disease, characterized by clinical signs such as skin darkening, exophthalmia, anaemia,
haemorrhage, and abnormal swimming behavior, often leading to high mortality. The
chronic form is usually a persistent infection in the absence of external clinical signs.
Finally, the nervous form is characterized by infection mainly in the brain tissue,
generating changes in the swimming behavior.
The form of the disease, the clinical signs, and the severity of mortality rates caused
by VHSV depend on several factors such as pathogen-related factors (strain of VHSV,
virus loads), host-related factors (species, growth stage, stress level) and
environmental-related factors (water temperature, oxygen concentration, water
salinity) (Smail and Snow 2011; OIE 2012).
2.5 Viral haemorrhagic septicaemia virus (VHSV)
The viral haemorrhagic septicaemia virus (VHSV), a member of the genus
Novirhabdovirus, belonging to the Rhabdoviridae family. VHSV is an enveloped virus
with the characteristic bullet shape of the rhabdovirus, 100 nm in length and 60 nm
width (Figure 1C). The genome is a single molecule of linear, negative-sense, single-
stranded RNA (ssRNA) of 11,4 kb in size (Walker, Benmansour et al. 2000).
The genome encodes six proteins, five of which are structural proteins, the
nucleoprotein (N), the phosphoprotein (P), the matrix protein (M), the glycoprotein (G)
and the RNA-dependent RNA polymerase (L). VHSV and other Novirhabdovirus
genomes further encode a non-structural protein denominated NV (Figure 1A-B). The
function of NV protein is not completely understood, but it has been associated with
apoptosis control in infected cells (Ammayappan and Vakharia 2011). The NV gene is
absent in the classical mammalian rhabdoviruses like vesicular stomatitis virus (VSV)
15
and rabies virus (RV) (Fig. 1) and it might be speculated that the NV protein somehow
reflects adaptation to poikilothermic animal hosts.
Figure 1. Genomic organization of (A) VHSV, and (B) Rabies virus. (C) VHSV
particle. Images from viral zone web page (www.viralzone.expasy.org)
2.5.1 VHSV infection cycle
When VHSV enters the host, the glycoprotein of the virion recognizes and attaches to a
host receptor on the plasma membrane (Bearzotti, Delmas et al. 1999), and enters
into the host cell by receptor-mediated endocytosis (Liu, Liu et al. 2011). Later, a pH-
dependent fusion of the viral envelope with the vesicle membrane releases the viral
ribonucleocapside (RNP), consisting of the genomic (-)ssRNA, N, L, and P into the
cytoplasm, where transcription and replication take place. The transcription of the
messenger RNAs from the genomic viral (-)ssRNA is carried out by a complex of the
RNA-dependent RNA polymerase (L) and the phosphoprotein (P). The same complex is
A
B
C
16
responsible for the post-transcriptional processing of the mRNA (capping and
polyadenylation) (Maclachlan and Dubovi 2010).
The VHVS genomic RNA only has one promoter, which is located at the 3’ end of the
genome. The viral RNA polymerase attaches to this promoter and moves along the
genome in the 3’ to 5’ direction. The six mRNAs are generated by a mechanism called
Attenuated Transcription or Stop-Start Transcription. Briefly, after transcribing the first
gene, the polymerase reaches the stop/start signal in the intergenic region, and a
fraction of the polymerases moves to the next gene to continue the transcription, while
another fraction of the polymerases fall off and attaches to the promoter to start again.
The result of this process is a higher transcription of the genes located at the 3’ end
(close to the promoter), reducing the transcription level gradually, according to the
position in the genome N>P>M>G>NV>L.
The next step in the viral cycle is the translation of the viral mRNAs by the host
machinery. When high levels of N and P are accumulated in the cytoplasm, the RNA
polymerase switches from synthesizing mRNA to synthesizing the antigenome, which is
later used as a template for the synthesis of the new genomic RNA. The nucleoprotein
attaches to the newly formed genomic RNA to form RNP, which, along with M protein,
binds the transmembrane glycoproteins inserted in the plasma membrane. The last
step of the cycle is the shedding that occurs when the virions are formed by the
budding of new virus particles from the plasma membrane (Maclachlan and Dubovi
2010).
2.5.2 VHSV: distribution, diversity, and adaptability
RNA viruses, and thus VHSV, have a characteristic high genetic variability, which is an
advantage for rapid adaptation to environmental or host changes. The capacity for
high variability is due to high replication rates, a large population size, and elevated
17
mutation rates due to the absence in most RNA viruses of a proofreading activity in
RNA polymerases (Manrubia and Lázaro 2006). To compare, while a vertebrate host
genome has a mutation rate of 1x10-9 substitution per site per year (sub/site/year),
the VHSV genome has a mutation rate of 2,58 x 10-4 sub/site/year (Holmes 2009;
Pierce and Stepien 2012). According to the quasispecies theory, the variability of RNA
viruses rapidly generates a heterogeneous virus population in the infected organisms.
This population consists of a dominant genome and a very diverse spectrum of low-
frequency viral genomes. The frequency of one of these viral genomes can change in
response to a shift in the environmental conditions or a shift to a new host (Manrubia
and Lázaro 2006; Domingo, Sheldon et al. 2012).
A demonstration of this principle is the capacity of certain viruses to generate escape
mutants under selective pressure, such as the immune protection induced by a vaccine
or the inhibition of the viral replication by antiviral drugs. Influenza A virus and human
respiratory syncytial virus are able to generate escape mutants to neutralizing
antibodies in embryonated chicken eggs and cell culture, respectively (Lambkin,
McLain et al. 1994; Tomé, Frabasile et al. 2012). However, retroviruses, such as the
human and simian immunodeficiency virus (HIV and SIV), have shown a high capacity
to escape the protection induced by vaccination and the effect of antiviral drugs
(Barouch, Kunstman et al. 2002; Barouch, Kunstman et al. 2003; Adetokunboh,
Atibioke et al. 2015). Therefore, the variability of RNA viruses must be taken into
account in the design, testing, and application of either vaccines or antiviral drugs.
Evidence for the high adaptation capacity of VHSV is shown by its distribution in
diverse environmental conditions (marine water, freshwater, and different
temperatures) and its ability to infect over 80 fish species. Phylogenetic analyses have
divided VHSV in four genotypes (I-IV). Genotype I is subdivided into Ia – Ie, and
together with genotype II and III were found in European freshwater and northern
18
European marine environments. Genotype IV is subdivided into IVa – IVc, which were
found in the Great Lakes in North America, Japan, Korea, and the west coast of
Canada and USA (Pierce and Stepien 2012). VHSV was recently declared eradicated
from the freshwater environment in Denmark (Olesen, Skall et al.). However, the virus
is still present in the marine environment, and although marine isolates of VHSV are
not- or low-virulent to rainbow trout, recent outbreaks have occurred in sea reared
rainbow trout in other Scandinavian countries (Dale, Orpetveit et al. 2009). The
potential risk of the emergence of a new high virulent variant is therefore constant and
requires disease control programs to have to be strictly applied and updated
continually.
2.6 Control of viral diseases in aquaculture
The constant growth of the aquaculture industry requires establishing of programs to
control the impact of fish diseases and to reduce the associated economic losses of the
industry. These programs include surveillance measures to detect the pathogens at
early stages of infection, avoiding spread of the diseases, management of infected fish
(quarantine, killing infected fish, fallowing periods) and prophylactic measures
(vaccination, probiotic, immunostimulant) (Kibenge, Godoy et al. 2012).
Even though all measures play a significant role in the disease control program, the
application of vaccines was a turning point in the development and expansion of the
aquaculture industry. The first vaccines commercially available were against the
bacterial enteric redmouth disease (ERM, yersiniosis) and vibriosis in the USA in 1976,
while the first anti-viral vaccine was against spring viremia carp in 1982 (Evelyn
1996). Although vaccines since then have been successful tools for controlling many
bacterial diseases in aquaculture and reducing the needs for antibiotic treatments
(Midtlyng, Grave et al. 2011), the outcome of attempts to develop and implement
19
vaccines against viral diseases has not been similarly promising. On major challenge is
that traditional vaccines based on killed virus usually are too expensive to produce to
be cost-efficient for use in aquacultured fish. And while many veterinary vaccines
against viral diseases in husbandry animals are based on attenuated virus, authorities
have been hesitating to allow use of live viral vaccines in the aquatic environment,
where environmental safety issues are often hard to predict. The way forward thus
seems to be development of recombinant subunit vaccines. However, the design of
such vaccines has appeared to require a better understanding of how the antiviral
immune mechanisms in fish can be efficiently activated and long lasting immunity
established.
2.7 Fish Immune system
Fish, as well as mammals, possess the two classical arms of the high vertebrate
immune system, the innate and the adaptive immunity. However, because of the
evolutionary distance between the fish and mammal immune system, there are some
structural and functional differences.
2.7.1 Innate immunity
Innate immunity in all vertebrates and invertebrates has the same fundamental
characteristics: quickly induced after infection, not specific to an antigen, and the
molecules involved in this immunity are encoded by germ-line genes. Some of the
components of the innate immunity that play an important role in the defense against
viral infection are outlined below:
The physical barriers are the first line of defense against pathogens, blocking
their entry into the organism. Skin, gut, and gill in combination with the
secretion of mucus are the main components of the physical barriers (Ángeles
20
Esteban 2012). The mucus contains lysozymes, proteases, cathepsin B, alkaline
phosphatase, and antimicrobial peptides, providing different strategies to
defend the organisms from a broad range of pathogens (Collet 2014).
Complement System. In higher vertebrates, the classical, mannan-binding
lectin (MBL), and the alternative complement pathway have been associated
with antiviral responses. In salmonid, the complement system has also been
involved in the fish defense against viruses. For instance, after salmon
alphavirus (SAV) infection, components of the classical pathway were up-
regulated (Desvignes, Quentel et al. 2002). Another example involves the VHSV
neutralization by fish serum in vitro, which is a complement-dependent process
(Olesen and Jørgensen 1986).
Cellular components such as Macrophages, Neutrophils, and Natural Killer-like
cells, among other immune cells, play two roles in the immune responses. First,
destroying directly pathogens or infected cells. Second, these cells can trigger
the activation of the adaptive immunity by processing the antigens, along with
producing cytokines and other soluble factors (Collet 2014).
Pattern Recognition Receptors (PRRs) are cellular receptors specialized in
recognizing the pathogen-associated molecular pattern (PAMPs), such as
lipopolysaccharides (LPS), flagellins and peptidoglycan in bacteria, or DNA CpG
motif, dsRNA, and glycoprotein in viruses. Toll-like receptors and RIG-like
helicases are essential PRRs for detection of viral components such as
intermediates of the virus replication in fish. The activation of these receptors
leads to the activation or synthesis of antiviral protein, inflammatory cytokines,
and chemokines (Workenhe, Rise et al. 2010).
Interferons (IFNs) are cytokines induced by the recognition of viral components
by PRRs. Fish and mammals IFN type I appears to induce similar activation
pathways. IFNs play an important role activating an antiviral status in infected
21
and in neighboring cells, inducing the up-regulation of the IFN-stimulated genes
(ISG), which are effector antiviral proteins such as protein kinase R (PKR), Vig-
1, ISG15, and Myxovirus resistance protein (Mx) (Workenhe, Rise et al. 2010;
Collet 2014).
Even though most components of the innate immunity in fish have homologous in
mammals, fish often have multiple isoforms of innate immune molecules such as
complement proteins and C-reactive proteins, and thereby showing a higher diversity
in the innate immune response than the one found in mammals (Magnadottir 2010).
This possibly reflects that innate protective mechanisms play a more important role in
fish, particularly at low temperatures, at which activation of adaptive mechanisms
takes longer time.
2.7.2 Adaptive immunity
The second arm of the vertebrate immune system is the adaptive immunity. The
adaptive immunity in both mammals and fish is characterized by: acting on a specific
antigen, requiring a longer activation time than the innate immunity, inducing long-
lasting protection, and eliciting an enhanced response to a second exposure to the
pathogen (immunological memory). It is important to take into account that the
temperature affects physiological processes in fish such as metabolism and the
immune responses in general, however, the adaptive immunity appears to be more
sensitive to this factor, compared to the innate immunity. A study in channel catfish
showed that at low temperature, the antigen processing and presentation was
impaired, causing a down-regulation of responses of helper T cells, and cytotoxic T
cells, generating a low antibody production (Vallejo, Miller et al. 1991). Therefore,
considering that the fish farms are located in different geographic areas, the
22
temperature might have a huge impact on the adaptive responses induced by
vaccination.
One major difference between mammals and fish is the organs involved in the
production and maturation of immune cells. In mammals, the production of red blood
cells, platelets and white blood cells (B and T lymphocytes, macrophages) occurs in the
bone marrow, while the antigen presentation and lymphocyte maturation take place in
the lymph nodes. Fish lack bone marrow, lymph nodes, germinal centers and mucosal-
associated lymphoid tissue (MALT) (Tort, Balasch et al. 2003). Instead, the major
lymphoid organs in fish are the head kidney, the thymus, and the spleen. The head
kidney is a primary lymphoid organ analogous to the bone marrow. The head kidney is
where all stages of maturation of B cell occurs, and the production antibodies take
place. Other regions of the kidney also possess some immunological functions (K2-K5
in figure 2). The thymus is another primary organ and has been associated with the
maturation of T cells. The spleen, a secondary lymphoid organ, is where the antigen
presentation occurs and thereby the place where the adaptive responses are initiated.
Additionally, two secondary lymphoid organs have been identified in fish, the
interbranchial lymphoid tissue (ILT) (Haugarvoll, Bjerkås et al. 2008; Koppang, Fischer
et al. 2010), and the gut-associated lymphoid tissue (GALT), the latter contains
intraepithelial T and B lymphocytes within the gut lamina propia (Figure 2) (Zapata,
Diez et al. 2006; Salinas, Zhang et al. 2011).
Figure 2. Location of lymphoid organs in teleost. Taken from (Kibenge, Godoy et al.
2012).
23
The adaptive immunity in fish, as well in mammals, can be divided into cellular and
humoral responses:
Cellular immunity. Fish immune system involves different types of cells that can
detect, internalize, process and present dangerous molecules on the Major
Histocompatibility Complex (MHC), activating multiple immune mechanisms. Due to
the blurry borders between the innate and adaptive immunity, some of these cells play
an essential role in both, the innate and adaptive immunity. Cells involved in the
adaptive immunity are (i) Cytotoxic T lymphocytes (CTL), which through cell-mediated
cytotoxicity kill cells infected by intracellular pathogens, which present antigens on
MHC I. (ii) Helper T cells, which activation is mediated by the internalization and
presentation of the exogenous antigen on the MHC II of macrophages, dendritic cells
or B-cells. Helper T cells are important for further activation of the humoral immunity.
Although, the main cellular components of the adaptive immunity in mammals are also
present in fish, the full characterization of these cell populations in fish is still limited
compared mammals (Fischer, Koppang et al. 2013).
Humoral immunity. As in mammals, the B-lymphocytes in fish or rather their
developed stage called plasma cells are responsible for the production of antibodies. It
has been identified that fish produce three immunoglobulin isotypes IgM, IgD, and IgT,
while mammals produce IgM, IgE, IgA, IgD, and IgG.
- IgM is the most prevalent antibody isotype in fish, and can be found as a
membrane-bound form and as a tetrameric secreted form. IgM is associated
with systemic functions, involving complement fixation, agglutination, binding
mannose, binding lectin, signaling cellular cytotoxicity (Kibenge, Godoy et al.
2012).
- IgD functions in both, fish and mammals, are not clear yet. In mammals, IgD
has been associated with some ancient function of surveillance and
24
inflammation, linking the innate and the adaptive immunities (Ma, Ye et al.
2013; Ye, Kaattari et al. 2013).
- IgT has been associated with the mucosal defense, which involves the combat
of parasitic infections. An analysis of surviving fish following a parasitic infection
showed a high titer of IgT parasite-specific in the gut, while very low
concentration in the serum. On the contrary, the same fish had a low titer of
IgM parasite-specific in the gut and high titer in the serum (Zhang, Salinas et
al. 2010).
Affinity maturation and immunological memory are two mechanisms that are better
developed in mammals than in fish. In mammals, low-affinity IgM changes to high-
affinity IgG in a process designated as class switching, which is absent in fish.
However, fish antibodies do pass through an affinity maturation process, but the
magnitude is lower than in mammals. The immunological memory in mammals is
defined as the secondary response to the same antigen, which triggers the production
of antibodies with higher affinity and titers. Memory B cells have also been
characterized in teleost, but with differences in the antibodies titer and affinity in the
secondary response than in mammals (Ma, Ye et al. 2013; Ye, Kaattari et al. 2013).
From the immunological point of view, an ideal vaccine has to induce the adaptive
immunity and particularly long-lasting protective mechanisms. However, taking into
account that the adaptive and innate immunity are connected, a vaccine also has to be
able to induce the innate immunity effectively.
2.8 Vaccines against VHSV
The losses caused by VHSV in economically important fish species such as the rainbow
trout, Japanese flounder, and turbot have driven the development and testing of all
kinds of vaccination strategies: live-attenuated vaccines, whole inactivated killed
25
vaccine, purified subunit proteins of the pathogen, purified proteins produced from
cloned genes, and DNA vaccines (Leong, Anderson et al. 1996). However, currently no
commercial vaccine against VHSV is available. Any commercial vaccine for aquaculture
should possess some features: be safe for the fish, the consumer, and the
environment, have a low cost per dose and be able to induce a high protection against
the pathogen.
In 1995, De Kinkelin and collaborators compared different vaccination strategies
against VHSV and showed that the inactivated virus vaccines induced protection by
intraperitoneal injection, but the efficiency was low when the delivery was performed
by immersion. Moreover, considering the need to use cell culture for its production, the
cost per dose makes this type of vaccine too expensive to be applied. Another type of
vaccine tested was the live-attenuated virus vaccine, which showed higher protection
along with lower cost production than inactivated virus vaccines, and the possibility of
immunizing fish through immersion, a convenient strategy considering the laborious
work to perform the injection on a fish farm with several thousand fish per cage.
Despite the advantages, the live-attenuated virus vaccine against VHSV showed some
residual virulence, which holds a risk of reemergence of the disease considering the
wild fish population surrounding the fish farms that can become reservoirs (De
Kinkelin, Bearzotti et al. 1995; Adelmann, Köllner et al. 2008).
Recombinant subunit vaccines are based on the expression of the VHSV glycoprotein,
which is the target of neutralizing and protective antibodies (Lorenzen, Olesen et al.
1990). The first recombinant subunit vaccine was the expression of the glycoprotein in
E.coli, but it showed a low immunogenicity (Lorenzen, Olesen et al. 1993). The second
involved the expression of the glycoprotein in baculovirus, which provides immune
protection, although part of this protection was a non-specific protection induced by
the insect cell (Lecocq-Xhonneux, Thiry et al. 1994).
26
A more recent, and so far the most promising type of recombinant vaccine tested
against VHSV is the DNA vaccine. This vaccine induces both short and long-term
protection along with a cheaper and simpler production than the other types of
vaccines.
2.9 DNA vaccine against VHSV
A DNA vaccine consists of a naked plasmid encoding an antigenic protein, controlled by
a eukaryotic promoter. After injection into the muscle, the antigen encoded in the DNA
vaccine is translated by the host machinery, inducing a specific protective response
against the antigen (Figure 3).
The first step in developing a DNA vaccine started in 1990, when Wolf and
collaborators showed that it was possible that the host cell machinery expresses a
reporter gene in mice muscle, after intramuscular injection of an expression vector
(Wolff, Malone et al. 1990). Later, the same principle was used, but, in this case,
injecting a DNA vaccine encoding the hemagglutinin protein from influenza, proving
that the intracellular expression of a viral antigen was able to induce immune
protection against this virus in mice. (Ulmer, Donnelly et al. 1993).
In 1996, Anderson and collaborators tested the same principle in rainbow trout. First,
they were able to detect expression of luciferase in the fish muscle after intramuscular
injecting the expression vector (Anderson, Mourich et al. 1996). Second, this
experiment was followed by the intramuscular injection of a plasmid encoding the
glycoprotein of IHNV in rainbow trout, which was able to induce strong immune
protection against this virus (Anderson, Mourich et al. 1996; Gomez-Chiarri, Livingston
et al. 1996). A few years later, similar results were obtained using a DNA vaccine
against VHSV (Heppell, Lorenzen et al. 1998).
27
Figure 3. Development of the DNA vaccine against VHS.
The DNA vaccine concept was later tested against different viral pathogens that affect
the aquaculture. So far, DNA vaccines have been successful against Novirhabdovirus
such as IHNV, VHSV and Hirame rhabdovirus (HIRRV) (Takano, Iwahori et al. 2004),
but has shown low efficacy against other virus, like IPNV or ISAV (Mikalsen, Torgersen
et al. 2004; Mikalsen, Sindre et al. 2005) or no protection against salmon alphavirus
(SAV) and Atlantic halibut nodavirus (Sommerset, Skern et al. 2005; Mutoloki and
Evensen 2011).
The total immune protection induced by the DNA vaccine against VHSV in rainbow
trout consists of two major mechanisms (Figure 4): first, shortly after intramuscular
injection of the DNA vaccine, the VHSV glycoprotein is expressed in the host cells,
inducing a non-specific and short-term protection that can be detected around 4 days
28
post-vaccination (dpv) and fades away after 3-10 weeks depending on the water
temperature. This protection was able to protect against a heterologous virus such as
IHNV, which is another Novirhabdovirus, and against the Atlantic halibut nodavirus, a
non-enveloped virus that belongs to Betanodavirus family. However, the DNA vaccine
was not able to induce protection against bacterial infection such as Yersinia ruckeri
and Aeromonas salmonicida, suggesting the mechanisms to be exclusively of an
antiviral nature (Lorenzen, Lorenzen et al. 2002).
Figure 4. Different immune protective mechanism induced by the DNA vaccine against
VHSV. (Lorenzen, Lorenzen et al. 2002)
Gene expression analyses have shown that early protection correlated with the
upregulation of Mx in the muscle, one of the antiviral proteins induced by IFN type I
(Boudinot, Blanco et al. 1998; Acosta, Petrie et al. 2005). Similar studies using the
DNA vaccine against IHNV have shown an upregulation of IFN type I, and thereby
several interferon-stimulated genes (ISGs), such as IRF-3, Mx-1, Vig-1, and Vig-8.
This expression analysis was carried out in the anterior kidney and spleen,
demonstrating that the antiviral mechanisms were not only induced at the injection
29
site but systemically (Purcell, Nichols et al. 2006). Additionally, some evidence of the
presence of Natural killer-like cells has been identified at short time after vaccination
(Utke, Kock et al. 2008), which agree with the upregulation of IFN-γ, usually
expressed by natural killers cells in mammals (Purcell, Nichols et al. 2006).
The non-specific and short protection induced by the DNA vaccine is followed by the
specific and long lasting protection of the adaptive immune response, which can last
for over two years, according to a time-course study using the DNA vaccine against
IHNV (Kurath, Garver et al. 2006). An additional characteristic of the DNA vaccine is
the capacity to induce both arms of the adaptive immunity, the humoral and the
cellular immune response (Liu 2011).
When the humoral response was analyzed, neutralizing antibodies could be detected
after 8 weeks post-vaccination, disappearing after 9 months post-vaccination, even
though the protection was intact. This result was an indication that the neutralization
by antibodies was not the only mechanism involved the protection. The cellular
responses showed that after intramuscular injection of the DNA vaccine in rainbow
trout, a higher number of pathogen-specific T cells were found in the blood in
comparison with non-injected fish, demonstrating that cellular responses play an
important role in the elimination of the cell that express the glycoprotein encoded in
the DNA vaccine (Utke, Kock et al. 2008).
The activation mechanisms of B cell, T helper cells and cytotoxic T cells by the DNA
vaccine are known for mammals (Figure 5). However, taking into account that
mammals and fish possess similar immune components, it is assumed that the
mechanisms involved in fish are comparable to the ones in mammals. Briefly, after
vaccination, the transfected cells, such as non-immune cells (myocytes) and antigen-
presenting cells (APC), express the antigen, which is processed into short peptides,
and presented for MHC class I (Figure 5B). The transfected APCs trigger the activation
30
of CD8+ cells (CTL) to further eliminate infected cells or in this case, transfected non-
immune cells with the vaccine. Additionally, the antigen secreted from the transfected
cells can be taken up by APCs, which can process it and present it on MHC class II,
activating CD4+, thereby enhancing B cell differentiation into specific antibody
producing cells (Figure 5C) (Rice, Dossett et al. 2008)
Figure 5. Immune mechanisms induced by the DNA vaccine against VHSV. (A)
Immunization or rainbow trout with a DNA vaccine. (B) Activation mechanisms in
different cell types by the expression of the VHSV glycoprotein. (C) Activation of
lymphocyte populations.
31
According to Figure 4, the protection induced by the DNA vaccines against VHSV and
IHNV can be divided into two major mechanisms, the non-specific and the specific
mechanisms. Nevertheless, it has been proposed that the protection induced by these
rhabdovirus DNA vaccines follows a model consisting of three sequential phases
instead of just two phases. The first one, the early antiviral responses (EAVR), is an
early, non-specific, and short-term protection associated with innate mechanisms. The
second phase is the specific antiviral responses (SAVR), which involves the humoral
responses in the presence of neutralizing antibodies and cellular immunity with the
presence of cytotoxic T cells, both associated with the adaptive immune response. The
third phase, the long-term antiviral responses (LAVR), is also associated with adaptive
immune responses, but without the presence of neutralizing antibody. In this third
phase the protection is slightly lower than in SAVR (Figure 6) (Kurath, Garver et al.
2006; Kurath, Purcell et al. 2007).
Figure 6. Model of the three phases of the host response to the IHNV and VHSV DNA
vaccines. Taken from (Kurath, Purcell et al. 2007). ISG: interferon-stimulated genes.
32
Besides inducing a strong protection against VHSV, DNA vaccines also possess a
technical advantage, such as low production costs, thermostability (it does not need
special storage conditions), short production time, and the manufacture of multivalent
vaccines is straightforward in comparison with other vaccine strategies.
In 2007, the first DNA vaccine was licensed and commercialized for aquaculture
against IHNV, in British Columbia, Canada, without outbreaks until now (Salonius,
Simard et al. 2007).
2.10 In this thesis
The experimental work in this thesis covers some aspects of the host-pathogen
interaction between rainbow trout immunized with the DNA vaccine and the fish
rhabdovirus VHSV. The contents are divided into two sections depending on the point
of view of this interaction.
The first section takes the VHSV point of view of this interaction and focuses on
whether VHSV, as a member of RNA viruses with high genetic variability capacity, is
able to escape from the protection induced by the DNA vaccine in rainbow trout,
thereby compromising the practical use of the vaccine.
The second section takes the vaccine point of view. The aim of this section was to
evaluate two innovative strategies for generic improvement of DNA vaccine vectors.
The first one analyzed the kinetics of the protection induced by a DNA vaccine with an
interferon-inducible rainbow trout Mx promoter controlling the expression of the VHSV
glycoprotein instead of the cytomegalovirus promoter used in the highly protective
current DNA vaccine. In terms of consumer safety, a fish-derived promoter would be
preferable to a mammalian virus promoter and an inducible promoter might improve
timing and duration of protective immunity in the fish. The second strategy aimed at
improvement of immunogenicity of a DNA vaccine encoding the secreted form of the
33
VHSV glycoprotein by linking the antigen to the constant region of the fish
Immunoglobulin (Fc). Such Fc-fusion proteins have been used in mammals to improve
the recognition of low immunogenic antigens by improving the Fc receptor mediated
take up by APCs and thereby promoting the antigen processing, presentation, and
further activation of the adaptive immune mechanisms. This approach could be a way
to improve the efficacy of DNA vaccines in fish in general.
34
3 Part II: Hypotheses and objectives
This thesis comprises the three manuscripts presented below.
3.1 Manuscript I
Title “Can VHS virus bypass the protective immunity induced by DNA
vaccination in rainbow trout?”
Hypotheses: Due to its intrinsic high variability capacity, VHSV is able to generate
mutants that can escape from the different protective mechanisms induced by the
glycoprotein gene DNA vaccine.
Objectives:
- Evaluate the ability of VHSV to escape from the innate and the adaptive antiviral
mechanism induced by the DNA vaccine by serial passaging of the virus in rainbow
trout immunized with the DNA vaccine.
-Evaluate the ability VHSV to escape from the neutralizing antibodies response by after
serial passaging or the virus in cell culture in the presence of serum from rainbow trout
immunized with the DNA vaccine.
3.2 Manuscript II
Title: “Time-course study of the immune protection induced by an interferon-
inducible DNA vaccine against viral haemorrhagic septicaemia virus in
rainbow trout”
Hypotheses: A DNA vaccine with a trout-derived IFN-inducible Mx promoter,
controlling the expression of VHSV glycoprotein is protective against VHS and a safer
alternative to the DNA vaccine with CMV promoter.
35
Objective:
-Evaluate the capacity of a DNA vaccine with the IFN-inducible Mx promoter to express
the antigen in fish and human cell lines.
-Evaluate the early, specific, and long-term antiviral responses induced by a DNA
vaccine with IFN-inducible Mx promoter.
3.3 Manuscript III
Title: “Attempt to mimic antibody-antigen complexes by DNA vaccination in a
fish virus model”
Hypotheses: The immunogenicity of a DNA vaccine encoding a secreted antigen can
be made more immunogenic by linking a secreted form of the VHSV glycoprotein to
the Fc domain of the fish immunoglobulin.
Objectives:
-Generate DNA vaccines encoding the secreted form of the VHSV glycoprotein linked to
the Fc domain of each immunoglobulin of rainbow trout.
- Analyze the secretion of the Fc-fusion proteins in cell culture.
- Evaluate the protection induced by DNA vaccines encoding the Fc-fusion proteins in
rainbow trout
36
4. Part III: Publications
4.1 Manuscript I
Can VHS virus bypass the protective immunity induced by DNA
vaccination in rainbow trout?
Dagoberto Sepúlveda, Niels Lorenzen
Submitted to PLOs One
37
Can VHS virus bypass the protective immunity induced by DNA vaccination in
rainbow trout?
Dagoberto Sepúlvedaa, Niels Lorenzen
a.
Fish Health Section, Department of Animal Science, Aarhus University, Aarhus, Denmarka
Corresponding author: Niels Lorenzen ([email protected])
38
ABSTRACT
DNA vaccines encoding viral glycoproteins have been very successful for induction of
protective immunity against diseases caused by rhabdovirus in cultured fish. However, the
vaccine is based on a single viral gene and since RNA viruses are known to possess high
variability and adaptation capacity, this work aimed at evaluating whether viral
haemorrhagic septicaemia virus (VHSV) was able to evade the protective immune response
induced by the DNA vaccination.
VHSV is a negative strand RNA virus, a member of the Rhabdoviridae family. The virus
causes lethal disease in rainbow trout and other economically important cultured fish
species.
The experiments comprised repeated serial passages of a highly pathogenic VHSV isolate
in fish cells in the presence of neutralizing fish serum (in vitro approach), and in rainbow
trout injected with the DNA vaccine (in vivo approach).
For the in vitro approach, the passaged virus was as sensitive as the parental virus to serum
neutralization. For the in vivo approach, the passaged viruses did not show increased
virulence nor increased persistence in vaccinated fish. However, a few vaccinated fish still
carried virus 4 weeks after challenge with passaged or parental virus and were able to
spread the infection to cohabitant naïve fish. The results demonstrated that the DNA
vaccine induces a robust protection, but also that the immunity is non-sterile and that it is
important not to consider vaccinated fish as virus free in veterinary terms.
39
INTRODUCTION
Viral haemorrhagic septicaemia virus (VHSV) is a negative-sense, single-stranded RNA
virus, which belongs to the Novirhabdovirus genus within the Rhabdoviridae family
(Walker, Benmansour et al. 2000). VHSV is the causative agent of the viral haemorrhagic
septicaemia (VHS), a serious and economically important disease of farmed rainbow trout
(Oncorhynchus mykiss) in Europe, causing high mortalities in all fish stages (Skall, Olesen
et al. 2005).
Currently, no commercial vaccine against VHS is available. Several vaccination strategies
have been tested to control this disease, among them live attenuated vaccines, inactivated
vaccines, and recombinant protein vaccines, but with limited efficiency or compromised
safety aspect (De Kinkelin, Bearzotti et al. 1995; Lorenzen and Olesen 1996). By contrast,
DNA vaccines have shown promising results by consistently protecting fish against
rhabdoviruses such as VHSV or Infectious hematopoietic necrosis virus (IHNV)
(Anderson, Mourich et al. 1996; Heppell, Lorenzen et al. 1998). This led to the licensing
and use of a DNA vaccine against IHNV in Atlantic salmon in Canada since 2005
(Salonius, Simard et al. 2007), with no outbreaks reported since.
The traditional DNA vaccine against VHSV consists of a plasmid designed for expression
of the viral surface glycoprotein (G) in eukaryotic cells. After injecting this vaccine
intramuscularly into the fish, an early non-specific interferon associated antiviral protection
is triggered (Lorenzen, Lorenzen et al. 2002; Sommerset, Lorenzen et al. 2003). The
temporary non-specific protection is followed by a specific and long lasting immunity,
40
including both the cellular and the humoral immune arms of adaptive immunity (Lorenzen,
Lorenzen et al. 1999; Utke, Kock et al. 2008)
Although the high efficacy of the DNA vaccine against VHSV has been consistent under
experimental conditions, its protective effect might be threatened following repeated use
under field conditions, due to the high variability of RNA viruses. The genetic variability of
VHSV is reflected by its ability to adapt to different environments and to a huge number of
different fish host species (Skall, Olesen et al. 2005; Pierce and Stepien 2012; Schönherz,
Lorenzen et al. 2015). Whether this variability might also promote generation and selection
of VHSV mutants, capable of evading the immunological protection induced by the DNA
vaccine remain to be addressed.
Some evidence about how the genetic variability of VHSV induces the generation of escape
mutants under selective conditions was shown when rainbow trouts were injected with a
plasmid encoding a neutralizing single chain antibody (scAb) against the G protein of
VHSV. In this case, a neutralization escape mutant was isolated from the survivors to the
infection (Lorenzen, Cupit et al. 2000). Similarly, selective conditions provided by
neutralizing monoclonal antibodies in vitro promoted the growth of neutralization-resistant
virus variants (Bearzotti, Monnier et al. 1995). These escape mutant had only one or few
mutations in the glycoprotein, demonstrating that specific selective conditions can quickly
promote a genetic change in the virus population both in vivo and in vitro. Previous reports
have shown that the DNA vaccine induced a slightly reduced immune protection against a
serotype heterologous to the one used in the vaccine (Lorenzen, Lorenzen et al. 1999). This
suggests that the difference of relatively few amino acids in G protein of VHSV can reduce
41
protection induced by a DNA vaccine. Similar observations have been made for IHNV
(Garver, LaPatra et al. 2005).
While mutations in the G protein can affect the efficacy of the adaptive protection,
mutations in e.g. the non-structural-protein (NS) may potentially affect the ability of the
virus to bypass the innate protection induced by the DNA vaccine. This viral protein has
been suggested to inhibit the apoptotic signal in virus infected cells at an early stage of
virus infection, thus affecting the virulence of the VHSV (Ammayappan and Vakharia
2011).
The aim of this work was to determine whether VHSV within a few generations, under the
selective pressure of DNA vaccine-induced immunity, will be able to develop mutants that
can escape from the innate or the adaptive protective mechanisms induced by the vaccine.
This information will allow us to evaluate the robustness of the current DNA vaccines and
potentially design a safer vaccination strategy.
MATERIALS AND METHODS
Cells. The fish cell lines used in this study were EPC (epithelioma papulosum cyprini)
(Fijan, Sulimanović et al. 1983) and BF2 (bluegill fry fibroblast) (Wolf, Gravell et al.
1966). The cells were maintained in minimum essential media (MEM) supplemented with
10% fetal bovine serum (FBS), 100 U/mL of Penicillin and 100 µg/mL of Streptomycin.
EPC and BF2 were grown for 24 hrs at 24 °C and 21 °C, respectively, and then maintained
at 15 °C.
Virus. To propagate VHSV, BF2 cell cultures were inoculated with low MOI of the virus
and maintained at 15°C until a complete cytopathic effect (CPE) was observed. The
42
supernatant was collected and centrifuged at 4500 x g for 15 min at 4 °C to eliminate
cellular debris. The virus was stored at - 80 °C. The titer was determined using the method
of 50% tissue culture infective doses (TCID50) per mL, in BF2 cells (Reed and Muench
1938).
Virological examination. Supernatants from cell culture or tissue homogenates were used
to prepare 10-fold serial dilutions, which were inoculated onto BF2 monolayer cultured at
60-80% confluence in a 24-well plate. The cultures were maintained at 15 °C for 7 days
when each well was examined. The wells with CPE were considered positive. The identity
of the CPE-causing virus was confirmed by PCR as outlined below.
Vaccination. For in vivo experiment, outbreed all female rainbow trout hatched and reared
under pathogen-free laboratory conditions and with a weight of 2-8 g were used. For the
vaccination, the fish were anesthetized in 0,01% benzocaine and injected intramuscularly
(IM) in the left epaxial muscle below the dorsal fin with 25 µL of purified DNA plasmid in
saline solution (0.9% NaCl), as described earlier (Lorenzen, Lorenzen et al. 1999). This
study included two groups, one vaccinated with 0,1 µg, and another vaccinated with 1,0 µg
of the plasmid pcDNA3-VHSV-G encoding the glycoprotein of VHSV DK3592b (Heppell,
Lorenzen et al. 1998). Non-vaccinated fish were used as controls. All fish were maintained
in pathogen-free laboratory facilities in 120 L aerated aquaria supplied with recirculated
water at 8-10°C. One day before inoculation with virus (challenge), the fish were
transferred to aerated aquaria of 8 L supplied with running tap water in a contained
experimental facility.
43
Passaging of VHSV in vaccinated fish. Infection trials included into two treatment
groups; one group challenged 1 week post-vaccination, and another group challenged 6
weeks post-vaccination (Figure 1).
Figure 1
The experiment included successive passages of the VHSV isolate DK3592b (parental
virus) in fish immunized with the DNA vaccine. In the first passage, each group was
subdivided into 3 subgroups; I) non-vaccinated fish, II) fish vaccinated with 0,1 µg of
plasmid and III) fish vaccinated with a dose of 1,0 µg of plasmid. Every subgroup was kept
in 2 aquaria with 25 fish in each. The infection was carried out by immersion in static water
with a virus concentration of 1 x 105 TCID50 mL
-1, in 8 L water for 3 hrs. After this, water
flow was restored. The experiment was monitored 3 times per day, and moribund fish were
euthanized with an overdose of benzocaine and stored at - 20 °C until further analysis.
At 21 days post infection, the surviving fish were euthanized with an overdose of
benzocaine. The moribund fish sampled were dissected, and spleen, liver, heart, head
kidney, and brain were collected and pooled per fish in MEM. Organs were homogenized
in a TissueLyser (Qiagen) for 2 min at 20 Hz. The homogenate was centrifuged at 4500 x g
for 15 min, and the supernatant was collected to be treated with gentamicin overnight at 4
°C. After the antibiotic treatment, the virus content was titrated and on BF2 cells and the
samples stored at -80 °C (Reed and Muench 1938). This homogenate was used for the next
passage.
The next passages had the same groups and subgroups as the previous passage, but in this
case, 10 fish were used per aquaria. The infection was performed by intraperitoneal
44
injection of the tissue homogenate supernatant collected from the previous passage.
Homogenates included organs from both survivors and dead fish. The procedure for
monitoring and sampling was performed as explained in the first passage.
Figure 2
Examination for VHSV escape mutants to the vaccine-induced immunity. A challenge
trial with vaccinated fish was performed to compare the performance of the parental virus
with that of the passaged virus, under the selective pressure induced by DNA vaccination.
The comparison was based on the accumulated mortality, the virus carrier state of the
vaccinated fish, as well as the level of virus transfer to co-habitant naïve fish.
To obtain sufficient virus for immersion challenge, the virus collected after successive
passages in vaccinated fish (passaged virus), was passaged once in BF2 cells and titrated as
outlined above. An RT-PCR assay with primers specific for the VHSV N-gene was used to
confirm the identity of the passaged virus. Total RNA was isolated from 100µL of each
supernatant using the RNeasy mini kit (Qiagen). Subsequently, the cDNA was synthesed
using the iScript kit (BioRad) following the manufacturer's recommendation. The qPCR
reaction contained 1 µL of the cDNA, 7,5 µL of SuperMix, 0,03 µL of Rox, 0.3 µL of each
primer VHSV-N-For 5’-AGG TCT CAG ATG TCA TCA AGG AG-3’ and VHSV-N-Rev
5’-CGG TGG AGC TCC TGA AGT T-3’, and 5.87 µL of free-nuclease water. The PCR
amplification program involved an initial step at 50°C for 2 min, and then a denaturation
95°C for 2 min. These steps were followed by 40 cycles 95°C for 15 sec and 60°C for 1
min. Amplification was performed in MX Pro-Mx3005P thermocycler (Stratagene)
Table 1
45
The fish involved were vaccinated with 1,0 µg of the DNA vaccine and challenged at 1 or 6
weeks post vaccination, using virus passaged at similar time points in vaccinated fish. Fish
challenged with the parental DK3592b virus served as controls. As an example, when the
fish were challenged 1 week post-vaccination the passaged virus used was VHSV-1W0,1
and VHSV-1W1,0. With each virus, the infection was performed in duplicates with 20 fish
in each aquarium. The infection was carried out by immersion in static water in the 8 L
aquaria for 3hrs with a final concentration of the virus at 1x104 TCID50 mL
-1. After this, the
water flow was restored.
Two weeks post-infection, 10 non-vaccinated (naïve) fish were transferred into each
aquarium to cohabitate with the vaccinated fish. The naïve fish were tagged by cutting a
part of the tail fin. After another 2 weeks, all surviving fish were euthanized with an
overdose of anesthetics. The spleen, heart, liver, kidney and brain were collected and
pooled from each fish individually. The tissues were homogenated and used for virological
examination.
In vitro passaging of VHSV in the presence of neutralizing trout serum. Serial 10-fold
dilutions of VHSV DK3592b (30 µL) were mixed in wells of 96-well plates with 15 µL of
a 1/40 dilution of the heat treated (30 min at 45°C) neutralizing trout serum obtained after
repeated immunization with the DNA vaccine encoding the VHSV glycoprotein (pcDNA3-
VHSV-G) (Utke, Kock et al. 2008). Following incubation for 1 h at 15°C, 15 µL of 1/40
dilution of normal trout serum was added per well as complement source (Olesen and
Jørgensen 1986). After incubation overnight at 15°C, 10 µL of the treated virus was added
46
to the wells of a 96-well plate with EPC cell culture, seeded the previous day, and
incubated for 30 min at 15 °C. Finally, to maintain the selective environment, 50 µl of
MEM 5% supplemented with a dilution of 1/640 of the immune serum and a dilution of
1/640 of the complement was added.
Five replicates well were used for each virus dilution. The cells were incubated at 15 °C for
7 days. After that, we collected the supernatant from 3 wells given the lowest virus
inoculum still causing CPE. Serial dilutions were made with each of the 3 collected
supernatants. The dilutions were mixed with antiserum for the second passage, following
the same procedure as for the first passage, except that only 3 replicate cell culture wells
were inoculated with diluted antiserum/virus mixtures. This passaging under selective
(antiserum) pressure was repeated 11 times.
Evaluation of virus´ susceptibility to serum neutralization. The susceptibility of the
passaged and the parental virus to the neutralizing effect of the immune serum was
compared using the plaque neutralization assay (PNT) (Olesen and Jørgensen 1986), in
which the titer of the serum is defined as the reciprocal value of the highest serum dilution
reducing the number of plaques by 50% compared to a normal trout serum control. To
evaluate the presence of mutations, the full-length glycoprotein gene of each passaged virus
was amplified by PCR and sequenced. The total RNA isolation and the cDNA synthesis
was performed following the same procedures outlined above. The PCR amplification was
performed with primers flanking the G gene using the high fidelity DNA polymerase
Herculase II Fusion (Agilent Technology) according to the procedure recommended by the
47
manufacturer. The alignment step in the PCR was performed at 57oC, using the forward
primer 5´ TAC AAT CGT GCC GTC GAA G 3´and the reverse primer 5´ AGG TCA CAG
TTG AGG TAG TTG 3´.
RESULTS
In vivo approach: Evaluation of the ability of passaged VHSV to evade the innate and
adaptive protection induced by the DNA vaccine
Passaging in vaccinated rainbow trout. To test the ability of the virus to bypass the
innate immunity induced by the DNA vaccine, we passaged VHSV in rainbow trout
vaccinated one week before inoculation with virus. When the fish used for passaging had
been vaccinated with a dose of 0,1 µg of the DNA vaccine, we were able to isolate virus
from dead and vaccinated surviving fish in each of the successive 5 passages. When fish
given 1,0 µg of the DNA vaccine were used, we were able to isolate virus only until the 2nd
passage. This suggested that the protection induced by 1,0 µg of the DNA vaccine was able
to clear the virus in the immunized fish more efficiently than in fish vaccinated with 0,1 µg
DNA, although the latter dose was still highly protective (data not shown).
To test the ability of the virus to bypass the adaptive immune response induced by the DNA
vaccine, the passaging was performed in rainbow trout vaccinated 6 weeks before
inoculation. In this setup, VHSV was re-isolated from dead and vaccinated survivor fish in
all 4 passages using both vaccine doses (data not shown).
48
Comparison between passaged virus and parental virus. After successive passages, the
virus obtained from the last passages under selective conditions (passaged virus), was
amplified by 1 passage on BF2 cells and later compared with the parental VHSV isolate
DK3592b.
The comparison in the in vivo approach included three parameters; mortalities induced in
vaccinated and non-vaccinated fish, the capacity of the virus to infect and persist in
vaccinated fish, and the ability of the virus to spread the infection from vaccinated carriers
to cohabitant naïve fish.
The mortality rates caused by the passaged virus and the parental virus in vaccinated fish
were both low, ranging between 0-12 %. Only one of the duplicate aquaria with fish
inoculated with the VHSV-1W1,0, and one of the duplicates inoculated with the VHSV-
6W0,1, showed higher mortalities (about 20%) than the aquaria inoculated with the parental
virus (Figure 3). These results were considered to be due to an intergroup variability rather
than increased virulence of the passaged viruses. In non-vaccinated fish, all viruses induced
high mortality rates, indicating that the passaging had not affected the virulence.
Figure 3
The evaluation of the ability of the virus to infect vaccinated fish showed that both the
parental and passaged viruses were able to infect and persist in some of the vaccinated fish
for at least 4 weeks post-challenge (Table 1). The highest frequencies of carriers in
individual aquaria were obtained with the parental virus, with 36% and 15,8% of virus-
positive fish, when the evaluation was performed at 1 and 6 weeks post-vaccination,
respectively. Among the fish inoculated with passaged virus, the highest carrier frequencies
49
reached 13.6% and 10.5 % respectively. Therefore, the passaging had not improved the
ability of the passaged virus to persist in vaccinated fish.
The analysis of the capacity of the virus to spread from vaccinated carriers to naïve fish
showed that even though only a few fish could be detected as carriers, vaccinated fish were
able to transmit the infection to naïve cohabitants.
Table 2
In vitro approach: Evaluation of the ability of passaged VHSV escape from
neutralization by serum from fish immunized with the DNA vaccine
After 11 successive passages in cell culture in the presence of neutralizing trout serum, we
compared the ability of the passaged virus and the parental virus to escape from the
neutralization by a trout immune serum. As shown in Table 3, no significant difference in
susceptibility to neutralization was found between the passaged viruses and the parental
virus.
The glycoprotein gene of the 3 passaged viruses and the parental virus was sequenced and
compared to determine the presence of mutations. The 4 sequences had 100% nucleotide
identity (not shown).
Table 3
DISCUSSION
This work focused on analyzing whether the fish rhabdovirus VHSV was able to mutate
and escape from the immune protection induced by a DNA vaccine. Such mutants would
represent a potential risk of reemergence of the disease in vaccinated fish populations,
50
reducing the applied potential of the DNA vaccine. To our knowledge, this important
aspect remains to be addressed for the otherwise extensively analyzed and highly protective
fish DNA vaccines. Our results suggest that the immune response triggered by the vaccine
is rather robust and not easily bypassed by the virus.
The high genetic variability of RNA viruses is due to the high replication rates, large
population size, and high mutation rates, which together generate a diverse spectrum of
virus variants in every replication cycle and result in a population of one dominant virus
variant along with multiple low-frequency virus variants. This phenomenon is known as the
quasispecies theory and allows the virus to adapt rapidly to new environments, and to new
hosts (Domingo, Biebricher et al. 2001). When RNA viruses are exposed to selective
exogenous conditions, the frequency of some virus variants in the population could change,
favoring those with a certain advantage to replicate in the new condition. The fact that
VHSV has been found in a wide range of host fish species suggest a high adaptation
capacity (Skall, Olesen et al. 2005; Schönherz, Lorenzen et al. 2015). We, therefore,
questioned whether the virus would also be able to adapt DNA-vaccinated fish.
The experimental design included two approaches. First, an in vivo approach was used to
evaluate the ability of VHSV to evade the early innate or the later adaptive immune
protection induced by the DNA vaccine in rainbow trout fingerlings. Second, an in vitro
approach was applied, to evaluate the ability of the virus to evade the neutralizing effect of
serum from rainbow trout immunized with the DNA vaccine.
The analysis of the in vivo approach took into account that an escape mutant could have
diverse strategies to bypass the immune protection induced by the DNA vaccine. Among
51
these strategies, escape mutants could have increased virulence in vaccinated fish, causing
higher mortality rates as a result of a more efficient viral replication. Alternatively,
decreased virulence might reduce clearance, thereby allowing the virus to persist in the host
and spread to cohabitant fish. However, the in vivo approach evaluation showed no
advantage of any of the passaged viruses in comparison with the parental virus, neither
considering virulence, persistence in vaccinated fish nor the capacity of vaccinated fish
carriers to infect naïve cohabitant fish.
Our results demonstrate that the virus is unlikely to escape from the protective immune
response within 4-5 passages in vaccinated fish. However, we also show that DNA
vaccinated fish can become infected and that the infection can spread to naïve co-habitants.
Therefore, as for many other veterinary vaccines not providing sterile immunity, DNA
vaccinated animals cannot be considered virus-free in terms of trade regulations. In our
setup, naïve cohabitants were stocked with vaccinated carriers already 2 weeks post
exposure of the latter to the virus. It may be anticipated that a longer time gap would have
given the, presumably few, carrier fish time to eliminate the infection and hereby have
reduced the chance of transmission. Further time-course studies are needed to address this
aspect.
According to Read et al. 2015, infected vaccinated chickens were associated with a higher
risk of spread of highly virulent virus than the infected non-vaccinated chickens. The
rationale behind this theory was that non-vaccinated chickens would die out rapidly and
thereby allow the infection to be kept under control, while the infected vaccinated chicken
would survive the infection and allow the virus to persist, replicate and spread in the host
population for an extended period. Furthermore, the persistence in vaccinated chickens
52
could promote the selection of hyperpathogenic virus strains that could cause a more severe
disease (Read, Baigent et al. 2015).
While this scenario might be true for some highly lethal viruses, our results suggest that it
does not count for VHSV infections in rainbow trout. Although the virus causes high
mortality, some individuals often survive and clearance from such fish is slower compared
DNA vaccinated individuals (Lorenzen, Einer-Jensen et al. 2000). Furthermore, despite
repeated passaging in such fish we were unable to isolate escape mutants. Repeated
stocking with vaccinated fish, therefore, seems to be a viable strategy for reducing the
prevalence of VHSV in endemic zones.
The in vitro aim was look at the humoral immune response to DNA vaccination alone and
evaluate whether serial passages of VHSV in the presence of serum from rainbow trout
immunized with the DNA vaccine, would favour propagation of neutralization escape
mutants.
Previous works showed that viruses like VHSV and IHNV were able to generate escape
mutants resistant to neutralization by monoclonal antibodies after a few passages in cell
culture (Bearzotti, Monnier et al. 1995; Huang, Chien et al. 1996). Another setup showed
that it was possible to isolate an escape mutant from rainbow trout injected with a plasmid
encoding a neutralizing recombinant single chain antibody (scAb) against the glycoprotein
of VHSV (Lorenzen, Cupit et al. 2000).
However, after 11 passages, there was no evidence of mutants escaping the neutralizing
effect of the trout immune serum. This was confirmed by the fact that the passaged and the
parental virus had a 100% identical glycoprotein gene sequence. In contrast to this, mutants
53
escaping neutralization by mouse monoclonal antibodies carried one or more amino acid
substitutions in the translated G gene (Bearzotti, Monnier et al. 1995). The explanation for
why the apparently rather adaptable virus could not escape from the neutralization by our
fish immune serum might be due to different neutralization mechanisms used by mouse
monoclonal antibodies (mIgG1) and by fish polyclonal antibodies IgM in serum.
Neutralizing monoclonal antibodies bind a single epitope and thereby most likely interfere
with the process of infection, e.g. by preventing recognition of the receptors on the cell
membrane or generating aggregates incapable of infecting host cells (Reading and
Dimmock 2007). One or a few amino acids changes could prevent antibody binding and
thereby generate a full escape mutant. In contrast, to produce an escape mutant of the
neutralizing serum antibodies the virus may have to mutate at multiple sites, assuming that
vaccination induces a polyclonal neutralizing response. Furthermore, fish IgM neutralizing
activity depends on the presence of complement, implying that the neutralization
mechanism is not just a steric blocking of the viral infectivity, but a more complex
mechanism potentially involving different sites of the protein, which could be more
difficult for VHSV to bypass without affecting the functional biology of the virus particle
(Lorenzen, Olesen et al. 1990). In summary, the results from the in vitro analysis supported
the in vivo data and suggested that VHSV cannot easily escape even from the humoral
immune response alone as induced by DNA vaccination. The trout immune serum used
here was obtained from a hyperimmunized fish, and all fish do not seroconvert following a
single vaccine injection (Lorenzen et al. 1998). However, our failure to isolate escape
mutants in vivo suggest that the broad nature of the immune response triggered by the
vaccine, involving a range of both innate and adaptive mechanisms, makes escape mutation
incompatible with maintaining the viability and the infectious capacity of the virus.
54
Our setup only included the most stringent selective condition by challenging vaccinated
fish with virus carrying a G gene identical to the vaccine gene. It can therefore not be
excluded that viral escape from DNA vaccine induced immunity might arise under less
selective conditions, such as when the vaccine G gene is heterologous to that of the
infecting virus. The safest strategy would thus be to sequence the prevalent VHSV variants
in the fish population to be vaccinated and then perform the vaccination with a homologous
or at least genetically closely related vaccine gene.
In conclusion, our results support the low probability to generate an escape mutant under
optimal DNA vaccination conditions, when a strict protective immunity is induced. The
difficulties to bypass the protection induced by the DNA vaccine are an additional
advantage of this vaccine against VHSV, making it a safe prophylactic tool. However, we
also observed that some of the vaccinated fish can get subclinically infected and that the
infection can be transmitted to naïve cohabitants if these are stocked with the vaccinated
fish shortly after their exposure to the virus. Vaccinated fish from endemically infected
zones should, therefore, be considered to be potential carriers in terms of trade regulations.
ACKNOWLEDGMENTS
The authors gratefully acknowledge the excellent assistance from the technical staff of the
Fish Health Section, Department of Animal Science, University of Aarhus.
55
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59
Figure 1. Vaccination and challenges for the in vivo approach.
60
Figure 2. Scheme of the passaging of VHSV in vaccinated fish for the first two passages.
Passage 3 and 4 followed the procedure of passage 2.
61
Figure 3. Comparison of the total mortality of rainbow trout challenged with the parental
virus, and the passaged virus. The challenges were performed at 1 week post vaccination
(A) and at 6 weeks post vaccination (B). White bars correspond to non-vaccinated fish and
black bars correspond to fish vaccinated with the DNA vaccine.
62
Table 1. Passaged virus
Virus
Label
Status of fish used for passaging
Time post vaccination Vaccine dose
VHSV-1W*0,1** 1 week 0,1 µg
VHSV-1W1,0 1 week 1,0 µg
VHSV-6W0,1 6 weeks 0,1 µg
VHSV-6W1,0 6 weeks 1,0 µg
* Refers to number of weeks between the vaccination and challenge
** Refers to vaccine dose (µg)
63
Table 2. Comparison of the carrier status of vaccinated rainbow trout challenged with the
parental virus or with the virus passaged in vaccinated fish.
Challenge
time
Virus
Replicate
Aquaria
N°
Vaccinated fish
positive in virological
examination (%)
Cohabitant naïve fish
positive in virological
examination (%)
1 wpv*
DK3592b
1 36,4 100
2 5,6 0
VHSV-1w 0,1
1 5,6 0
2 13,6 0
VHSV-1w 1,0
1 0 0
2 5,0 100
6 wpv
DK3592b
1 0 0
2 15,8 80
VHSV-6w 0,1
1 10,5 60
2 5 60
VHSV-6w 1,0
1 0 0
2 10,0 0
* wpv: Weeks post vaccination
64
Table 3. Neutralizing titers of trout immune serum for in vitro passaged and parental virus.
Parental Virus
DK3592b
Passaged
Virus1
Passaged
Virus2
Passaged
Virus3
IS CS IS CS IS CS IS CS
50% PNT
titer
5120 <40 20480 <40 5120 <40 10240 <40
IS= Immune serum collected from rainbow trout repeatedly immunized with the DNA
vaccine
CS= Control serum collected from non-vaccinated rainbow trout
65
4.2 Manuscript II
Time-course study of the immune protection induced by an
interferon-inducible DNA vaccine against viral haemorrhagic
septicaemia virus in rainbow trout
Dagoberto Sepúlveda, Ellen Lorenzen, Jesper Skou Rasmussen, Katja
Einer-Jensen, Bertrand Collet, Chris Secombes, Niels Lorenzen
Intended for submission to Fish and Shell Fish Immunology
66
Time-course study of the immune protection induced by an interferon-
inducible DNA vaccine against viral haemorrhagic septicaemia virus in
rainbow trout
Dagoberto Sepúlvedaa, Ellen Lorenzena, Jesper Skou Rasmussena, Katja Einer-Jensenb,
Bertrand Colletc, Chris Secombesd, Niels Lorenzena
a Department of Animal Science, Aarhus University, Denmark
b Qiagen, Aarhus, Denmark
c Marine Scotland, Marine Laboratory, Aberdeen, United Kingdom
d Aberdeen University, Aberdeen, United Kingdom
67
ABSTRACT
Attempts to improve the efficacy and safety of DNA vaccines against viral diseases in
aquacultured fish have focused on elements of the plasmid vector such as the
regulatory elements driving the expression of vaccine antigen. Ideally, the expression
of the antigen should be controlled by a fish-derived promoter, with minimal or no
activity in human cells.
In the work presented here, we compared a DNA vaccine with the interferon-inducible
Mx promoter from rainbow trout, and a DNA vaccine with a cytomegalovirus promoter
(CMV), both encoding the viral haemorrhagic septicaemia virus (VHSV) glycoprotein G.
The in vitro analysis showed that while the DNA vaccine with the CMV promoter
constitutively induced expression of the G protein in both fish and human cell lines, the
DNA vaccine with the Mx promoter inducibly promoted expression of the glycoprotein
only in the fish cell lines.
To address the three-phase protection model suggested by Kurath et al. (2006) –
comprising early, specific and long-term (EAVR, SAVR, LAVR) phases - infection trials
were performed with vaccinated fish at 2, 8, and 78 weeks post vaccination (wpv),
respectively. The DNA vaccine with CMV promoter provided protection at all times,
while vaccination with the DNA vaccine with the Mx promoter only protected the fish at
8 wpv. However, following induction with polyI:C in vaccinated fish one week before
challenge, protection was also evident at the early challenge 2wpv.,
The results revealed a superior consumer safety of the trout Mx promoter compared to
the traditional CMV promoter in the context of DNA vaccination of farmed rainbow
trout. However, improvements will be needed in terms of time course efficacy.
Importantly, the data further suggest a lack of direct interdependency of protection in
the different phases of the immune response to the rhabdovirus G gene DNA vaccines.
68
INTRODUCTION
Infectious diseases are one of the major causes of economic losses in the expanding
aquaculture industry. Application of effective vaccines is fundamental to keep the
industry sustainable. Viral haemorrhagic septicaemia virus (VHSV), a member of the
Rhabdoviridae family (Walker, Benmansour et al. 2000), causes a serious disease in
farmed fish, such as rainbow trout and turbot in Europe, and Japanese flounder in East
Asia (Skall, Olesen et al. 2005). Several vaccination strategies have been tested
against VHSV, including inactivated virus vaccines, live-attenuated virus vaccines, and
recombinant vaccines. However, due to low efficacy, high cost per dose, or safety
limitations, there is currently no commercially available vaccine against VHSV (De
Kinkelin, Bearzotti et al. 1995; Lorenzen and Olesen 1996). In 1998, the testing a DNA
vaccine as an alternative immunization strategy against VHSV revealed establishment
of highly protective immunity (Heppell, Lorenzen et al. 1998). Since then, several
studies have evaluated the protection induced by DNA vaccination against VHSV and
the related infectious haematopoietic necrosis virus (IHNV) under different
experimental conditions, with promising results (Lorenzen and LaPatra 2005; Kurath,
Purcell et al. 2007). These DNA vaccines consisted of a eukaryotic expression vector
encoding the viral surface glycoprotein G, under the control of a cytomegalovirus
promoter (CMV). The immunological protection follows a three-phase scenario (Kurath,
Purcell et al. 2007), which involves:
(i) The early antiviral responses (EAVR), which are a cross-reactive protection
associated with innate antiviral mechanisms. This protective phase starts
shortly after the intramuscular injection of the DNA vaccine, and is
characterized by the overexpression of interferon type I (IFN I), and
consequently the expression of multiple interferon-stimulated genes (ISG)
69
such as: Mx, Vig-1, Vig-8 (Boudinot, Blanco et al. 1998; Acosta, Petrie et
al. 2005; Purcell, Nichols et al. 2006).
(ii) The specific antiviral responses (SAVR), which are associated with adaptive
immunity mechanisms and characterized by the presence of neutralizing
antibodies, and cytotoxic T lymphocytes (CTL) and natural killer (NK)-like
cells (Lorenzen, Einer-Jensen et al. 2000; Kurath, Garver et al. 2006; Utke,
Kock et al. 2008).
(iii) The long-term antiviral responses (LAVR), which follow the SAVR, are
characterized by a slightly lower protection than in SAVR and minimal
detection or absence of neutralizing antibodies (Kurath, Garver et al. 2006;
Kurath, Purcell et al. 2007).
The CMV promoter is the most common promoter used in expression vectors for DNA
vaccines, due to its high expression activity in a broad range of eukaryotic cells.
However, the safety concern of the potential recombination of a CMV promoter
sequence in a DNA vaccine for aquaculture has driven the search of an alternative fish-
derived promoter. Some fish-derived promoters analysed in vivo in a DNA vaccine
were the Interferon regulatory factor 1A (IRF1A) promoter, Mx1 promoter (Alonso,
Johnson et al. 2003), and the carp β-actin (AE6) promoter (Chico, Ortega-Villaizan et
al. 2009).
Some of the examined alternative promoters have shown potential in terms of
protection induced by the related DNA vaccines. However, the reports published so far
have not taken the time-course variation of the protective mechanisms into account.
This is important from a practical point of view, where the ability of the vaccine to
induce a fast, efficient, and long-lasting protection, is essential.
The aim of this work was to analyze the capacity of a VHSV glycoprotein-gene DNA
vaccine with an IFN-inducible trout-derived Mx promoter to induce EAVR, SAVR and
70
LAVR in rainbow trout fingerlings. Moreover, in terms of consumer safety, a promoter
showing minimal or no expression in human cells would be preferable. Therefore, we
also compared expression of the vaccine protein in transfected cell lines derived from
fish and humans respectively.
MATERIALS AND METHODS
Cell lines. EPC cells (epithelioma papulosum cyprinid) (Fijan, Sulimanović et al. 1983),
BF2 cells (bluegill fry fibroblast) (Wolf, Gravell et al. 1966) and HeLa cells (ATCC: CCL-
2) were used in this work. The cells were maintained in minimum essential media
(MEM) supplemented with 10% fetal bovine serum (FBS), 100 U/mL of Penicillin and
100 µg/mL of Streptomycin. EPC and BF2 were maintained at 15°C, and HeLa were
maintained at 37°C.
Virus. A low passaged VHSV isolate (DK3592b) was propagated in BF2 cells by
inoculating freshly passaged cells with a low MOI (multiplicity of infection). The
infected cell cultures were maintained at 15°C. When a complete cytopathic effect was
observed, the supernatant was collected and centrifuged at 5000 r.p.m for 15 min at
4°C. The titer of the virus was determined using the method of 50% tissue culture
infective doses (TCID50) per mL in BF2 cells (Reed and Muench 1938).
Plasmid constructs. An expression vector with Mx promoter (pcDNA3-Mx) was
constructed by replacing the CMV promoter of pcDNA3 (pcDNA3-CMV) (Invitrogen)
with the Mx1 promoter from pGL3-Basic-PrMx1 (Collet and Secombes 2001). The Mx1
promoter was excised from pGL3-Basic-PrMx1 as a 600 bp MluI-BglII fragment and
inserted into pcDNA3 digested with MluI and BamHI. The IFN-regulated expression
vector encoding the VHSV glycoprotein (pMx-vhsG) was obtained by excising the VHSV
71
glycoprotein gene from pcDNA3-vhsG (Lorenzen, Lorenzen et al. 1998) as a 1576 bp
EcoRI-EcoRI fragment and ligating it into pcDNA3-Mx digested with EcoRI (Figure 1).
The glycoprotein gene was from originally derived from VHSV isolate DK3592b. The
empty vectors with CMV and Mx promoters were used as a negative control.
Escherichia coli transformed with each plasmid were propagated overnight in 4 L of LB
medium supplemented with ampicillin. Endofree plasmid purification kit (Gigaprep kit
Qiagen) were used for the further purification of the DNA constructs. The vaccination
trial included the constructs described in Table 1.
Figure 1. Construction of the DNA vaccine with the IFN-inducible Mx promoter.
72
Table 1: Description of the plasmids used for DNA vaccination
Plasmids Promoter Transgene
pCMV-Empty CMV without transgene
pCMV-vhsG CMV VHSV glycoprotein
pMx-Empty IFN-inducible Mx promoter without transgene
pMx-vhsG IFN-inducible Mx promoter VHSV glycoprotein
Expression of the VHSV glycoprotein in cell culture
EPC and HeLa cells were seeded in a 24-well plate (2x105 cell/well) one day before
transfection. The transfection was performed with the plasmids, pCMV-Empty, pCMV-
vhsG, and pMx-vhsG using Superfect (Qiagen) as described by the manufacturer. The
amount of plasmids used for the transfection was 4 µg/mL for EPC cells and 9 µg/mL
for HeLa cells. Twenty four hrs post-transfection, the medium was replaced by medium
with and without poly I:C (Sigma), a potent inducer of IFN, in a final concentration of
10 µg/mL.
Detection of the VHSV glycoprotein
The transfected cells were fixed with 72 hrs post transfection in cold acetone 80%. The
staining was carried out according to the protocol used in (Lorenzen, Cupit et al.
2000). Three mouse anti-VHSV glycoprotein monoclonal antibodies were used in this
work as primary antibody: Mab IP1H3 that recognizes a linear epitope, the 3F1A2 that
recognize a conformation-dependent epitope (Lorenzen, Olesen et al. 1990; Lorenzen,
Cupit et al. 2000). The secondary antibody was HRP-conjugated rabbit anti-mouse IgG
(DAKO P0260).
73
First vaccination trial: Evaluation of EAVR and SAVR
Outbreed, all female rainbow trout between 3 - 5 g were used for the vaccination. The
fish were anesthetized in 0,01% benzocaine and then injected intramuscularly with
1µg of each of the 4 purified DNA plasmids (Table 1) in 25 µL of saline solution (0,9%
NaCl). At one week post-vaccination, the fish vaccinated with pMx-Empty and with
pMx-vhsG were split into two subgroups. One subgroup was injected intraperitoneally
(I.P) with 3,5 µg of poly I:C (Sigma) in 50 µL of saline solution, and the second
subgroup was injected with 50 µL of saline solution. After vaccination, the fish were
maintained in 120 L aerated aquaria supplied with recirculated water at 8-10°C in a
pathogen-free laboratory facility.
The challenge with VHSV isolate DK3592b was performed at two times, at 2 weeks and
12 weeks post-vaccination, respectively, in aerated 8 L aquaria with 3 replicates of 24-
26 fish per treatment. The challenge was carried out by immersion in static water with
an infectious dose of 1x105 TCID50 mL-1 of water. After 2 hrs, the water flow was re-
established. During the following 3 weeks, fish with evident clinical signs were
euthanized with an overdose of benzocaine.
Second vaccination trial: Evaluation of the LAVR
In this trial, we focused on the long-term antiviral responses (LAVR). Outbreed all
female rainbow trout (2 - 5g) were divided into 5 groups, 4 of them injected
intramuscularly with the plasmids in 25µL of saline solution, and one group injected
with a saline solution (0.9% NaCl). The plasmid used are described in Table 1. Each
group contained 160 fish, which were maintained in 120 L aerated aquaria supplied
with recirculated water at 8-10°C in a pathogen-free laboratory facility. At 68 weeks
post-vaccination, the groups of fish previously injected with saline solution (0.9%
NaCl), pMx-Empty, or pMx-vhsG were split into two subgroups, one was injected with
74
saline solution (0.9% NaCl) and the another was injected I.P with 100µg of poly I:C
(Sigma) diluted in 100 µl of saline solution per fish. The fish injected with pCMV-
Empty, and pCMV-vhsG were injected only with the saline solution. At this time, the
weight of the fish was 40-70 g each.
The challenge was performed at 78 weeks post vaccination (10 weeks post-induction
with poly I:C). The infection was carried out like in the previous section. The virus used
was VHSV isolate DK3592b with a titer of 3x104TCID50 mL-1in an 8L aquaria. The
challenged was carried out with 3 replicates of 20 fish per treatment.
The mortality of the challenges was recorded daily for 30 days and the relative
percentage survival (RPS) was calculated: RPS=[1-(% mortality of immunized fish / %
mortality of control fish)]x100.
Figure 1. Scheme of the evaluations of the three phases of the protective immunity
induced by the DNA vaccines against VHSV. (A) EAVR, (B) SAVR, (C) LAVR.
75
RESULTS
Expression analysis in vitro. The EPC cell transfected with pMx-vhsG expressed the
glycoprotein following induction with poly I:C, while no expression was detected in
transfected a human HeLa cell. On the contrary, both EPC and HeLa cell transfected
with the pCMV-vhsG expressed the viral glycoprotein in both human and fish cell lines
(Table 2). In EPC cell, the immunostaining of the glycoprotein was positive using both
MAbs, while in HeLa cells the glycoprotein could be detected only with the MAb IP1H3.
This suggested that the glycoprotein was incorrectly folded.
Table 2. Expression of the VHSV glycoprotein in fish and human cell culture
EPC cells HeLa cells
IP1H3 3F1A2 IP1H3 3F1A2
Poly I:C
10 µg/mL + - + - + - + -
pCMV-Empty -* - - - - - - -
pCMV-vhsG ++ ++ ++ ++ + + - -
pMx-vhsG + - + - - - - -
* No expression detected: -, intermediated expression: +, high expression:++
First vaccination trial: Evaluation EAVR and SAVR
When the challenge was performed at 2 wpv, the fish immunized with the DNA vaccine
with the IFN-inducible Mx promoter (pMx-vhsG), induced protection only in fish
injected with poly I:C. This protection was not due to an antiviral mechanism induced
poly I:C, but an effect of the expression of the glycoprotein since fish injected with the
control plasmid pMx-Empty and with poly I:C were not protected. When this DNA
vaccine was evaluated at 8 wpv, protection was evident independently of the poly I:C
stimulation. The reference DNA vaccine with CMV promoter induced high protection
without stimulation with poly I:C, at both 2 and 8 wpv, respectively. The plasmids
without the G gene did not induce any protection against VHSV (Table 3).
76
Table 3: Early and specific antiviral responses induced by the DNA vaccines against
VHSV
Groups Induction
1wpv
Challenge
2wpv
(RPS)
Challenge
8wpv
(RPS)
pCMV-vhsG NI* 80,7 94,9
pMx-Empty Poly I:C 0 0
pMx-Empty 0.9% NaCl 0 3,1
pMx-vhsG Poly I:C 79,6 77,6
pMx-vhsG 0.9% NaCl 33,7 79,6
*NI: No induction
Second vaccination trial: Evaluation of the LAVR
Vaccination with the DNA vaccine with the CMV promoter provided good protection
against VHSV challenge at 78 weeks post-vaccination. However, the fish immunized
with the DNA vaccine with Mx promoter did not show any protection. Table 4 shows
the average cumulative mortality in the three replicates of each group. The fish
immunized with the pMx-vhsG stimulated with poly I:C showed a lower cumulative
mortality than the control, it was due to only one of the three replicates, which might
be due to an inter-replicate variability and not to a real protective effect (Table 4).
77
Table 4. Long-term antiviral responses induced by the DNA vaccines against VHSV
Groups Induction
68wpv
Challenge 78wpv*
RPS
Saline 0.9% NaCl 8,3 (6,3; 18,7; 0)
Saline Poly I:C 14 (12,4; 23,3; 6,3)
pCMV-Empty 0.9% NaCl 3,9 (5,5; 6,3; 0)
pCMV-vhsG 0.9% NaCl 81,3 (87,5; 62,5; 93,8)
pMx-Empty Poly I:C 14,6 (25,0; 18,7; 0)
pMx-Empty 0.9% NaCl 17,7 (46,9; 0; 6,3)
pMx-vhsG Poly I:C 30,6 (23,3; 49.9; 18,7)
pMx-vhsG 0.9% NaCl 16,6 (0; 0; 49,9)
* RPS values are the average of the three replicates showed in the table.
DISCUSSION
In this study, we performed a functional characterization of a DNA vaccine with an IFN-
inducible Mx promoter derived from rainbow trout. This characterization involved, first,
an analysis of the expression activity in both a human and a fish cell line, and second,
an evaluation of the protection during the three immune response phases, classified
according to the timing and nature of the presumed protective mechanisms and named
EAVR, SAVR and LAVR (Kurath 2006, Kurath and Purcell 2007).
Our in vitro results showed that the DNA vaccine with the IFN-inducible Mx promoter
from rainbow trout was able to promote expression of the VHSV glycoprotein in fish
cells, but not in a human cell line, while the vaccine with the CMV promoter induced
78
expression of the glycoprotein in both fish and human cells. The Mx promoter driven
expression in the EPC cells was dependent on IFN as induced by poly I:C treatment.
Similar results were obtained with a more sensitive luciferase reporter gene setup (not
shown). Taking into account that the intracellular pathway for activating expression of
IFN-inducible elements is highly conserved between teleost and higher vertebrates
(Robertsen 2008; Collet 2014), it seems unlikely that lack of functionality of the trout
Mx promoter in the HeLa cells should be due to a species-specific transcription factors.
However, since the fish EPC cells were grown at 18°C and HeLa cells at 37°, one
possibility could be that temperature dependent conformation of the Mx promoter
region interfered with activation of transcription in the latter. This needs further
analyses to be determined, but lack of activity of the trout Mx promoter in human cells
makes it attractive for use in farmed fish, since this would eliminate concerns about
potential side effects of transgene expression in consumers eating vaccinated fish.
The efficacy of a DNA vaccine depends on several factors. These include the
immunogenicity of the antigen, the degradation rate of the DNA vaccine in the host,
the expression level of the transgene, and the quality of the host immune responses
(Hølvold, Myhr et al. 2014). Since the initial reports of the high efficacy of the CMV
promoter-based DNA vaccines against fish rhabdoviruses (Anderson, Mourich et al.
1996; Lorenzen, Lorenzen et al. 1998), considerable efforts have been made to
identify alternative promoters, not derived from a human pathogenic virus (Alonso,
Johnson et al. 2003; Chico, Ortega-Villaizan et al. 2009; Martinez-Lopez, Chinchilla et
al. 2013). However, these studies have either been based on quantitative expression
analyses in vitro in transfected cell cultures, or included only a single test point in vivo
in terms challenge post-vaccination. Our results demonstrate, that in order to evaluate
the practical application of a DNA vaccine, it is necessary to examine protection against
disease in vivo in all three phases of the immune response to the vaccine.
79
Back in 2003, Alonso et al. reported rather low protection (RPS=16) against IHN in 0.4
g rainbow trout fry following DNA vaccination with a trout Mx promoter IHNV–G gene
construct resembling that used for VHSV-G in the current study. However, despite the
fact that poly I:C was shown to upregulate expression by a factor 7 in vitro, the effect
was not analyzed in vivo. Since the challenge was performed at one month post-
vaccination with fish kept at 13°C, the authors could not exclude that the observed
protection with the CMV promoter reference construct might be due to innate
mechanisms, i.e. the EARV. Accordingly, we here observed protection at the presumed
time of EARV only when pMx-vhsG vaccinated fish were given poly I:C one week prior
to challenge.
Thus, while the Mx promoter has been observed to have a certain base-line activity,
even without stimulation (Alonso, Johnson et al. 2003; Collet, Boudinot et al. 2004;
Martinez-Lopez, Chinchilla et al. 2013), this appeared insufficient to activate a
protective innate response. In contrast, the high protection against VHSV challenge at
8 wpv found in the current study in fish given the pMx-vhsG, even without poly I:C
stimulation, suggested that the base-line activity of the Mx promoter was sufficient to
trigger a protective SAVR. Since the VHSV glycoprotein has been shown to be able to
induce up-regulation of IFN by itself in transfected cell cultures (McLauchlan, Collet et
al. 2003; Acosta, Petrie et al. 2005) an autocrine stimulation might also have been
involved. At the virus challenge performed 78 wpv the response induced by pMX-vhsG
failed to protect the fish, suggesting an insufficient activation of the LAVR as compared
to the high protection among fish given pCMV-vhsG. While it is general knowledge that
IFN and related innate antiviral immune mechanisms are important not only for
protection at the early stage of infection, but also for paving the way for an efficient
adaptive response (Coffman, Sher et al. 2010), our results suggest a lack of direct
interdependency of establishment of protective immunity during the EAVR, SAVR and
80
LAVR phases. It may thus be anticipated that there are qualitative and/or quantitative
differences between the protective -, and the SAVR/LAVR -promoting mechanism of
the EAVR. Similarly, there may be distinct requirements to reach a protective LAVR on
top of, or beside, those needed for a protective SARV. Further experiments including
examination of the specificity of the protection induced by the pMx-vhsG vaccine at
8wpv along with immune gene expression analyses are needed to further resolve this
aspect. Interestingly, Chang et. al. in a recent report showed that while one type of
IFN I was able to provide protection against infectious salmon anaemia virus (ISAV) in
Atlantic salmon, other types of IFN promoted generation of a protective immune
response to a co-injected antigen (Chang, Sun et al. 2015).
In applied terms, our initial hypothesis was that without poly I:C induction shortly after
vaccination of fish with pMx-vhsG, it would be possible to delay the elimination of cells
harboring the plasmid by the local inflammatory response described in fish vaccinated
with pCMV-vhsG (Lorenzen, Lorenzen et al. 2005). This could then allow a later
dynamic management of the fish immune status by activation of the antigen
expression by stimulation of an IFN response, e.g. by feeding the fish with
immunostimulants before moving them to an endemically infected environment. This
strategy clearly failed, possibly because the induced base-line expression of the
antigen by the Mx promoter was sufficient to activate cytotoxic immune reactions to
eliminate transfected cells. However, taking the very long lasting protection reported
here for the pCMV-vhsG vaccinated fish (78 wpv), and the typical 2-3 year lifespan for
cultured rainbow trout into account, there is limited need for improved duration of
immunity. With poly I:C administration shortly after pMx-vhsG vaccination, protective
EAVR and SAVR comparable to those obtained with pCMV-vhsG were reached. Future
experiments should therefore address whether this also counts for LAVR to evaluate
the applied potential an Mx promoter DNA vaccine construct. Finally, it might be
81
possible to combine the attractive safety aspect of the trout Mx promoter with the high
expression capacity of other promoters by making hybrid promoters as recently
reported by Martinez-Lopez et al (2013) (Martinez-Lopez, Chinchilla et al. 2013).
Acknowledgements
This study was supported by Chilean National Scholarship Program for Graduate
Studies Conicyt for DS, and by the European Commission contract FP7311993
TargetFish.
The authors gratefully acknowledge the excellent assistance from the technical staff of
the Fish Health Section, Department of Animal Science, University of Aarhus.
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Kurath, G., K. A. Garver, et al. (2006). "Protective immunity and lack of histopathological damage two years after DNA vaccination against infectious hematopoietic necrosis virus in trout." Vaccine 24(3): 345-354.
Kurath, G., M. Purcell, et al. (2007). "Fish rhabdovirus models for understanding host response to DNA vaccines." CAB reviews 2(1): 1-12.
Lorenzen, E., K. Einer-Jensen, et al. (2000). "DNA vaccination of rainbow trout against viral hemorrhagic septicemia virus: a dose–response and time–course study." Journal of Aquatic Animal Health 12(3): 167-180.
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Lorenzen, E., N. Lorenzen, et al. (2005). "Time course study of in situ expression of antigens following DNA-vaccination against VHS in rainbow trout (< i> Oncorhynchus mykiss</i> Walbaum) fry." Fish & Shellfish Immunology 19(1): 27-41.
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4.3 Manuscript III
Attempt to mimicking antibody-antigen complexes by DNA
vaccination in a fish virus model
Dagoberto Sepúlveda, Jesper Skou Rasmussen, David Parra, Niels
Lorenzen
Intended for submission to Fish and Shell Fish Immunology
86
Attempt to mimicking antibody-antigen complexes by DNA vaccination in a
fish virus model
Dagoberto Sepúlvedaa, Jesper Skou Rasmussena, David Parrab, Niels Lorenzena
a Department of Animal Science, Aarhus University, Denmark.
b Department of Cellular Biology, Physiology and Immunology, Autonomous University
of Barcelona, Spain.
ABSTRACT
DNA vaccines have shown contradictory results inducing protection against fish viral
diseases. While the DNA vaccines against fish rhabdovirus have proved to be highly
protective under different experimental conditions, DNA vaccines against other fish
viral diseases have not shown the same promising results. The low immunogenicity of
the antigen encoded in theses vaccines might be a factor in the induction of low or no
protective immune responses in the host.
Studies in mammals have shown that antigens genetically linked to the
immunoglobulin Fc domain of IgG elicited a superior immune response compared to
the antigen without the Fc domain presumably by promoting an efficient uptake
mediated by Fc-receptors on immune cells. Here, we aimed at applying this approach
to DNA vaccination of fish in order to develop a generic strategy for enhancing the
immunogenicity of the expressed antigen. A low protective DNA vaccine encoding the
secreted form of the VHSV glycoprotein (Gs) was used as a model.
87
While cell cultures transfected with the DNA vaccine plasmids encoding Gs secreted the
recombinant protein into the supernatant, the Fc-fusion proteins could only be
detected in the cell fraction of such cultures.
The in vivo evaluation showed that no protection was induced by the DNA vaccines
encoding either Gs-Fc or Gs. However, due to the absence of secretion in vitro, we
could not conclude that Fc-fusion protein approach did not work as an enhancer of the
immunogenicity of the antigen. Structural differences between fish and mammalian Fc
domains might explain the difficulties with the implementation of this approach in fish.
Therefore, further optimization of the secretion of the fish Fc-fusion protein design is
probably needed.
INTRODUCTION
DNA vaccines against fish rhabdovirus, such as viral haemorrhagic septicaemia virus
(VHSV), infectious haematopoietic necrosis virus (IHNV), and hirame rhabdovirus
(HIRRV) have been able to induce high level of protection under different experimental
conditions (Anderson, Mourich et al. 1996; Heppell, Lorenzen et al. 1998; Takano,
Iwahori et al. 2004). The effectiveness of these vaccines relies on: (i) the high
immunogenicity of the viral glycoprotein encoded by these DNA vaccines (Bearzotti,
Monnier et al. 1995; Winton 1996), and (ii) the fact that DNA vaccination allows the
activation of different protective immune mechanisms in the host (Liu 2011). Shortly
after intramuscular injection of the DNA vaccine against VHSV in rainbow trout, the
expression of the glycoprotein by the host induces an early and non-specific protection,
which is orchestrated by the up-regulation of interferon type I (IFN I), a central
antiviral component of the innate immunity (Boudinot, Blanco et al. 1998; Lorenzen,
Lorenzen et al. 2002; Acosta, Petrie et al. 2005). The non-specific protection is
followed by a specific protection associated with both mechanisms of the adaptive
88
immunity, the cellular and humoral immune responses (LaPatra, Corbeil et al. 2000;
Utke, Kock et al. 2008).
However, the promising results of the DNA vaccine against fish rhabdovirus have not
been replicated for other viruses that affect aquaculture industry. Experimental DNA
vaccines against infectious salmon anemia virus (ISAV) and infectious pancreatic
necrosis virus (IPNV) have induced relatively low protection (Mikalsen, Torgersen et al.
2004; Mikalsen, Sindre et al. 2005; Munang’andu, Fredriksen et al. 2012), while the
DNA vaccines against salmon alphavirus (SAV) and Atlantic halibut nodavirus (AHNV)
have shown not protection at all (Sommerset, Skern et al. 2005; Xu, Mutoloki et al.
2012).
An efficacious vaccine should involve a high immunogenic antigen, which is recognized
as a dangerous molecule by the host immune system, and consequently, activate
multiple protective mechanisms involving both innate and adaptive immune
mechanism. A low protective DNA vaccine against ISAV, encoding the hemagglutinin
had significantly increased efficacy when co-injected with a plasmid encoding type I
interferon (IFN). This indicates that the hemagglutinin by itself was incapable of
inducing the innate antiviral responses necessary to trigger a protective adaptive
response (Chang, Sun et al. 2015). Therefore, enhancing the immunogenicity of an
antigen could be a strategy to improve the protection induced by the related DNA
vaccine against a viral fish disease.
The Fc-fusion proteins could be an alternative to increasing immunogenicity of
antigens. The Fc-fusion proteins consist of an active protein (e.g. antigen) genetically
linked to an Fc domain of an immunoglobulin (Levin, Golding et al. 2015). Initially, the
Fc-fusion proteins were used to extend the half-life of the active protein, prolonging
the activity of therapeutic proteins in the blood stream, because an immunoglobulin Fc
domain avoids the endosomal degradation of the active protein (Roopenian and Akilesh
89
2007). Additionally, the presence of an Fc domain has been used to improve stability
and solubility of some proteins, as well as to allow protein purification by using protein
G/A affinity matrices (Rath, Baker et al. 2013).
Nevertheless, the capacity of the IgFc domain to engage specific cellular receptors
(FcR) and thereby modulate the immune response of the host, is one of the most
important properties of the Fc-fusion proteins, that have driven their application within
different therapeutic purposes. Some of the response mechanisms modulated by Fc-
fusion proteins are; phagocytosis, activation of the antibody-dependent cell mediated
cytotoxicity (ADCC) by natural killer cells, or the complement-dependent cytotoxicity
(CDC) (Shinkawa, Nakamura et al. 2003; Levin, Golding et al. 2015). Specifically for
vaccine application, the Fc domain can improve the efficacy by which the antigen is
recognized by FcRs on antigen presenting cells (APC), thereby enhancing the take up,
process, and antigen presentation (Soleimanpour, Farsiani et al. 2015). Vaccination of
mice with antigens from either HIV or influenza virus linked to the Fc domain of IgG2a,
thus induced a more effective immune response than the antigen alone (Loureiro, Ren
et al. 2011; Zaharatos, Yu et al. 2011).
In this study, we made the first attempts to design and evaluate a DNA vaccine
encoding an Fc-fusion protein for vaccination against VHSV, as a model of a generic
DNA vaccine design for fish. In order to evaluate any improvement in the protection
induced by this approach, a low protective DNA vaccine that encoded the secreted
form of the VHSV glycoprotein (Gs) was compared to DNA vaccines encoding the Gs
genetically linked to the Fc domain (Gs-Fc) of each of the three rainbow trout
immunoglobulin isotypes (IgM, IgT, and IgD).
90
MATERIALS AND METHODS
Cell culture. Epithelioma papulosum cyprinid (EPC) cells (Fijan, Sulimanović et al.
1983) and bluegill fry (BF2) cells (Wolf, Gravell et al. 1966) were used in this work.
Both cell lines were maintained at 15°C in minimal essential medium (MEM)
supplemented with 10% fetal bovine serum (FBS), 2 mM L-glutamine, and 100 U/mL
of Penicillin and 100 µg/mL of Streptomycin antibiotics.
Virus. DK-3292b VHSV isolate was propagated in BF2 cells. The cell culture was
infected with a low multiplicity of infection (MOI). When a complete cytopathic effect
was observed, the supernatant was collected and centrifuged at 4500 x g for 15 min at
4°C. The virus was stored at -80°C. Virus titer was determined using tissue culture
infectious dose per mL (TCID50 /mL) (Reed and Muench 1938).
Amplification of Fc domains of rainbow trout immunoglobulins. Total RNA was
isolated from spleen from rainbow trout stored in RNAlater at -20°C, using the RNeasy
mini kit (Qiagen). The cDNA was synthesized from 500 ng of the isolated RNA with
iScript (Bio-Rad) according to the procedure recommended by the manufacturer. The
PCR amplification was performed with the primers listed in Table 1. The primer design
was based on the sequence of the secreted form of each immunoglobulin isotype of
rainbow trout; IgM (Genebank No: AY870259.1), IgT (Genebank No: AY870268.1),
IgD (Genebank No:JQ003979.1).
For each fish immunoglobulin, two versions of the Fc domain were amplified. One
version consisted of the Fc region of the 3 C-terminal CH domains of the secreted
immunoglobulin molecule, here called “long-Fc”(LFc). The second version was the
short-Fc (ShFc), which included only the most C-terminal CH domain of the Fc region
(Figure 2). For the amplification of each immunoglobulin Fc isotype, two forward
primers (short-Fc and long-Fc) and one reverse primer with the stop codon were used.
91
The forward primers contained the Sal I restriction site while the reverse primer
contained the EcoRI restriction site to allow insertion into the expression vector.
The PCR amplification was carried out with the high fidelity DNA polymerase, Herculase
II Fusion (Agilent Technology) according to the recommendations of the manufacturer.
The estimated annealing temperature of the primers was 57°C. The size of the
amplicons was checked by agarose gel electrophoresis.
Table 1. Primers used to amplify the different Fc domains of fish immunoglobulins
Primer name Sequence 5’-3’
IgM-short-Fc- SalI-For ATATAT GTCGAC CAGCGTCCATCTGTCTTTC
IgM-long-Fc- SalI-For TTATAT GTCGAC CAGCCGTCTCTTTACGTAATG
IgM-Stop-EcorRI-R CTGCAT GAATTC CCTCTACTGGGCCATGCATC
IgT-short-Fc- SalI-For ATATAT GTCGAC TCTGTGTCCGTCCACATTC
IgT-long-Fc- SalI-For TTATAT GTCGAC CTGATGTGTATGATTGAAGATTTC
IgT-Stop-EcorRI-R ATATAT GAATTC TTACTTGTCTTCACATGAGTTAC
IgD-short-Fc- SalI-For ATATAT GTCGAC TCAGTGACCCCCTCCGC
IgD-long-Fc- SalI-For ATATAT GTCGAC GAACTCCTTCTAGTCCCCAG
IgD-Stop-EcorRI-R ATATAT GAATTC TTATATCAGAATTGAGTGAACGGAC
Bold sequence: endonuclease restriction sites
Underline sequence: stop codon
Plasmids. The pVax1 vector (Thermo Fisher Scientific) was used as the expression
vector in this work. According to Figure 1, the Fc-fusion proteins had three sections
inserted between HindIII and EcoRI of pVax1. The first section, named Gene1,
consisted of the secreted form of the VHSV glycoprotein (Gs), which consisted in the
sequence from the position 1 to 1356 of the full-length glycoprotein gene. The second
section consists of a flexible linker to avoid interferences between active protein (Gs)
92
and the Fc domain. The linker sequence involved 3 repetitions of the amino acidic
sequence Gly-Ser-Ser-Ser. The third section, named Gene2, which consist of the
different Fc domains amplified from different fish immunoglobulins. One construct only
contained Gs and the linker, to evaluate if the linker interfered with the Gs secretion.
Additionally, two DNA vaccines were used as a reference, first a highly protective DNA
vaccine that encodes the full-length VHSV glycoprotein (1521bp) and second, the DNA
vaccine that encode only the Gs. All constructs used in this work are summarized in
Table 2. Conventional cloning procedures were used to make all constructs. The
purification of the constructs were performed with Endofree plasmid Megaprep kit
(Qiagen). All constructs were sequenced using generic external primers for the CMV
promoter and polyadenylation signal, and with the primers listed in Table 1.
Figure 1: Scheme of the different sections of the Fc-fusion constructs inserted into the
expression vector. The antigen part is where both the full length and the secreted form
of the VHSV glycoprotein were inserted. The Fc domain part is where both versions of
the Fc domain of each fish immunoglobulin isotypes were inserted.
93
Table 2. Constructs for vaccination
Name Antigen part
(5’-end) Linker
Fc domain part
(3’-end)
pVax-vhsG Gfulla ---- ----
pVax-Gs Gsb ---- ----
pVax-Gs-Lc Gs (GSSS)3 ----
pVax-Gs-L-ShFc-IgM d Gs (GSSS)3 ShFc-IgM (short)
pVax-Gs-L-LFc-IgMe Gs (GSSS)3 LFc-IgM (long)
pVax-Gs-L- ShFc-IgT Gs (GSSS)3 ShFc-IgT (short)
pVax-Gs-L- LFc -IgT Gs (GSSS)3 LFc-IgT (long)
pVax-Gs-L- ShFc-IgD Gs (GSSS)3 ShFc-IgD (short)
pVax-Gs-L-LFc-IgD Gs (GSSS)3 LFc-IgD (long)
a Gfull: it is full-length of the VHSV glycoprotein gene (1521 bp) including the
transmembrane domain.
b Gs: secreted form of the VHSV glycoprotein gene (1356 bp) without the
transmembrane domain.
c ”L” refers to the linker peptide.
d “ShFc” refers to the short variant of the Fc domain part (Fig 2)
e “LFc” refers to the long variant fo the Fc domain part (Fig 2)
94
Figure 2. Short and long versions of the Fc domain in the Fc-fusion proteins. (A)
Structure of the heavy chain of a fish immunoglobulin. The secreted forms of IgM and
IgT have the same structure showed in this scheme, while the secreted form of IgD
possess 7 CH domains instead of 4. (B) Short and long versions of the Fc-fusion protein
encoded in the DNA vaccines. The Gs in the figure correspond to the extracellular
domain of VSV glycoprotein in order represent the Gs part of the Fc-fusion protein. The
glycoprotein was taken from (Garry and Garry 2008).
Transfection. In a 24-well plate, 2x105 cells/well were seeded 24 hrs. before the
transfection. The day of the transfection, the medium of each well was replaced for
250 µL of fresh MEM with 10% serum. The transfection solution was performed mixing
0.75 µg of each construct and 2µg of PEI, in a total volume of 250 µL of MEM without
serum. The transfection solution was incubated for 20 min at room temperature and
then added to one well, to have a final volume of 500 µL. This procedure was carried
out with each construct described in Table 2. The transfected cell cultures were
incubated at 28°C for 5 hrs. Then the medium of each well was replaced for 400 µL of
95
fresh MEM with 10% serum and maintained at 15oC until the evaluation of the
supernatant and the cell monolayer were performed.
ELISA. At 7 days post-transfection, the supernatant and cell lysate were collected to
evaluate the amount of Fc-fusion proteins in each fraction. The cells were lysed using
in each well 150 µL of lysis buffer (150 mM NaCl, 10 mM Tris, 1% Triton x-100, and
protease inhibitors) after removing the supernatant. In a 96-well plate coated with
rabbit anti-VHSV glycoprotein, 50 µL of either supernatant or cell lysate was added to
each well and incubated for 1hr at room temperature. For detection of bound VHSV G
protein, the primary antibody used was a mouse monoclonal anti-VHSV glycoprotein
IP1H3 (Lorenzen, Olesen et al. 1988). An HRP-conjugated rabbit anti-mouse IgG
(DAKO P0260) was used as secondary antibody.
Vaccination. Outbreed rainbow trout (5-10 gr.) were anesthetized in 0.01%
benzocaine. The immunization was performed with 3 µg of plasmids dissolved in 50µL
of saline solution (0,9% NaCl) per fish. The fish were divided into two groups; one
group was vaccinated with an intraperitoneal injection (I.P), while another group with
an intramuscular injection (I.M). The fish were kept in aerated 120L aquaria with
recirculated water at 8-10°C. The immunization was performed with a mixture
containing 1 µg of each of the three constructs with the short-Fc, as one treatment.
The same was performed with the long-Fc constructs.
Challenge. At 7 weeks post vaccination, the fish were transferred to aerated 8 L
aquaria in a contained facility. Each treatment was tested in duplicate with 18-20 fish
per aquarium. The infection was performed by immersion in static water with the VHSV
isolated DK3592b, used with an infectious dose of 1x105 TCID50 mL-1. The water flow
was re-established after 3 hrs. The fish were monitored 3 times per day for 30 days.
Fish with evident clinical sign of the disease or with compromised welfare were
euthanized by an overdose of benzocaine.
96
Statistical analysis
The statistical analysis was performed using t-test with R. Statistical significance was
considered when p<0.05.
RESULTS
Evaluation of the antigen localization in transfected cell cultures
The comparative analysis showed that while the Gs expressed by transfected cell was
mostly secreted into the supernatant, the Gfull, was mostly detected in the cellular
fraction, as expected and presumably due to the presence of the transmembrane
domain, (Figure 3A).
At 7 days post-transfection, the cell cultures transfected with the DNA vaccine
encoding the Gs (pVax-Gs) and Gs with the linker (pVax-Gs-L) had recombinant G
protein mainly in the supernatant. However, the cell cultures transfected with the DNA
vaccines encoding the various Fc-fusion proteins (Gs-Fc) we all had the fusion proteins
retained in the cellular fraction (Figure 3B).
97
Figure 3. Secretion profile in vitro of the DNA vaccines encoding: (A) Gs and Gfull,
and (B) the Fc-fusion proteins. The difference between the secreted and retained
fraction was statistically significant (p<0,05).
Evaluation of the immune protection induced by a DNA vaccine encoding the
Fc-fusion proteins
The DNA vaccines that encode any of the Fc-fusion proteins were not able to induce
protection against VHSV in rainbow trout fingerlings. Moreover, no difference was
observed when the immunization was performed either by I.P or I.M. The DNA vaccine
that encode the full-length glycoprotein (pVax-vhsG) induced protection when was
injected I.M (Figure 6), while no protection was observed by I.P injection. In one of the
replicate aquaria with fish injected with pVax-vhsG a tail-biting activity of some of the
fish led to termination of more than 50% of the population due to welfare concerns.
This aquaria was excluded from the data.
98
Figure 4. Protection against VHSV challenge induced by the DNA vaccine encoding the
Fc-fusion proteins. Each DNA vaccine was injected intraperitoneally (I.P) and
intramuscularly (I.M).
DISCUSSION
The immunogenicity of antigen is fundamental to trigger the innate and adaptive
immune responses establishment of protection against disease (Loureiro, Ren et al.
2011; Zaharatos, Yu et al. 2011; Thim, Villoing et al. 2014; Chang, Sun et al. 2015).
In this work, we evaluated whether it was possible to improve the protection induced
by a DNA vaccine that encodes a secreted antigen (Gs) by linking the antigen to a fish
immunoglobulin Fc domain.
Because, this was the first attempt to develop the Fc-fusion protein approach applied
to fish viral diseases, we took into account:
(i) It is known that an Fc domain of a specific immunoglobulin isotype has specific
effector functions. For instance, an antigen linked to an Fc domain from IgG2a elicited
superior humoral responses compared to the antigen linked to the Fc domain of IgG1
in mice (Zaharatos, Yu et al. 2011). The Fc-fusion proteins developed here comprised
the Fc domain of all three fish immunoglobulin isotypes (IgM, IgT, and IgD).
(ii) In mammals, the first constant domain of the immunoglobulin heavy chains (CH1)
binds a chaperone protein (BIP) in the endoplasmic reticulum (ER) (Elkabetz, Argon et
al. 2005). BIP releases the immunoglobulin only when heavy chain binds light chain.
Heavy chains without the CH1 domain can be secreted as a monomer without the
presence of the light chain. Whether fish immunoglobulin heavy chains follow the same
mechanisms is unknown. Therefore, two versions of the fish immunoglobulin Fc
domain were linked to the antigen and tested in this study. The long-Fc version
99
corresponded to the full-length Fc domain of IgM and IgT, respectively (Figure 2B).
The short-Fc version was designed to evaluate whether a potential retention of the
heavy chain could be due to other regions beside CH1 (CH2, CH3). Because, it has to be
taken into account the absence of hinge region in fish immunoglobulins, a natural
separation between CH1 and the Fc domain.
The in vivo trial showed no protection induced by the vaccination with any of the DNA
vaccines encoding the Fc-fusion proteins. Additionally, no differences were observed
related to the route of delivery (I.P vs I.M). Similarly, the DNA vaccine encoding the
non-linked Gs was not able to induce protection against VHSV. The DNA vaccine that
encodes the full-length glycoprotein was only able to induce protection in fish when it
was injected I.M. Taking into account that the effect of certain vaccines is different
according to the delivery route, here we evaluated both I.P and I.M immunizations
(McLauchlan, Collet et al. 2003; Martinez-Lopez, García-Valtanen et al. 2013).
Our results confirm the assumption that the immune mechanism by which the
immunogenicity of an antigen is enhanced using the Fc-fusion protein approach
requires secretion of the antigen, thereby allowing the interaction of Fc domain with Fc
receptors on specific immune cells. Therefore, due to the absence of secretion
observed in cell culture and likely in vivo, we could not conclude that the Fc-fusion
protein approach in fish was not able to induce protection in rainbow trout fingerlings.
Optimizing the secretion of the Fc-fusion proteins will be necessary to assess their real
capacity to induce protection in fish.
It has been described that the amino acidic sequence in the C-terminal of the Fc
domain, determine the secreted or membrane bound form of the immunoglobulins.
However, for IgM and IgA of mammals, the C-terminal has also been associated with a
control mechanism to secrete immunoglobulin with the correct polymerization (Guenzi,
Fra et al. 1994). Beside the CH1 domain, a cysteine close to the C- terminal of the
100
secreted form of the heavy chain cause cellular retention. Similarly, the secreted form
of fish immunoglobulins also has a cysteine close to the C-terminal that could be
causing the cellular retention of the Fc-fusion proteins designed here (Table 3).
Therefore, to perform an evaluation of the protection induced by a DNA vaccine
encoding the Gs-Fc is fundamental to optimize the secretion of the different Fc-fusion
protein. In order to do so, the first step would be to modify the cysteine in the C-
terminal of the Fc domains of the fish immunoglobulins.
Table 3. C-terminal tail of murine and fish immunoglobulins.
Isotype Sequence
Murine IgG Murine IgE Murine IgD Murine IgM Murine IgA RT IgM RT IgT RT IgD
G K G K N T S L R P S G C Y H L L P E S D G F S R R P D G P A L A G K P T L Y N V S L I M S D T G G T C Y G K P T N V S V S V I M S E G D G I C Y I D R T S N Q P N L V N L S L N V P Q R C M A Q G S D N S T S P K E M S V S K S T G N S C E D K L A L N I S K P G V C L S V H S I L I
RT: Rainbow Trout
Cysteines (C) in the C-terminal tail of the murine and fish immunoglobulins are
underlined.
However, it is important to consider that fish immunoglobulins are not structurally
identical to mammals’ immunoglobulins. For instance, fish antibodies lack the hinge
region, and the J peptide, and while the most prevalent form of fish IgM in serum is
tetrameric, it is pentameric in mammals. Therefore, it is possible that, compared to
mammalian Ig, other elements in the fish immunoglobulin Fc domains could affect the
secretion of Fc-fusion proteins.
This work represents the first attempt to apply the Fc-fusion protein approach in a
vaccine against a fish viral disease. Taking into account that in mammals, the Fc-fusion
proteins have not only showed potential as a therapeutic strategy, but also as a
molecular tool to determine how the Fc domain works modulating the immune system,
101
a functional Fc fusion protein would have a huge potential to elucidate important
aspects of the effector mechanisms driven by the humoral immune responses in
teleost.
Acknowledgements
This study was supported by the Chilean National Scholarship Program for Graduate
Studies (Conicyt) for DS, and by the European Commission contract FP7311993
TargetFish.
The authors gratefully acknowledge the excellent assistance from the technical staff of
the Fish Health Section, Department of Animal Science, University of Aarhus.
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5. Part IV: General discussion and perspectives
Since the first time that the DNA vaccines against VHSV and IHNV were successfully
evaluated in fish in the late 1990’s (Anderson, Mourich et al. 1996; Heppell, Lorenzen
et al. 1998), several studies have contributed to understand many aspects of
protection induced by DNA vaccines, among them (i) what mechanisms were triggered
by DNA vaccines, (ii) what environmental or physiological factors could affect the
protection induced by these vaccines, and (iii) the duration of each type of protective
mechanism. At the beginning, the focus of these studies was driven by the commercial
purpose of developing an immunization strategy to fight serious viral diseases that
affect aquaculture industry (Corbeil, LaPatra et al. 1999; Corbeil, Kurath et al. 2000;
LaPatra, Corbeil et al. 2000; Lorenzen, Einer-Jensen et al. 2000). All these knowledge
led to license and use of a DNA vaccine against IHNV in 2005 (Salonius, Simard et al.
2007). Besides the commercial aspect of developing effective prophylactic measures to
control viral diseases, DNA vaccines have also been a useful tool to obtain a better
understanding of how the fish antiviral immunity works (Lorenzen, Lorenzen et al.
2002; Kurath, Purcell et al. 2007).
This thesis was divided into two sections according to the addressed topics. The first
part, include manuscript I, aimed at evaluating of whether repeated passaging of VHSV
in vaccinated fish would promote the virus to break through the protection and cause
disease. The second part used the DNA vaccine against VHSV as a model to evaluate
two new DNA vaccine designs, which could potentially improve the safety and general
applicability of DNA vaccine in farmed fish.
106
5.1 Section I
5.1.1 Manuscript I
The results suggested that there is a low probability that VHSV might generate and
select a variant that escapes from any of the protective mechanisms induced by the
DNA vaccine in a short time: the early antiviral responses, the specific antiviral
responses, and the neutralizing antibodies from immunized rainbow trout sera.
Although this is an advantage in term of applicability of DNA vaccine, one factor to
consider is that the experimental setup used here was designed to evaluate the
selection of escape mutants under highly protective immunization conditions, which
included:
(i) The vaccination was carried out with a highly protective dose of the DNA
vaccine.
(ii) The DNA vaccine used encoded the homologous VHSV glycoprotein to the one
encoded by the virus used in the challenge.
However, it is important to take into account that this work did not cover the
possibility of VHSV could generate and select escape mutants upon less protective
vaccination conditions or after more passages of VHSV infection in vaccinated fish.
5.2 Section II
This part focused on the characterization of the immune protection induced by two
innovative DNA vaccine approaches. These approaches took advantage of our
knowledge of the fish immune system and applied immune elements from the innate
and adaptive arms, respectively, to modulate the vaccine effect in order to improve
safety and applicability of DNA vaccines in general.
107
5.2.1 Manuscript II
The analysis of the first vaccine approach was described in the manuscript II. In
agreement with safety guidelines, the DNA vaccine tested in this manuscript consisted
of an expression vector with a trout-derived interferon-inducible Mx promoter, which
control the expression of VHSV glycoprotein in the host, instead of the human
cytomegalovirus (CMV) promoter, which has been used in the extensively analyzed
DNA vaccine against VHSV (Heppell, Lorenzen et al. 1998; Lorenzen, Einer-Jensen et
al. 2000).
The manuscript II showed a time-course study to evaluate whether the fish immunized
with DNA vaccine with Mx promoter was able to mount the three phases of antiviral
responses: early antiviral responses (EAVR), specific antiviral responses (SAVR), and
long-term antiviral responses (LAVR). Furthermore, because of the inducible feature of
this DNA vaccine, it was also possible to understand how different expression levels of
the glycoprotein affect the induction of the different protective phases.
The results in manuscript II agreed with the model that DNA vaccination induces three
phases of antiviral responses (Kurath, Purcell et al. 2007), also indicating that each
phase needs to be activated independently. In the specific case of the activation of
SAVR and LAVR, both antiviral responses are associated with the adaptive immune
responses. However, this does not mean that the activation of an efficacious SAVR
involves the activation of an efficacious LAVR. Indeed, the DNA vaccine with Mx
promoter without stimulation with poly I:C showed no induction of LAVR even when an
efficient SAVR was induced. Many vaccine evaluations published are performed
between 1-3 month post vaccination or 300-900 degree days. However, in order to
evaluate different protective mechanisms is suggested that the evaluation of any
vaccine for aquaculture should include a challenge to test specifically the LAVR.
108
It is well known, that to mount an efficacious adaptive immunity by vaccines is
necessary to trigger mechanisms associated with innate responses (Coffman, Sher et
al. 2010). Although it requires further experiments, the results of the protection
induced by the DNA vaccine with CMV and Mx promoter, suggested that the innate
antiviral responses (EAVR) could be either protective or the non-protective, and both
could be able to trigger a protective SAVR. However, the activation of LAVR might
require triggering additional and more complex mechanisms that are present only in
the protective innate antiviral responses (Figure 7).
Figure 7. Model of induction of SAVR and LAVR by innate responses. (A) without
innate responses is not possible to activate SAVR or LAVR. (B) non-protective innate
antiviral responses are able to trigger the activation of SAVR. (C) Protective innate
antiviral responses are able to trigger the activation of SAVR and LAVR.
109
Future perspectives
The fish-derived promoter and the selective expression of the antigen in fish cell and
not in human cell line are two preferable characteristics in a DNA vaccine developed for
aquacultured fish. However, it seems that the low expression activity of Mx promoter
under stimulation of poly I:C is not sufficient to mount an effective long-term antiviral
response. An alternative strategy, based on the work presented in Martinez-Lopez et al
(2012), could be design a hybrid promoter combining the enhancers or the promoter
cores from other fish-derived promoters in order to keep the preferable features of the
Mx promoter, but with a high expression activity to effectively trigger all three phases
of the host antiviral responses, similar to the protection induced by the DNA vaccine
with the CMV promoter (Martinez-Lopez, Chinchilla et al. 2012).
Additionally, further experiments should involve a gene expression analysis comparing
the innate responses induced by the DNA vaccine with the Mx promoter and the CMV
promoter. These results would help to understand the specific innate responses
required to induce SAVR and/or LAVR. This knowledge might be applied to adjuvants
development, which would be able to induce specific pathways of the innate immunity
according to the characteristic of the vaccine, reducing the side effects of the
traditional adjuvants used in fish vaccination.
5.2.2 Manuscript III
The second DNA vaccine approach evaluated in this section was described in the
manuscript III. This manuscript showed the first attempt to apply the Fc-fusion protein
approach to increase the immunogenicity of the fish-derived antigen. In order to apply
this approach, the DNA vaccine against VHSV was used as a model for further
development of a generic vaccination strategy that can be used against other viruses
that affect finfish aquaculture.
110
The secretion of Fc-fusion proteins is fundamental to allow the Fc domains to engage
FcR on immune cells. Taking into account that cell cultures transfected with the DNA
vaccines encoding the Fc-fusion proteins showed no secretion of these proteins, it is
logical to think that an in vivo infection trial should fail in inducing protection.
Nevertheless, the preliminary in vivo trial was carried out for two reasons: First, it
might be that undetectable levels of the Fc-fusion proteins were indeed secreted in cell
culture, which could be sufficient to induce protection against VHS. Second, although
the Fc fusion protein were retained inside the cells, these proteins could be released
upon cellular lysis associated with the production of the Fc-fusion protein, which would
allow the Fc domains bind the FcRs on immune cells and trigger the immune response.
The in vivo and in vitro results suggested that the retention of the Fc-proteins was
likely caused by a region in the C-terminal of the Fc domains. This agreed with the fact
that IgM and IgA from mammals are retained inside the cell even after removing the
CH1 domain, similar to what occurs with the constructs studied in this study (Sitia,
Neuberger et al. 1987; Guenzi, Fra et al. 1994). The analysis of mammals´ IgM and
IgA showed that this retention was due to a cysteine closer to C-terminal. Fish
immunoglobulins also have a cysteine close to the C-terminal, which might be
interfering with the secretion.
Future perspectives
The next steps to develop the Fc-fusion proteins approach against fish viruses should
include modifying the C-terminal of the Fc domain of each fish immunoglobulin isotype
in order to optimize the secretion of these proteins in cell culture (Sitia, Neuberger et
al. 1987; Sitia, Neuberger et al. 1990). After the optimization of the Fc-fusion protein
secretion, it should be necessary to carry out a new in vivo infection trial, but in this
experiment, each vaccine will be evaluated individually, instead of mixing them like in
the preliminary trial described in manuscript III. This analysis could also provide some
111
knowledge about the specific function of Fc-domain of each fish immunoglobulin
isotype.
Additionally, it has been reported that certain mutations in the Fc-domain of IgG have
allowed modulating specific immune responses according to the therapeutic
applications. Therefore, it should be interesting to explore this principle with the fish Fc
domains to understand effector mechanisms triggered by fish.
112
6. Concluding remarks
The three manuscripts, on which this Ph.D. thesis is based, provide significant
new knowledge on functional aspects of the immune protection induced by
DNA vaccination of rainbow trout against VHS virus under experimental
conditions. The main results of the studies are listed in the following.
Section I
Manuscript I: “Can VHS virus bypass the protective immunity induced by
DNA vaccination in rainbow trout?”
- After repetitive passages of VHSV in rainbow trout immunized with the
DNA vaccine, the virus did not generate variants capable of bypassing
the innate and adaptive protection induced by the DNA vaccine.
- No neutralization resistant VHSV escape variants were found after
repetitive passaging of VHSV in cell culture in the presence of serum
from rainbow trout immunized with the DNA vaccine.
- When examined shortly after inoculation with VHSV, some vaccinated
healthy fish appeared to be carriers of infection. Such carriers could
transmit the infection to cohabitant naïve fish.
113
Section II
Manuscript II: “Time-course study of the immune protection induced by an
interferon-inducible DNA vaccine against viral haemorrhagic septicaemia
virus in rainbow trout”
- The DNA vaccine with Mx promoter allowed differential antigen
expression in cell lines of fish and human origin, respectively. Only the
transfected fish cell line expressed the glycoprotein upon stimulation
with IFN inducer poly I:C.
Both fish and human cell lines transfected with the DNA vaccine with the
CMV promoter constitutively expressed the glycoprotein.
- Immunization with the DNA vaccine with the Mx promoter induced
protective EAVR and SAVR upon stimulation with poly I:C, while only
protective SAVR was induced without stimulation.
- Despite stimulation of a protective SAVR, the DNA vaccine with Mx
promoter was not able to induce a similar long-term protection, as
observed in the DNA vaccine with the CMV promoter.
- The results suggest a lack of direct relationship between protection in
the three phases of the immune response to the DNA vaccination. This
stresses the importance of testing new vaccines throughout the full
response profile.
114
Manuscript III: “Attempt to mimicking antibody-antigen complexes by DNA
vaccination in a fish virus model”
- None of the Fc-fusion proteins designed in this work were secreted from
transfected cell cultures.
- No protection against VHS was induced in rainbow trout fingerlings by
the DNA vaccines encoding the Fc-fusion proteins or the Gs alone.
- Optimization of the fusion gene design to obtain antigen that can be
secreted is probably necessary to perform a proper evaluation of the
prophylactic potential of Fc-fusion proteins as vaccines against fish
diseases.
115
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