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Characterization of functional properties of Enteroccoccus
feacium strains isolated from human gut
Journal: Canadian Journal of Microbiology
Manuscript ID cjm-2015-0446.R2
Manuscript Type: Article
Date Submitted by the Author: 11-Sep-2015
Complete List of Authors: Đspirli, Hümeyra; Bayburt University Demirbaş, Fatmanur ; Bayburt University Dertli, Enes; Bayburt University, Department of Food Engineering
Keyword: Gut bacteria, Enterococcus faecium, probiotic, virulence determinants, antibiotic resistance
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Characterization of functional properties of Enteroccoccus feacium strains
isolated from human gut
Hümeyra Đspirli, Fatmanur Demirbaş and Enes Dertli *
Department of Food Engineering, Faculty of Engineering, Bayburt University, Bayburt,
Turkey
* Enes Dertli, Department of Food Engineering, Faculty of Engineering, Bayburt University,
Bayburt, 69000, Turkey Tel: +90 (0) 458 2111153, Fax: +90 (0) 458 2111172, Email:
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Abstract
The aim of this work was to characterize the functional properties of Enterococcus faecium
strains identified after isolation from human faeces. Of these isolates strain R13 showed the
best resistance to low pH, bile salts and survival in the simulated in vitro digestion assay and
demonstrated an important level of adhesion to hexadecane as a potential probiotic candidate.
Analysis of the antibiotic resistance of E. faecium strains indicated that in general these
isolates were sensitive to the tested antibiotics and no strain appeared to be resistant to
vancomycin. Examination of the virulence determinants for E. faecium strains demonstrated
that all strains contained the virulence genes common in gut and food originated enterococci
and strain R13 harboured the lowest number of virulence genes. Additionally no strain
contained the genes related with the cytolysin metabolism and showed hemolytic activity.
The antimicrobial role of E. faecium strains were tested against several pathogens in which
different levels of inhibitory effects were observed and strain R13 was inhibitory to all tested
pathogens. The PCR screening of genes encoding enterocin A and B indicated the presence
of these genes in E. faecium strains. Preliminary characterization of bacteriocins revealed that
their activity was lost after proteolytic enzyme treatments but no alteration in antimicrobial
activity was observed at different pHs (3.5 to 9.5) and after heat treatments. In conclusion this
study revealed the functional characteristics of E. faecium R13 as a gut isolate and this strain
could be developed as a new probiotic after further tests.
Keywords: Gut bacteria, Enterococcus faecium, probiotic, virulence determinants, antibiotic
resistance,
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Introduction
Besides their role in environmental, clinical and food microbiology, Enterococci that are
members of lactic acid bacteria (LAB), are regular residents of GI (gastrointestinal) tract of
humans and animals (Pieniz et al. 2014). This advances their potential as being probiotics that
are live microorganisms which when administered in adequate amounts confer a health
benefit to the host (Nueno-Palop and Narbad 2011). Importantly several Enterococcus strains
were used as probiotics that might improve intestinal health and decrease the serum
cholesterol levels (Giraffa 2003; Hlivak et al. 2005).
Selection of probiotics depends on the essential characteristics that probiotics fulfil which
include the ability to survive under harsh environment of GI tract such as low pH, acid, bile
and gastric conditions and their adhesion capacity (Dunne et al. 2001). Additionally antibiotic
resistance and production of antimicrobial substances are also important for selection of
probiotics from safety and functional perspective of view, respectively (Ogier and Serror
2008). Several studies showed the probiotic potentials of both food and human originated
enterococci including Enterococcus faecium strains (Bhardwaj et al. 2010; Nueno-Palop and
Narbad 2011; Pieniz et al. 2014) and enterococci are also well know for the production of
enterocins that are a class of bacteriocins which can be able to inhibit the growth of
pathogenic organisms (Franz et al. 2007). But the presences of clinical enterococcal species
that may have pathogenic effects require not only determination of antibiotic resistance
profile but also the assessment of virulence genes of enterococci (Nueno-Palop and Narbad
2011). Additionally there is not a clear discrimination of pathogenic and safe enterococcal
strains and the latter might harbour virulence factors (Eaton and Gasson 2001). Several
virulence determinants in enterococci have been described so far that include cylA and cylB
which are associated with activation and transport of cytolysin, respectively and cytolysin
lyses the eukaryotic cells; agg related with aggregation that results in adherence to eukaryotic
cells; esp encoding a gene of a cell wall-associated protein involved in immune evasion;
efaAfs and efaAfm that encode adhesins expressed in serum by Enterococcus faecalis and
Enterococcus faecium respectively; cob and gelE which facilitates conjugation and
hydrolyzes gelatine, collagen and other bioactive compounds, respectively (Eaton and Gasson
2001; Nueno-Palop and Narbad 2011). In this study, we report the characterization of
functional characteristics of Enterococcus faecium strains isolated from human gut and
assessment of their safety. Results of this study revealed the potential of E. faecium R13 to be
further tested as a probiotic candidate strain.
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Materials and Methods
Isolation of gut bacteria
Two healthy adults (aged 20-40) who had not been prescribed antibiotics for at least three
months prior to this study and had taken any probiotics provided the faecal samples. For the
isolation of gut bacteria, freshly collected faecal samples were suspended in Phosphate Buffer
Saline (PBS) and after homogenisation serial dilutions were performed from these
suspensions by plating to de Man, Rogosa, Sharpe (MRS) and Brain Heart Infusion (BHI)
(Merck, Germany) agars and incubation of the plates were conducted at 37oC under anaerobic
conditions for 48 h. From these plates potential different isolates were selected and further
subcultured in MRS broth and then stored at − 80 °C in glycerol (40% v/v).
Bacterial identification by 16S RNA gene sequencing
All isolates were genotypically discriminated by rep-PCR as described previously (Sagdic et
al. 2014) and selected strains were identified. The c.1.5 kb 16S rRNA gene of the selected
strains were amplified with primers AMP_F (5’-GAGAGTTTGATYCTGGCTCAG-3’) and
AMP_R (5’- AAGGAGGTGATCCARCCGCA-3’) (Baker et al. 2003). PCR reaction
mixtures contained 1 µl DNA template from Genomic DNA extracted from each strain using
a DNA isolation kit (Qiagen, Turkey), 10 µl 5× PCR buffer for Taq polymerase (Promega),
0.4 µl dNTPs (Bioline), 1 µl of 20 mM primers AMP_F and AMP_R, 0.25 µl 5U Taq
polymerase (Promega) and up to 50 µl of sterile H2O. PCR was performed using a thermal
cycler (Benchmark, TC9639) with the following programme: 95°C for 2 min, 20 cycles of
95°C for 30 s, 55°C for 20 s, and 72°C for 30 s and 72°C for 5 min final extension. PCR
products were run on a gel to check the amplication and amplicons were further purified
using SureClean kit (Bioline). Sequencing reactions were prepared using primers AMP_F/
AMP_R at 1.6 µM concentrations and the ABI Prism BigDye Terminator v3.1 Cycle
Sequence Kit (Applied Biosystems) according to the manufacturer’s protocol. Sequences
obtained were interrogated with the NCBI database using the BLAST algorithm with a
similarity criterion of 97–100%.
Resistance to low pH and bile salts
To assess resistance to low pH and bile salts, strains were grown overnight aerobically in
MRS medium and then a 1% inoculum subcultured into MRS medium as a control and MRS
medium either adjusted to pH 4 using 1M HCl or containing bile salts (Bovine bile, Sigma) at
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concentration of 0.3% (v/v) to obtain an OD600 of 0.1. All samples in 20 ml bottles were
incubated at 37°C unshaken and the growth of E. faecium strains were measured at OD600
over 24 h using a Spectrophotometer (PG Instruments, T60).
Survival in simulated in vitro digestion
In vitro digestion tests of E. faecium strains were performed as described previously (Nueno-
Palop and Narbad 2011). Briefly, strains were grown in MRS media overnight and harvested
by centrifugation (4000 g for 10 min at 4°C). The harvested cells were then resuspended in
PBS to obtain an OD600nm ~ 1.0 and cell counts were determined. To simulate gastric
digestion, each sample was adjusted to pH 3.0 using 1M HCl and Pepsin (Sigma) was added
to a final concentration of 5% (w/v). The mix was incubated at 37°C for 90 min with
agitation at 110 rpm. To create intestinal digestion conditions, the sample was adjusted to pH
6.0 and solutions of pancreatin (Sigma) and bile salts at a final concentration of 0.1% and
0.3% (w/v) respectively were added. Samples were incubated for 150 min at 37°C with
agitation (110 rpm) and following the final incubation cell counts were determined. An
aliquot was serially diluted before and after digestion and then plated on MRS agar in
triplicate. The plates were incubated at 37°C for 48 h. The survival percentage was calculated
by comparing cell counts before and after digestion for each strain.
Bacteriocin activity and detection of bacteriocin coding genes
For the detection of antagonistic activity with regards to bacteriocin production of E. faecium
strains, cultures were grown overnight with 1% inoculation in 10 ml MRS broth. Cells were
removed by centrifugation at 14,000 g for 5 min. The supernatant was filtered through a
sterile 0.22 µm syringe filter in order to remove all bacterial cells that may remain in the
supernatant. The pH of the filtered supernatant was adjusted to pH 6.0 with NaOH for the
elimination of possible inhibition effects organic acids following the inhibition of H2O2 with
catalase (Merck) application at 25°C for 30 min. A final filtration step was applied and the 20
µl supernatants were applied to the TSB agar plates in which the target pathogen strains were
previously spread and the antimicrobial activity was observed after 24h incubation at 37°C by
measurement of the formed inhibition zones in each strain and expressed as diameters of the
inhibition zone in mm. The bacteriocin activities were also expressed as arbitrary units (AU
ml-1) in which one AU unit was defined as the reciprocal of the highest dilution showing a
clear zone higher than 2 mm as described previously (De Kwaadsteniet et al. 2005). Six
pathogen strains; Salmonella typhimurium RSSK 95091, Escherichia coli BC 1402, Bacillus
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cereus BC 6830, Yersinia enterocolitica ATCC 27729 and Staphylococcus aureus ATCC
25923, Staphylococcus aureus BC 7231. All pathogens were grown with Tryptic Soy Broth
(TSB) medium under aerobic conditions at 37°C.
The presence of the genes encoding enterocin A and B was PCR detected for E. faecium
strains with primer sets entA_F (AAATATTATGGAAATGGAGTGTAT), entA_R
(GCACTTCCCTGGAATTGCTC) and entB_F (GAAAATGATCACAGAATGCCTA),
entB_R (GTTGCATTTAGAGTATACATTTG), respectively (Toit et al. 2000). DNA was
isolated from each strain and PCR conditions were performed as described previously
(Fontana et al. 2015) using a thermal cycler (Benchmark, TC9639). PCR products were run
on a gel to check the amplicon size of 126 bp and 162 bp for the presence of enterocin A and
B, respectively.
Effect of enzymes, detergents, pH and temperature on the bacteriocin activity
The supernatants of E. faecium strains R3, R5, R6 and R13 were obtained as described above
and proteinase K (Sigma), pepsin (Sigma) and catalase (Merck) were added to the
supernatants at final concentration of 1 mg/ml and following 2 h incubation the antimicrobial
activity of the supernatants were tested against all pathogens as described above. Similarly
for the determination of the effect of the detergents on bacteriocin activity of E. faecium
strains sodium dodecyl sulphate (SDS), Tween 20 and Triton X-100 were added to the
supernatants at 1% final concentration and after 5 h incubation at 37°C the antimicrobial
activities were observed as described above. The effect of pH on bacteriocin activity was
determined by adjusting the supernatants between pH 3.5 and 9.5 with sterile 1 N HCl or 1 N
NaOH. Finally effect of high temperature on bacteriocin activity was determined by heating
the supernatants at 80, 90 and 100°C for 30 min. Untreated supernatants of E. faecium strains
were applied as control in all experiments.
Microbial adhesion to hexadecane (MATH) assay
The cell surface hydrophobicity of E. faecium strains was carried out using largely following
the method described previously (Sagdic et al. 2014). Briefly, overnight grown cultures were
collected by centrifugation (8000 × g for 10 min at 4°C) and resuspended in 50 mM K2HPO4
(pH 6.5) buffer to obtain an OD590 of 1.0. The bacterial cell suspension (3 ml) was then
mixed with 0.6 ml of hexadecane (Sigma). The mixture was vortexed for 1 min and then left
undisturbed for 20 min to allow complete phase separation. After equilibration, the aqueous
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phase was removed carefully, in order not to disturb the interfacial equilibrium, and the
OD590 was measured. The percentage adhesion was calculated using the following equation:
% Adhesion to hexadecane = (1-A1/A0) × 100, where A0 is the initial absorbance (OD600) of
the bacterial suspension and A1 is the absorbance after 20 min of incubation.
Antibiotic susceptibility
Resistance of E. faecium strains against ampicillin (Amp, 10 µg), chloramphenicol (C, 30
µg), erythromycin (E, 15 µg), kanamycin (K, 30 µg), tetracycline hydrochloride (TE, 30 µg),
vancomycin (VA, 30 µg), Gentamicin (Cn, 10 µg), Rifampicin (Rd, 5 µg), Carbenicillin
(CAR, 100 µg), Amoxicillin (Aml, 25 µg), Oxacillin (Ox, 1 µg) and Streptomycin (S, 10 µg),
(Oxoid, UK) was determined using antibiotic disks. Each strain was activated in MRS broth
and 1% inoculum added to MRS agar at 45–50 °C and poured into plates. Then, antibiotic
disks were placed at the center of the medium and plates were incubated at 37 °C for 24–48
h. The inhibition zones around the disks if presented were measured and expressed as
centimetre (cm).
Screening of E. faecium strains for virulence determinants
The PCR screening of the Enterococcal strains for the virulence determinants was conducted
targeting specific virulence factors (Agg, gelE, cylA, cylB, esp, efaAfs, efaAfm and cob)
using the primer sets described previously (Eaton and Gasson 2001). Genomic DNA was
isolated from overnight cultures of E. faecium strains using a commercial DNA isolation kit
(Qiagen, Turkey). The Tm of each primer set was determined and PCR was performed as
described previously (Eaton and Gasson 2001).
Determination of hemolytic activity
The haemolytic activity of Enterococcus strains were determined using previously described
methodology (De Vuyst et al. 2003). Basically strains were grown overnight in MRS medium
at 37 °C, and then transferred onto BHI and Blood Agar Base (Merck) plates containing 7%
of human blood (Bayburt State Hospital, Bayburt, Turkey). The plates were incubated
overnight under aerobic and anaerobic conditions at 37 °C and formation of a clear zone of
hydrolysis, a partial hydrolysis or no reaction around colonies reflecting β hemolysis, α
hemolysis and γ hemolysis, respectively was observed for the determination of the hemolytic
activity (De Vuyst et al. 2003).
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Results
In this study 3 Lactobacillus paracasei, 3 L. plantarum and 3 L. casei strains were isolated
from faecal samples together with 9 Enteroccus faecium strains. The genotypic
characterization revealed the presence of 4 different E. faecium strains (R3, R5, R6 and R13)
within these isolates. The functional properties of these strains including resistance to low pH
and bile salts, survival in simulated in vitro digestion, inhibition of pathogens and presence of
bacteriocin coding genes and production of bacteriocin(s), preliminary characterization of
bacteriocin(s) adhesion, antibiotic susceptibility, presence of the virulence determinant genes
and their hemolytic activity were determined. The 16S sequences of E. faecium strains R3,
R5, R6 and R13 were deposited in GenBank under accession numbers KT119620-
KT119623, respectively.
The effect of stress conditions on cell growth of E. faecium strains was measured by growing
cells at low pH, in the presence of bile salts and in MRS broth as a control over a 24 h period
(Figure 1A-B-C). In the first half of the growth period all strains showed reduced growth
rates except strain R13 which revealed increased growth after 8 h. In the second half of the
growth period strain R3 and R5 showed similar growth rates and reached to OD600 of 1.0
(Figure 1A). Strain E6 was the most affected strain from the low pH and reached to lower OD
values compared to the other three strains tested. In general strain R13 was the least affected
strain from the low pH and showed the highest growth rate at the end of the growth period.
Similar to the low pH, E. faecium strains was also affected from the bile salts but generally a
lower growth repression was observed except stain R6 (Figure 1B). This strain showed
significantly lower growth rates compared to the other strains and after reaching to its peak
growth at 4 h no significant growth was observed. Similar to the low pH, strain R13 showed
the highest growth compared to the other strains in the presence of the bile salts (Figure 1B).
All strains showed similar levels of growth under control conditions (Figure 1C) and reached
higher OD values than the low pH and bile salts conditions showing the detrimental effects of
the conditions tested.
One of the important characteristics of probiotic bacteria is to survive during the GI tract
passage. Table 1 shows the digestion survival of E. faecium strains tested in this study. There
were clear differences among the survival of E. faecium strains and strain E13 showed the
highest resistance during simulated in vitro survival test (Table 1).
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Similar to the survival under harsh conditions adhesion is also important for probiotic strains
to show their functional characteristics and the hydrophobicity of E. faecium strains was
assessed using adhesion to hexadecane (Table 1). The adhesion of E. faecium strains showed
marked differences among the four strains tested and the highest adhesion was observed for
strain R3 and R6. The adhesion of strain R13 was slightly lower than these strains and the
lowest adhesion was observed for strain R5 which was nearly half of the adhesion % of the
other three strains tested (Table 1).
Antibiotic resistance of probiotics and more importantly of enterococci is an important
concern and the antibiotic resistance of gut isolate E. faecium strains was tested against 12
antibiotics (Table 2). Several different patterns were observed for the antibiotic resistance of
E. faecium strains and all strains were resistant to streptomycin. Strain R3 was resistant to
vancomycin and kanamycin and strain R5 was also resistant to vancomycin. Addition of
strain R13 was resistant to gentamycin and kanamycin and strain R6 was appeared to be
sensitive to all tested antibiotics expect streptomycin (Table 2). In general, when the tested
strains were sensitive to the tested antibiotics, similar levels of inhibition zones were
detected.
Similar to the presence of antibiotic resistance, enterococcal strains can harbour several
virulence factors which have to be determined for selection of these strains as probiotics. In
this respect, the presence of the known virulent factors in E. faecium strains was tested by the
PCR detection of the putative virulence genes in these strains (Table 3). Several different
patterns were observed for the presence of the virulence determinants in tested E. faecium
strains and all strains possessed two or more virulence determinants (Table 3). All strains
possessed efaAfm and strains R3, R5 and R6 were found to be positive for cob, agg and
efaAfs determinants. Additionally strains R5 and R6 possessed gelE and esp, respectively.
Strain R13 was only positive for gelE in addition to the efaAfm determinant (Table 3).
Another important safety aspect for the selection of probiotic strains is their hemolytic
activity (FAO/WHO 2002) and we tested the hemolytic activities of the E. faecium strains
isolated from human gut. Importantly no hemolysis of human blood (γ hemolysis) was
observed with the tested strains.
The antagonist role of probiotic strains due to the production of antimicrobial substances is an
important functional role to exclude the pathogens from the GI tract. In this respect, the role
of E. faecium strains on inhibition of pathogens was tested in this study and several different
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patterns were observed (Table 4A). It should be noted that strain R13 was the only strain to
show antimicrobial effects to all pathogen strains tested compared to the other E. faecium
strains in which bacteriocin(s) produced by this strains revealed a large spectrum of inhibition
and this strain had the highest inhibitory effects in all conditions except its inhibitory effect
against Staph. aureus ATCC 25923 (Table 4A). All strains were able to inhibit Staph. aureus
ATCC 25923 and S. typhimurium with varying degrees and only strain R13 showed
inhibition effect to Y.enterocolitica and B. cereus. Strain R3 and R5 were not able to inhibit
Staph. aureus BC 7231 and the level of inhibitory effect of R6 and R13 to this strain was
reduced compared to the ATCC 25923. Addition of all E. faecium strains except strain R3
showed antimicrobial effects to E. coli (Table 4A).
The antimicrobial role of Enterococcus strains is well known originating from the production
of bacteriocins and/or bacteriocin like substances by these species. The presence of the
enterocins A and B genes in the tested gut isolate E. faecium strains were evaluated by PCR
and all strains were found to be positive (data not shown) for the presence of these genes
suggesting the production of these bacteriocins. The bacteriocin activity of the E. faecium
strains were further determined using Staph. aureus and S. typhimurium as the indicator
strains as all E. faecium strains showed antimicrobial activity to these pathogens. Strain R3,
R5, R6 and R13 showed 6400, 3200, 1600 and 3200 AU/ml activity against Staph. aureus,
respectively whereas the levels of activity against S. typhimurium were detected to be 3200,
3200, 800 and 3200 AU/ml for the tested strains R3, R5, R6 and R13, respectively (Table
4B).
Table 5 shows the evaluation of the bacteriocin activities of E. feacium strains after treatment
with enzymes, detergents, different pH and high temperatures. Treatment of cell-free
supernatants of all E. feacium strains with Proteinase K and pepsin resulted in complete
inactivation of the antimicrobial activity against tested pathogens (Table 5). But no alteration
of the antimicrobial activity observed after catalase treatment, setting the pH of the
supernatant between 3.5-9.5 as well as high temperature application as 80, 90 and 100°C 30
min (Table 5).
Discussion
Enterococci is a wide group of microorganisms that can be found in different niches
including GI tract of humans (Nueno-Palop and Narbad 2011), food products especially
fermented meat and dairy products (Gomes et al. 2008; Martín-Platero et al. 2009).
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Enterococcal species as starter cultures have been used in dairy industry for decades and they
were also shown to act as probiotics (Eaton and Gasson 2001). However enterococcal species
also contain pathogenic strains that can be responsible for serious infections in both humans
and animals (Carlos et al. 2010) and safety assessment of enterococci with regards to
antibiotic resistance and virulence traits is crucial for selection of these strains for industrial
purposes and more importantly as probiotics (Nueno-Palop and Narbad 2011). The aim of
this study was to evaluate the functional characteristics of E. faecium strains to be selected as
potential probiotics isolated from human GI tract.
One of the main desired characteristics of probiotic bacteria in order to show their functional
roles is their survival ability in the GI tract in which low pH, bile salts and digestion
conditions are the main factors affecting this ability (Tan et al. 2013). The low pH and bile
salts resistance of E. faecium strains tested in this study was similar to that of previous
observations compared to the other enterococci (Banwo et al. 2013; Pieniz et al. 2014) and all
strains showed exponential growth from the inoculation until the end of incubation period in
which strain R13 showed better growth abilities. One of the main criteria for selection of
probiotic bacteria is their resistance to bile salts and all E. faecium strains in this study except
R6 revealed good growth rates suggesting their potentials as probiotic candidates. However
all strains showed higher growth rates under control MRS medium conditions suggesting the
growth suppression effects of the low pH and bile salt conditions.
The survival ability of bacteria during their passage through the upper digestive tract to reach
the colon where their beneficial roles are expected to be observed is crucial for their selection
as probiotics (Bezkorovainy 2001; Charteris et al. 1998). All E. faecium strains survived
under simulated digestion conditions at different levels confirming previous report suggesting
that E. faecium strains might resist to the harsh conditions originating from pepsin and
pancreatin (Hosseini et al. 2009) and the highest survival ability in this study was observed
for strain R13 as 24% although Nueno-Palop and Narbad (2011) reported higher levels of
survival for enterococci. Similar to the survival, adhesion of probiotic bacteria to the
intestinal mucosa is critical for probiotic functions, which avoids their removal from the
colon by peristalsis (Nueno-Palop and Narbad 2011) and cell surface hydrophobicity may
determine bacterial adhesion (Dertli et al. 2015). All gut isolate E. faecium strains showed
marked hydrophobicity levels except R5 suggesting their potential adhesive properties.
Previously higher (Abdhul et al. 2014) and lower hydrophobicity levels (Favaro et al. 2014;
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Santos et al. 2015) were reported for E. faecium strains which reveal the importance of the
strains specific properties such as cell surface structure determining the adhesion properties
One of the major concern for selection of enterococci as probiotic organism or starter culture
is high risk of antibiotic resistance in these strains due to the fact that antibiotic resistance
genes in this organisms are generally plasmid encoded or transposon associated revealing the
potential risk of horizontal gene transfer (Hasman et al. 2005). However it was noted that in
general the antibiotic resistance of the non-clinical originated enterococcal isolates displayed
lower occurrence of antibiotic resistance compared to the clinical ones (Abriouel et al. 2008).
The susceptibility of gut isolates E. faecium strains to several antibiotics was determined in
this study and several patterns were observed. Vancomycin-resistant enteroccocci (VRE) is a
major health problem worldwide (Cetinkaya et al. 2000) and E. faecium strains R3 and R5
showed resistance to this antibiotic. But more importantly, strain R13 was sensitive to
vancomycin together with strain R6. Addition of strain R13 showed resistance to three
antibiotics gentamicin, streptomycin and kanamycin in which the number of antibiotic
resistance traits was lower than previous observation found for food isolate Enterococcus
strains (Abriouel et al. 2008). Similar to our observation kanamycin and gentamicin
resistances in food and gut isolate Enterococcus strains was reported to be at high levels
(Pesavento et al. 2014; Ruiz-Moyano et al. 2009). A recent report also tested the antibiotic
susceptibility of E. faecium strain from animal origin and this strain was found to be highly
sensitive to the tested antibiotics although vancomycin resistance was observed for this strain
(Zheng et al. 2015). In another report E. faecium strains from goat’s milk were tested for their
antibiotic resistance against 50 antibiotics and a very low incidence of resistance was
observed showing the crucial role of the origin potentially affecting the transmission of
resistance (Schirru et al. 2012). Consequently, although the level of antibiotic resistance of E.
faecium strains was low in the present report, the presence of vancomycin-resistant gut isolate
E. faecium strains should be noted.
The gut isolate E. faecium strains were also tested for the presence of putative virulence
genes due to the safety considerations in this study. We found that E. faecium strains R3, R5,
R6 and R13 carry four, five, five and two virulence genes, respectively which reveals that the
number of virulence factors in these strains is low as generally enteroccocci may carry
between 6 to 11 virulence genes (Nueno-Palop and Narbad 2011). But two recent reports also
showed the non-presence of these virulence factors in food isolate E. faecium strains (Santos
et al. 2015; Zheng et al. 2015) although previously several starter and food originated
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Enterococci were shown to harbour some of the virulence factors suggesting the importance
the strain specific properties for carrying these virulence factors (Eaton and Gasson 2001). In
our study all strains contained adhesion factor efaAfm gene which does not represent a high
risk value in which the high incidence of this factor was also previously shown (Eaton and
Gasson 2001; Ruiz-Moyano et al. 2009). Additionally efaAfs was presented in all isolates
except R13 in which its presence was shown to influence pathogenicity in animal models
(Singh et al. 1998) and previous studies also reported its high presence in enteroccocci
including potential probiotics and starter cultures (Eaton and Gasson 2001; Nueno-Palop and
Narbad 2011). The other adhesion determinant (esp) was only detected in strain R6
supporting low level of occurrence of this indicator in non-medical isolates as previously
suggested (Eaton and Gasson 2001). All gut isolate E. faecium strains except strain R13
carried sex pheromone determinants (cob and agg) which can be related with both virulence
and antibiotic resistance gene transfer mechanisms (Ruiz-Moyano et al. 2009) and Eaton and
Gasson (2001) previously reported the high incidence of these genes in other enterococcal
strains. In addition gelE which is associated with gelatinase activity as a pathogenicity factor
was found in strains R5 and R13 which supports previous findings revealing high occurrence
of this gene in commensal enterococci (Lempiäinen et al. 2005; Nueno-Palop and Narbad
2011). More importantly none of the E. faecium strains carried the virulence factors cylA and
cylB which are required in cytolysin metabolism which is the most important virulence trait
that lyses the eukaryotic cells (Kayser 2003). This was similar to the previous observations of
Abriouel et al. (2008) and Nueno-Palop and Narbad (2011) in which non-clinical isolates
from human or food originated enterococci did not carry any cytolysin genes.
Testing the presence of hemolysins in Enterococcus strains is also crucial for safety
considerations and previously several food and human isolate E. faecium strains was shown
to be positive for β-hemolysis although the incidence of β-hemolysis was reported to be
lower than the E. faecalis strains (De Vuyst et al. 2003). In this study no hemolytic reaction
was observed for E. faecium strains including strain R13 showing their safety in terms of
hemolysins supporting their potential to be tested for their functional characteristics.
Biosynthesis of antimicrobial components such as bacteriocins in gut environment is an
important functional characteristic of probiotic bacteria (Saarela et al. 2000). The production
of variety of bacteriocins called enterocins with broad spectrum activity is well known for
enterococci (Giraffa 2003) and E. faecium strains in this study showed varying levels of
antimicrobial effects to selected Gram + and Gram – pathogens suggesting the production of
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bacteriocins. Enterocins are generally active against Gram + bacteria (Giraffa 2003) but
several studies also reported enterocins active against Gram – bacteria (De Kwaadsteniet et
al. 2005; Line et al. 2008). Our findings confirmed these reports as all E. faecium strains
showed inhibitory effects to both Gram + and Gram – bacteria. The wide range inhibitory
activity of gut isolates can be specifically important in complex gut environment. The PCR
amplification of the genes required for the production of enterocins A and B was also positive
for all E. faecium strains supporting the production of enterocins by these isolates. Similar to
our findings previous studies also showed the presence of both genes in E. faecium strains
with antimicrobial effects (Banwo et al. 2013; Cocolin et al. 2007) and it was reported that in
the presence of enterocin A gene, enterocin B gene always occurs (De Vuyst et al. 2003)
confirming our findings. A recent report also revealed the high level of the presence of
bacteriocin related genes in enterococci which were suggested to be reason for the high
degree of bactericidal activity of these species (Fontana et al. 2015). The presence of these
genes and inhibitory effects in commensal E. faecium strains can be crucial and E. faecium
R13 displays important functional characteristics.
Similar to the previous knowledge (Campos et al. 2006; De Kwaadsteniet et al. 2005; Franz
et al. 1996; Toit et al. 2000), the antimicrobial activities of E. faecium strains were lost after
treatment of the supernatants with proteolytic enzymes confirming the proteinaceous nature
of bacteriocins but treatment with catalase resulted in no alteration in antimicrobial activity
eliminating the potential involvement of the H2O2 in the antagonism process (Schirru et al.
2012). Additionally bacteriocin activities were not affected from detergents SDS, Triton X-
100 and Tween 20, heat treatments as well as effect of pH between 3.5 and 9.5. Similar
results were recorded previously (Arihara et al. 1993; Campos et al. 2006; De Kwaadsteniet
et al. 2005) for other bacteriocins although loss of antimicrobial activity at different pHs and
after higher temperature applications were also reported (Schirru et al. 2012; Toit et al. 2000).
The preliminary characterization of the bacteriocins of the E. faecium strains supported the
role of these strains as a probiotic candidate with respect to their antimicrobial activities.
In summary we have showed that E. faecium R13 from human gut may be a probiotic
candidate with functional characteristics in terms of resistance to low pH and bile salts,
survival under digestion conditions and adhesion, antimicrobial properties, antibiotic
resistance and presence of the virulence factors as well as hemolytic reaction. Further work is
in progress to characterize the bacteriocin(s) as well as its probiotic functionality and to
determine the expression patterns of the virulence genes in this strain.
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Acknowledgments
This research was supported by Bayburt University through an internal fund.
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Tables and Figures
Table 1. Survival of E. faecium strains in simulated digestion condition and percentage
adhesion of these strains to hexadecane.
Table 2. Resistance of E. faecium strains against antibiotics (inhibition zone, cm).
Table 3. Detection of some virulence determinant genes in E. faecium strains tested in this
study.
Table 4. Antibacterial activity of E. faecium strains against selected pathogens (A) and
determination of the antibacterial activity of E. faecium strains as AU ml-1 against selected
pathogens (B).
Table 5. Effect of enzymes, detergents, pH and temperature applications on the antimicrobial
activity of E. feacium strains on S. typhimurium and Staphylococcus aureus ATC. Activity of
bacteriocin is expressed in: (+) = presence of inhibition zone (>2 mm); (-) = no inhibition.
Figure 1. Assessment of growth of E. faecium strains under low pH (A), bile salts (B) and
control (C) conditions over 24 h. E. faecium strains R3( ), R5( ), R6 ( ) and R13 ( )
were grown in MRS at pH 4 (A) or in the presence of 0.3% bile salts (B) and in MRS as a
control medium (C).
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Table 1.
Digestion survival (%) Adhesion to hexadecane Enterococcus faecium R3 20.4 ± 1.71 45.45 ± 0.9 Enterococcus faecium R5 11.3 ± 1.47 19.65 ± 2.47 Enterococcus faecium R6 14.2 ± 4.2 42.05 ± 0.77 Enterococcus faecium R13 24.3 ± 1.4 38.65 ± 1.06
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Table 2.
AMP C Va Cn Rd K E TE CAR Aml Ox S R3 1.4±0.2 1.2±0.1 - 0.2±0.04 0.4±0.01 - 0.3±0.02 1.4±0.01 1.2±0.02 1.3±0.02 0.1±0.01 -
R5 1.3±0.1 1.3±0.1 - 0.2±0.07 0.4±0.02 0.2±0.01 0.3±0.02 1.6±0.1 1.3±0.05 1.6±0.1 0.1±0.01 -
R6 1.5±0.3 1.0±0.1 1.0±0.1 0.2±0.03 0.3±0.02 0.8±0.01 0.7±0.03 1.6±0.2 1.3±0.2 1.2±0.2 0.1±0.03 -
R13 1.3±0.1 1.2±0.1 1.0±0.1 - 0.3±0.01 - 0.4±0.01 1.0±0.1 1.5±0.02 1.2±0.02 0.1±0.01 -
Amp: Ampicillin, C: Chloramphenicol, Va: Vancomycin, Cn: Gentamicin, Rd: Rifampicin,
K: Kanamycin, E: Erythromycin, TE: Tetracycline, CAR: Carbenicillin Aml: Amoxicillin,
Ox: Oxacillin, S: Streptomycin, - No inhibition zone.
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Table 3.
Strain Virulent factors Enterococcus faecium R3 cob; agg; efaAfm; efaAfs Enterococcus faecium R5 cob; agg; efaAfm; efaAfs; gelE Enterococcus faecium R6 cob; agg; efaAfm; efaAfs; esp; Enterococcus faecium R13 efaAfm; gelE
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Table 4.
A
EC SA ATC SA BC YE ST BC
Enterococcus faecium R3 - 8 ± 1.41 - - 6.5 ± 0.7 - Enterococcus faecium R5 2.5 ± 0.7 5.5 ± 0.7 - - 5.5 ± 0.7 - Enterococcus faecium R6 2.3 ± 0.6 4.5 ± 2.1 2.5 ± 0.7 - 3.5 ± 0.7 - Enterococcus faecium R13 4.5 ± 0.7 5 ± 1.4 3 ± 1.4 1.75 ± 0.35 4.5 ± 0.7 3.5 ± 0.7
Results are expressed as diameters of the inhibition zone and standard deviations in mm. EC:
E. coli, SA: S. aureus, YE: Y. Enterocolitica, ST: S. typhimurium, BC: B. cereus, -: No
inhibiton zone
B
Bacteriocin activity
Strains SA ATC ST
Enterococcus faecium R3 6400* 3200 Enterococcus faecium R5 3200 3200 Enterococcus faecium R6 1600 800 Enterococcus faecium R13 3200 3200
*Results are expressed as AU ml-1 calculated from the highest dilution showing a clear zone
> 2 mm. SA: S. aureus, ST: S. typhimurium.
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Table 5.
Bacteriocins R3 R5 R6 R13 Enzymes
Pepsin, Proteinase K catalase
- +
- +
- +
- +
Detergents
SDS Triton X-100 Tween 20
+ + +
+ + +
+ + +
+ + +
pH
3.5-9.5
+
+
+
+
Temperatures
80, 90, 100°C 30 min
+
+
+
+
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Figure 1
A
B
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C
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