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Protein engineering to explore andimprove affinity ligands
Martin Linhult
Royal Institute of Technology
Department of Biotechnology
Stockholm 2003
ISBN 91-7283-596-6
Stockholm 2003 © Martin Linhult
Royal Institute of TechnologyAlbanova University CenterDepartment of BiotechnologySE-106 91 StockholmSweden
Printed at Författares BokmaskinS:t Eriksgatan 10Box 12071SE-102 22 Stockholm
Linhult M.2003. Protein engineering to explore and improve affinity ligands.Department of Biotechnology, Albanova University Center, Royal Institute ofTechnology, Stockholm, Sweden.
AbstractIn order to produce predictable and robust systems for protein purification and detection, wellcharacterized, small, folded domains descending from bacterial receptors have been used. Thesebacterial receptors, staphylococcal protein A (SPA) and streptococcal protein G (SPG), possess highaffinity to IgG and / or HSA. They are composed of repetitive units in which each one binds the ligandindependently. The domains fold independently and are very stable. Since the domains also have well-known three-dimensional structures and do not contain cysteine residues, they are very suitable asframeworks for further protein engineering.
Streptococcal protein G (SPG) is a multidomain protein present on the cell surface ofStreptococcus. X-ray crystallography has been used to determine the binding site of the Ig-bindingdomain. In this thesis the region responsible for the HSA affinity of ABD3 has been determined bydirected mutagenesis followed by functional and structural analysis. The analysis shows that the HSA-binding involves residues mainly in the second a-helix.
Most protein-based affinity chromatography media are very sensitive towards alkaline treatment,which is the preferred method for regeneration and removal of contaminants from the purificationdevices in industrial applications. Here, a protein engineering strategy has been used to improve thetolerance to alkaline conditions of different domains from protein G, ABD3 and C2. Amino acidsknown to be susceptible towards high pH were substituted for less alkali susceptible residues. The new,engineered variants of C2 and ABD shown higher stability towards alkaline pH. Also, very importantfor the potential use as affinity ligands, these mutated variants retained the secondary structure and theaffinity to HSA and IgG, respectively. Moreover, dimerization was performed to investigate whether ahigher binding capacity could be obtained by multivalency. For ABD, binding studies showed thatdivalent ligands coupled using non-directed chemistry demonstrated an increased molar bindingcapacity compared to monovalent ligands. In contrast, equal molar binding capacities were observedfor both types of ligands when using a directed ligand coupling chemistry involving the introductionand recruitment of a unique C-terminal cysteine residue.
The staphylococcal protein A-derived domain Z is also a well known and thoroughly characterizedfusion partner widely used in affinity chromatography systems. This domain is considered to berelatively tolerant towards alkaline conditions. Nevertheless, it is desirable to further improve thestability in order to enable an SPA-based affinity medium to withstand even longer exposure to theharsh conditions associated with cleaning in place (CIP) procedures. For this purpose a differentprotein engineering strategy was employed. Small changes in stability due to the mutations would bedifficult to assess. Hence, in order to enable detection of improvements regarding the alkalineresistance of the Z domain, a by-pass mutagenesis strategy was utilized, where a mutated structurallydestabilized variant, Z(F30A) was used as a surrogate framework. All eight asparagines in the domainwere exchanged one-by-one. The residues were all shown to have different impact on the alkalinetolerance of the domain. By exchanging asparagine 23 for a threonine we were able to remarkablyincrease the stability of the Z(F30A)-domain towards alkaline conditions. Also, when grafting theN23T mutation to the Z scaffold we were able to detect an increased tolerance towards alkalinetreatment compared to the native Z molecule. In all cases, the most sensitive asparagines were found tobe located in the loops region.
In summary, the work presented in this thesis shows the usefulness of protein engineeringstrategies, both to explore the importance of different amino acids regarding stability and functionalityand to improve the characteristics of a protein.
Keywords: binding, affinity, human serum albumin (HSA), albumin-binding domain(ABD), affinity chromatography, deamidation, protein A, stabilization, Z-domain,capacity, protein G, cleaning-in-place (CIP), protein engineering, C2 receptor.
© Martin Linhult
An intellectual is a man who says a simple thing in a difficult way;an artist is a man who says a difficult thing in a simple way.
Charles Bukowski, “Notes of a Dirty Old Man”
List of publicationsThis thesis is based on the following publications, referred to in the text by theirrespective roman numerals:
I. Linhult, M., Binz, K., Uhlén, M. and Hober, S. (2002) Mutational analysis ofthe interaction between Albumin-Binding Domain (ABD) from Streptococcalprotein G and Human Serum Albumin (HSA). Protein Sci. 11: 206-213.
II. Gülich, S., Linhult, M., Nygren, P-Å., Uhlén, M. and Hober, S. (2000)Stabilization of an affinity protein ligand towards Cleaning In Place (CIP)conditions. J Biotechnol. 80:169-78.
III. Linhult, M., Gülich S., Gräslund, T., Nygren, P-Å. and Hober, S. (2003)Evaluation of different linker regions for multimerization and the couplingchemistry for immobilization of a proteinaceous affinity ligand. ProteinEngineering In press.
IV. Gülich, S,. Linhult, M., Ståhl, S. and Hober. S. (2002) EngineeringStreptococcal protein G for increased alkaline stability. Protein Engineering15(10):835-42.
V. Linhult, M., Gülich, S., Gräslund, T., Simon, A., Karlsson, M.,Sjöberg, A., Nord, K. and Hober, S. (2003) Improving the tolerance of proteinA to repeated alkaline exposures using a by-pass mutagenesis approach.Proteins: Struct., Funct. and Genet. In press.
Table of contentsIntroduction 10
Protein structure 11
Protein engineering 13
Site directed mutagenesis 13
Combinatorial approaches 15
Protein stability 17
Rational design 20
Tolerance to alkaline conditions 22
Protein-protein interactions 24
Kinetic studies 24
Measuring protein-protein interactions 26
Bacterial surface receptors 27
Staphylococcal protein A 28
Streptococcal protein G 30
HSA binding region 30
IgG binding region 32
Affinity chromatography purification 33
Present investigation 36
HSA binding domain 36
Mutational analysis of an ABD 36
Stabilization of ABD towards alkaline conditions 40
IgG binding domains 49
Stabilization of C2 towards alkaline conditions 49
Stabilization of Z towards alkaline conditions 53
Concluding remarks 58
Acknowledgements 59
Abbreviations 60
References 61
10
IntroductionFifty years have now passed since the structure of the DNA double helix was
discovered (Watson and Crick 1953). In this time, great efforts have been made in the
field of life sciences, leading to advance across a range of important and emerging
areas. A continued challenge for scientists in the coming years will be to further
deepen our understanding of biology at the molecular level, including all classes of
biomolecules involved in life processes. An increased knowledge about protein
function in particular has become especially important in the so-called post genomic
era, where many unknown gene products are currently being characterized for
localization, expression levels, interactions and ultimately function. Somewhat
simplified, proteins are linear biomolecules of different lengths which are synthesized
from 20 different amino acid building blocks by the cellular machinery according to a
blueprint stored as genetic information. Following synthesis, the linear molecule
undergoes complex folding processes forming various secondary structure elements
such as a-helices, b-sheets and different turn/loops. Subsequent arrangement of these
structure elements results in the final three-dimensional structure of a protein. Despite
the limited number of building blocks, proteins can be very diverse with respect to for
example their functions, and the environments in which they act. Fundamental
questions to answer in this respect are for example how proteins have evolved to
interact with other proteins and to be function in radically different environments.
Protein engineering is one approach that can be used to shed some light onto these
questions, and increase the utility of the proteins in different biotechnological and
industrial applications. Protein engineering techniques have proven fruitful for
resolving questions in the field of biochemistry since the late 1970s; pioneered by the
work done on site-directed mutagenesis on Tyrosyl-transfer RNA synthetase (TyrS)
by Michael Smith and co-workers in Vancouver (Hutchison et al. 1978; Winter et al.
1982). In recent years, protein engineering has evolved from studies involving the
substitution, deletion or insertion of amino acids one-by-one, to studies involving the
manipulation of larger parts of proteins. This has become possible through the
development of a range of new techniques, for instance the polymerase chain reaction
(PCR) facilitating genetic work, gene shuffling for generation of diversity and
different in vitro selection techniques, such as phage display. At its inception, protein
engineering was used as a tool for understanding more about protein structure and
11
function. More recently, a number of different applications have come into existence,
proving the success of protein engineering outside the lab. For instance, proteases and
lipases have been engineered to work well in modern washing machines, and
antibodies are now being engineered for clinical use in therapeutic applications
(Holliger and Bohlen 1999; McCafferty and Glover 2000).
Protein structure
The building blocks of proteins and peptides are the amino acids linked together with
planar peptide bonds, described by Pauling as early as 1960 (Pauling 1960). The 20
natural amino acids differ in their respective properties, such as hydrophobicity, size,
shape, and electrostatics. By altering the combinations and numbers of these amino
acids, nature can build an immense number of more or less complex protein
structures, of different stabilities and functions.
The different properties of amino acids make them more or less suited to be
present in different types of secondary structure elements (usually referred to as
having different helix or b-sheet propensities). A number of studies have been
performed to explore such different amino acid propensities in a-helices and b-sheets
(Lyu et al. 1990; O'Neil and DeGrado 1990; Horovitz et al. 1992; Blaber et al. 1993;
Munoz and Serrano 1994; Smith et al. 1994; Smith and Regan 1995; Myers et al.
1997). In addition, also loops and turns have been investigated in relation to amino
acid propensities (Williams et al. 1987; Wojcik et al. 1999; Crasto and Feng 2001).
These results can be beneficial in protein engineering, giving advice on which amino
acids could be introduced in what structure elements without disturbing the overall
structure. A popular strategy to investigate the importance of a particular amino acid
position for a given trait is to replace the native amino acid with an alanine. The
characteristics of this amino acid (relative small, pH-independent properties, high a-
helix and b-sheet propensities) make it a good first choice in site-directed
mutagenesis approaches (Fersht 1999).
The a-helix consists of a right-handed coil wherein the n residue forms a hydrogen
bond with the n+4 residue, resulting in 3.6 residues per turn. Hence, neither the first
nor the last residues in the a-helix can make the intra-helical hydrogen bond between
the backbone C=O groups of one turn and the NH groups of residues in the next
(Fersht, 1999). This requires that for stabilization of the helix, hydrogen bonds must
12
be made with either other groups in the protein or the solvent. Capping boxes, termed
N- and C-caps are often occurring in the N- and C-terminal to stabilize the ends of the
helices. These residues form side chain hydrogen bonds to the backbone of the
polypeptide chain inside the helix (Richardson and Richardson 1988; Doig 2002). The
alignment of the dipoles in the polypeptide backbone causes a net dipole moment
along the helix. The N-terminal is positively polarized while the C-terminal is
negatively polarized Thus, there is a preference for negatively charged N-terminal
amino acids, and consequently a preference for positively charged C-terminal amino
acids (Hol 1985; Chakrabartty et al. 1993). Attempts to stabilize a-helices via
favoring the electrostatics has been successful, for example, the introduction of
negatively charged amino acid in the N-terminus of an a-helix of the T4 Lysozyme
protein resulted in a stabilization as determined by (Nicholson et al. 1988).
Polypeptide chains can also form complementary hydrogen bonds to a parallel
polypeptide chain. These parallel chains can be aligned in either the same or opposite
directions. This class of secondary structure elements is called the b-sheet. Because of
the nature of b, sheets-always forming a hydrogen bond with another polypeptide
chain, it is more difficult to predict b-sheet occurrence and amino acid propensities
for b-sheet than for a-helices (Minor and Kim 1994b; a). Interestingly, high quantities
of b-sheets occur in proteins prone to form arrays of insoluble fibrils, which are
involved in for instance prion diseases such as Creutzfeldt-Jakob Disease (CJD)
(Prusiner 1998).
Loop and turn regions connect the a-helices and b-sheets. The definitions of turns
and loops are not very distinct, with turns consisting of a few residues while loops are
longer and have less well-defined structures. Polar and charged residues quite often
occur on these surface exposed areas (Leszczynski and Rose 1986; Argos 1990). The
structures described above constitute secondary structure elements of a protein. The
tertiary structure of a protein is in turn defined by how these secondary structures of a
single polypeptide chain are grouped together. A number of proteins consist of two or
more polypeptide chains. The three dimensional arrangement of the different domains
is in turn called the quaternary structure.
Our understanding of the function/structure relationship of a protein is obviously
facilitated if a three-dimensional structure of the protein is available. To date (sept
2003) 20 413 protein, peptide and virus structures have become available in the
13
Brookhaven Protein Databank; 17 653 which have been solved by X-ray
crystallography and 2760 which have been solved by nuclear magnetic resonance
(NMR). Another technique used to investigate protein structure is Circular Dichroism
(CD) (Pace 1997a), a spectroscopy-based technique that measures the differential
absorption of left and right circularly polarized light. The CD technique quickly and
easily provides information about the secondary structure content of a protein sample
(Schmid 1997; Kelly and Price 2000). CD spectroscopy is widely used as a tool in
protein engineering, since it rapidly can assess the secondary structure of a range of
protein constructs. By superimposing the spectra of different mutants, it is possible to
verify structural differences. Another advantage with CD is that it is applicable in
different experimental conditions, allowing for the collection of spectra in for
example, different concentration of denaturants, different pHs and at different
temperatures which can be used to analyze the stability of a protein (Kelly and Price
2000). The main limitation of CD is that it only provides relatively low-resolution
structural information, but the conclusions can be enhanced through using secondary
structure prediction algorithms (Ribas De Pouplana et al. 1991; Unneberg et al. 2001).
Protein engineering
Site directed mutagenesis
Site-directed mutagenesis has proven to be a valuable tool for increasing our
understanding of different biomolecular principles, for instance enzyme mechanisms,
folding pathways and biomolecular recognition. By changing a limited number of
amino acids, and then investigating how these new amino acids influence the
inherited function, the contribution of the various building blocks can be mapped. A
high-resolution three-dimensional structure of the protein of interest (both the wild
type and the variants) will obviously facilitate the evaluation of the collected data.
However, even with the accumulated knowledge from numerous studies of different
proteins, it is still very difficult, if not impossible to make accurate predictions about
the effects, even from a single amino acid substitution in a protein. Therefore protein-
engineering strategies could turn out to be a rather laborious. However, when both the
three-dimensional structure is known, and the active part of the target protein is
mapped, then the capacity for predicting the effect is greater. The first example of site
14
directed mutagenesis was presented by Michael Smith and co-workers in 1978. In this
experiment, single-stranded viral DNA from an Escherichia coli (E. coli) specific
bacteriophage was used as a template for mutagenesis. A mismatch oligonucleotide
consisting of 12 bases was added and after hybridization, DNA polymerase I was
used to make the DNA double stranded (ds). After ligation using T4-DNA ligase, the
vector was transfected into E.coli cells resulting in the production of phages
exhibiting the desired mutation (Hutchison et al. 1978). However, since both strands
(wild type and mutation-containing strand) can serve as templates for replication,
several clones must often be screened before a “pure” mutant is found. Later, Kunkel
and coworker developed a more practical system (Kunkel et al. 1987), wherein the
template vector first is propagated inside a uracil n-glycsoylate deficient (ung-) strain.
This strain, to some extent incorporates uracil nucleotides instead of thymidines
nucleotides into newly synthesized DNA. The heteroduplex DNA containing DNA
with uracil in the template strand and newly synthesized DNA in the second strand is
used to transfect an ung+ strain. The strain will efficiently degrade the template DNA
strand, as it has incorporated uracil nucleotides. This can dramatically increase the
mutation frequency (Kunkel et al. 1987; Kunkel et al. 1991). In the mid 1980s Kary B
Mullis invented the PCR technique for enzymatic in vitro amplification of DNA.
Variants of this technique have later been developed for site-specific mutagenesis
purposes (Figure 1). In these methods PCR is performed with primers including the
mutations to be inserted resulting in a PCR products containing the desired mutation.
15
Figure 1. A PCR-based method for site-directed mutagenesis developed by Ho and
coworkers (Ho et al. 1989), where (A) shows two separate PCR reactions which are
performed with primers (a+b) and (c+d) respectively on the same template where c and b
includes the desired mutation. B shows the two PCR products which both contain the
inserted mutation. C shows the use of the previous produced PCR product as templates in a
second PCR reaction using primers a and b resulting in a full-length product harboring the
mutation (D).
Combinatorial approaches
An alternative way to change the properties of a protein would be to create a library
consisting of numerous member entities, and then carry out a selection or a screening
procedure to find a member with desirable properties. Over the last few years, several
techniques to create protein libraries have been developed providing links between
genotype and phenotype, thereby facilitating the identification of the selected
members by sequencing of the encoding gene. Phage display technology has to date
been the most commonly used system for selection (Clackson and Wells 1994), which
is described in the next paragraph. Recently a number of in vitro systems have been
developed, for instance, ribosomal display (Hanes and Pluckthun 1997) and water-in-
oil emulsion selection (Tawfik and Griffiths 1998). One significant advantage with
these systems is that they have overcome the library size-limiting step of
A
B
a
b
c
d
C
d
a
D
16
transformation in that cell-free extract rather than intact cells are used for the
biosynthesis of the library members.
The first phase when using protein-library methods are to create a gene library
encoding for the different members. Several different methods have lately been
reported in the literature for the generation of diversity in a library. One strategy is to
employ synthetic oligonucleotides to code for a part of the gene. Here parts of the
oligonucleotide are randomized to create diversity. Error-prone PCR is another
widespread technique in which a thermostable DNA polymerase is forced to
misincorporate nucleotides under certain conditions, such as the addition of Mn2+
(Miyazaki and Arnold 1999). In 1994 Stemmer described another strategy for creating
diversity involving DNA shuffling. In this method, homologous genes are digested
and reassembled using PCR to yield a pool of new genes (Stemmer 1994).
Once the library containing the different gene constructs is established, it needs to
be analyzed to find a member with the desired properties. This procedure can be
performed using a screening or selection procedure. In the screening procedure, each
member in the library is analyzed at the time. One elegant screening method which
have been developed by Phillips and co-workers use the in vivo folding properties to
screen for variants with an increased thermodynamic stability. The system is based on
detection of protein folding in vivo and makes use of the distance-dependent
fluorescence resonance energy transfer (FRET) from the green fluorescent protein
(GFP) to the blue fluorescent protein (BFP). FRET only occurs when BFP and GFP
are in close proximity. The system is based on the construction of a ternary fusion
protein in which a protein of interest (X) is fused between GFP and BFP. If protein X
is unfolded and degraded by cellular proteases FRET between the donor BFP and the
acceptor GFP does not occur (Philipps et al. 2003).
Working with selection, the optimal goal is to design a selection procedure in
which only the variants with desired properties are isolated. Phage display is a
powerful selection method applicable to both proteins and peptide libraries. The
principle was first described in 1985 for the display of EcoRI endonuclease fragments
on the surface of the E. coli filamentous phage M13 (Smith 1985). Phage display
enables a physical link to be established between the protein of interest and the
encoding genetic material. A foreign gene sequence is fused to the gene for one of the
phage coat proteins, in most cases pIII or pVIII, making a hybrid fusion protein
displayed on the surface of the phage. Thus when constructing a combinatorial library
17
of the protein or peptide of interest, each member exhibiting a unique property will be
accessible on the surface of the phage enabling “fishing out” of the protein with the
desired properties. Any method capable of separating clones with a desired trait from
their background can be used as a selection method. In principle, most selection
methods are based on affinity for a certain target molecule. After binding the phages
to the target, non-specific binders are washed away. The phages that remain bound are
then eluted and subsequently amplified. The amplified phages are again presented for
the target, while non-specific binders are washed away. This routine is then repeated
four to six times to find the desired proteins linked to the encoding DNA by phage
particles (Clackson and Wells 1994).
Protein stability
Over the last few years, stabilization of proteins has been of great interest to scientists
for academic as well as economic reasons. When discussing protein stability one
should bare in mind that different environment will affect the protein of interest
differently. Proteins that have high thermal stability are not necessarily stable in high
concentration of different unfolding agents, such as Urea, GdnHCl or alkaline
solutions. Many attempts have been made to understand the structural and chemical
reasons for the higher stability of enzymes isolated from extremozymes, in terms of
their three-dimensional (3D) structure, than enzymes adapted to physiological
environments. A structural comparison between mesophilic and extremophilic
enzymes could illuminate ways for identifying mutations that could lead to stabilized
variants. In some cases this has indeed been possible (Eijsink et al. 1995; Perl et al.
2000; Delbruck et al. 2001). Notable structural differences between mesophilic and
thermophilic enzymes could for instance include increased compactness, shorter
surface loops, smaller internal cavities and large ion-pair networks, as in the case for
the enzyme citrate synthase (Danson and Hough 1998). However, using this
knowledge in stabilizing proteins has proven to be more difficult than expected. The
notable differences, which could be used as rules to stabilize mesophilic proteins,
have been shown to not be generally applicable, and are therefore definitely not
universal (Van den burg and Eijsink 2002).
In an evolutionary context of adaptations to high temperatures, it can be kept in
mind that the hyperthermophilic archaea represent the shortest phylogenetic lineage to
18
the root of the universal phylogenetic tree derived from small subunit (SSU) rRNA
sequence data (Pace 1997b) (see Figure 2). Therefore stability, or at least
thermostability, could be regarded as a starting point for evolution. Hence, by
studying proteins from this source it might be possible to adapt numerous proteins for
high temperature environment.
Figure 2. Universal phylogenetic tree based on SSU rRNA sequences. The scale bar
corresponds to 0.1 changes per nucleotide. Reproduced, with permission from Pace (1997).
Thermostabilization of proteins would be advantageous for a number of reasons; for
instance, an increased thermal stability would be beneficial for many industrial
applications. A process running at a higher temperature would be accompanied by
19
higher reaction rates, higher solubility of reactants and a lower risk of microbial
contaminations (van den Burg and Eijsink 2002).
It is possible to increase the tolerance for a protein by adding extrinsic factor, such
as glycine betaine. Glycine betaine has been found to stabilize a firefly luciferase used
in bioluminometric assays at elevated temperature (Eriksson et al. 2003). Extrinsic
factor seems also play a role in nature for different thermophilic bacteria. There is
increasing evidence that hyperthermophilic archaea (archaebacteria) produce organic
solutes such as 2-O-b-mannosylglycerate at high temperature (Hensel 1988; Martins
1997). Studies have also actually shown that these factors could have a direct effect
on enzyme thermostability (Ramos 1997).
In the field of protein stabilization through protein engineering, three different
main strategies could be outlined, as random mutagenesis, consensus approaches and
rational design. Recently, several groups have shown via different combinatorial
techniques that it is possible to stabilize a protein by random mutagenesis. For
instance, directed evolution, error-prone PCR, and gene shuffling are all techniques
that have led to the creation of many new biocatalysts, including variants with
significantly improved stability (Gershenson and Arnold 2000; Arnold 2001;
Bornscheuer and Pohl 2001; Chen 2001). The common theme in these strategies is the
creation of a library from which a suitable variant could be selected. The selection
procedure must be high-throughput as well as sufficiently discriminative. Preferably,
assay conditions are such that only stabilized variants are active, thereby enabling
them to be detected. For example, selections for a protein that is essential for growth
and survival of the host can be carried out in a thermophile (Gershenson and Arnold
2000). Another elegant selection strategy which can be mentioned here is one
designed by Sieber with co-workers using a phage display system (Sieber et al. 1998).
The general concept for the system is that an unfolded polypeptide chain, positioned
C-terminally to one of the domains of protein III in a multidomain fusion protein
displayed on the phage particle, would be cleaved through proteolysis. Hence, phage
clones for which this occurs will loose the infectivity.
20
Rational design
Rational design strategies have proven to be successful in making a protein more
tolerant to different environments, such as increased temperature, extreme pHs and
proteolytic enzymes. Traditionally, the most common strategy for increasing the
structural stability for stabilizing a protein has been to change residues internally in
the hydrophobic core (Van den Burg and Eijsink 2002). As the knowledge about
protein structure and stability has increased, changing residues at the surface has
turned out to be more successful strategy, since the hydrophobic core in most cases
already is well packed. Difficulties in predicting the effects of one or more of the
changed amino acids in the structurally important hydrophobic core may result in a
less stable protein, or even a ruined scaffold. Furthermore, as the hydrophobic core is
most often very well packed, the possibility to improve the stability by surface
mutations, which instead influence the electrostatic interactions on the surface, is
higher (Van den Burg and Eijsink 2002; Grimsley et al. 1999; Martin et al. 2001). In
spite of the degree of unpredictability a number of rational approaches for structural
stabilization have proven successful for a variety of proteins. These approaches
include the improvement of the packing of the hydrophobic core, the stabilization of
a-helix dipoles, the engineering of surface salt bridges and point mutations aimed at
reducing the entropy of the unfolded state (Nicholson et al. 1988; Van den Burg et al.
1998; Grimsley et al. 1999; Wang et al. 1999; Olson et al. 2001).
By comparing the amino acid content between two highly homologous domains,
Serrano and co-researchers presented a rational design strategy for stabilizing a
protein (Serrano et al. 1993). In this approach, each individual amino acid that differs
between the two domains is mutated. Afterwards, each mutated protein is analyzed
and the mutations that increase the stability can be combined to construct a multiple
mutant. However, this strategy is quite tedious and has to be carried out carefully, as
probably only a few key mutations will contribute to the increased stability (Van den
Burg and Eijsink 2002).
Eijsink and co-workers outlined another interesting alternative strategy in which a
reduction of local unfolding could be of importance for increasing the thermal
stability. For a neutral protease from Bacillus, it was found that stabilizing mutations
were all clustered in a certain surface region of the protein (Van den Burg et al. 1998;
Vriend et al. 1998). Further stabilization of the protein was found to be quite
21
straightforward as this region had been localized (Mansfeld et al. 1997; Van den Burg
et al. 1998).
The consensus approach, which is a semi-rational approach developed by
Lehmann and co-researchers, can be regarded as an expansion of Serrano’s rational
design of protein stabilization (Serrano et al. 1993; and previous section). This
strategy is built around the idea that the amino acids contributing to the stability of the
protein acid is retained during evolution and thereby a consensus residue should
contribute more to the stability of a protein than a non-consensus amino acid.
Therefore, while comparing the amino acid sequences of different homologous
proteins, the most frequently occurring residue should be used (Lehmann et al. 2000;
Lehmann and Wyss 2001; Lehmann et al. 2002). This strategy has turned out to be
successful for obtaining a highly thermostable fungal phytases (Lehmann et al. 2000)
and a more thermostable a-helical tetratricopeptide repeat (TPR) protein than its
natural counter part (Main et al. 2003).
Increasing the stability of proteins to proteases is also of interest in industrial
applications of enzymes. If the proteolytic pattern is specific, it would be relatively
easy to pinpoint the sensitive regions of the protein, and thus by rational design, alter
the amino acid content and stabilize the protein. In some cases, while a higher
temperature will unfold the proteins, the proteolytic stability correlates with the
thermal stability due to the exposure of flexible amino acid sequences (McLendon
and Radany 1978; Daniel et al. 1982; Parsell and Sauer 1989; Akasako et al. 1995).
However, even folded proteins could be attacked by proteases if they contain regions
that are accessible and flexible (Price 1990; Hubbard 1998). There are two different
foci for altering amino acids to increase their tolerance to proteolysis; i.e decrease the
conformational flexibility of the attacked structural region or changing the primary
structure and introducing amino acids that are disadvantageous for the protease
(Frenken et al. 1993; Markert et al. 2001).
22
Tolerance to alkaline conditions
Changing the primary structure by introducing amino acids that could increase the
tolerance of the protein towards harsh environment, such as temperature, pH or
proteases, is a general concept for some of the work presented in this thesis.
Asparagines are known to be susceptible to high pH, through covalent modifications
such as deamidation (see path a in Figure 3) or backbone cleavage (see path b in
Figure 3). Since NaOH is a common agent used to clean chromatographic media in
large-scale processes (for a more detailed description, see the section Affinity
chromatography) it is of importance for affinity ligands suitable for coupling to
chromatographic matrices to be tolerant to high pH. Glutamine is also susceptible,
though it is modified to a lesser extent than asparagine. These reactions are
spontaneous and may also occur at physiological solvent conditions, often resulting in
the loss of activity of the protein or peptide (Geiger and Clarke 1987). The extent of
modification of the different residues is highly sequence and conformation dependent
(Kossiakoff 1988; Lura and Schirch 1988; Kosky et al. 1999). The deamidation
reaction involves the main chain peptide nitrogen succeeding the asparagine. The
nitrogen functions as the nucleophile and attacks the side-chain carbonyl of
asparagine, resulting in a succinimide intermediate. This succinimide intermediate
may open at either of the two C-N bonds to form aspartic acid or isoaspartic acid,
resulting in an addition of a negative charge. These two isomers may occur in their L
or D forms (see path a in Figure 3).
Cleavage of the peptide chain could also occur at the asparagine residues. In these
reactions the mechanism proposed involves the side-chain amide nitrogen attacking
the Ca, forming a C-terminal succinimide, as illustrated in path b in Figure 3. Both
reactions are believed to occur simultaneously, although in general the deamidation
reaction is faster (Tyler-Cross and Schirch 1991). An interesting hypothesis has been
proposed by Robinson, in which through the reaction mechanisms presented above,
glutaminyl and asparaginyl residues in peptides and proteins act as molecular timers
of biological events such as protein turnover, development, and aging (Robinson et al.
1970; Robinson 1974; Robinson and Rudd 1974; Robinson and Lubke 1978; Tyler-
Cross and Schirch 1991).
23
Figure 3. Reaction mechanism for deamidation and backbone cleavage of asparagine
residues in peptides and proteins via the formation of a succinimide intermediate; where in a
the five-member succinimide intermediate is formed via a nucleophilic attack on the side-
chain carbonyl carbon of asparagine by the backbone nitrogen of the ensuing amino acid,
releasing NH3. The succinimide ring is labile to bases and readily opens, yielding either
aspartic acid or isoaspartic acid. In b, peptide cleavage could also occur through a
succinimide intermediate by attacking the side-chain amide of asparagine on the backbone
peptide carbonyl of asparagine.
C
NH2
NHRNH
H2C
C
H2C
O
O
RN+1
C
NH2
RNH
H2C
C
H2C
O
O
NRN+1
C
NH
RNH
H2C
C
H2C
O
O
RN+1
C
O
NHRNH
H2C
C
H2C
O
O
RN+1
O
O
C
NH
RNH
H2C
C
H2C
RN+1
O
a bAsparagine
SuccinimideSuccinimide
Aspartate isoAspartate
24
Protein-protein interactions
Many biological processes are regulated through protein interactions involving non-
covalent associations, for example signal transduction, cell regulation, immune
response, and regulation of enzymatic activities. Apart from basic science aspects, a
deeper understanding of the underlying principles of such biomolecular interactions
would be helpful for the design of improved or novel affinity proteins. In addition,
accurate prediction of binding surfaces, or hotspots from a three-dimensional structure
(Ma et al. 2001; DeLano 2002) would be beneficial for the design of either agonist or
antagagonist compounds for therapeutic applications. In general, hotspots residues in
protein-protein interaction are defined as residues that upon mutation cause a large
shift in binding affinity.
Kinetic studies
A specific, rapid association of protein complexes is essential for a range of diverseprocesses. The rate of association of a protein complex is diffusion controlled, and in
a random collision theory, the rate constant could be up to approximately 109 M-1 s-1
(Schreiber and Fersht 1996; Schreiber 2002). Most determined association rates are
some thousands times lower, but association rates close to the diffusion limit have
been measured (Fersht, 1999). In these cases, the speed of the process is functionallyimportant, and introduction of additional electrostatic forces has been used to enhance
the rate of association (Schreiber and Fersht 1996). The association of a pair ofproteins can be described as a two-step reaction, A+B ‹=› [AB]* ‹=› AB, where A and
B are the free proteins, [AB]* is the encounter complex, and AB is the final complex.
The two proteins, A and B tumble randomly around until they reach an areadesignated the steering region. These collisions create a transition state that
consequently produces the energetically favoured complex AB. The mechanismsbehind such complex formation have been a matter of considerable research
(Northrup and Erickson 1992; Janin 1997; Gabdoulline and Wade 1999; Selzer and
Schreiber 2001).
Many different strategies can be used to increase our understanding of the kinetics
of protein-protein interactions, for instance, adding cosolvents, introducing mutations
and changing the temperature or pH. The surroundings of the molecules are of great
importance for the relative association rate; for example a simple relationship between
25
kon and viscosity with a slope of ~1 has been demonstrated (Raman et al. 1992; Stone
and Hermans 1995). This means that the relative association rate (koon/k
von) in the
absence and presence of a viscous agent is linearly dependent on the relative viscosity
(h/ho). In addition, ionic strength and pH are of obvious importance for the
association of two biomolecules and different studies have shown a relationship
between kon and ionic strength which follow the Debye-Hückel equation
(Vijayakumar et al. 1998; Selzer and Schreiber 1999).
Measuring the effect of mutation is a powerful tool that can be used to interpret
protein-protein interactions. Extensive mutagenesis of the surface residues of different
binding partners, such as TEM1-BLIP, barnase-barstar, interferon-receptor, growth
hormone-receptor and interleukin-4-receptor, has demonstrated that mutations
involving charged residues significantly affect the kon, whereas mutations of
uncharged residues do not (Schreiber and Fersht 1995; Wang et al. 1997; Clackson et
al. 1998; Albeck and Schreiber 1999; Piehler et al. 2000; Selzer et al. 2000). When
introducing a substitution into a given protein, careful consideration has to be paid to
the structural changes the new residue will generate. Hence, it is essential to carry out
a structural comparison between the wild-type protein and the new mutated version.
To ascertain whether the change in affinity upon mutation of two different residues is
energetically independent on each other, employing a double mutant cycle is an
effective strategy. Double mutant cycles were introduced in 1984 by Carter and co-
researchers to study structural changes (Carter et al. 1984) changes. Later studies have
shown that this strategy also is suitable for investigating protein-protein interactions
(Schreiber and Fersht 1995; Frisch et al. 1997). By comparing the difference change
in the free energy (DDG) upon complex formation between the single mutants (A and
B) and HSA and the double mutant (C) and HSA (DDG=DGC-DGA-DGB), a
synergistic effect introduced by the mutations can be detected. If the effects of the two
single mutations are independent (which means DDG = 0), the residues do not effect
each other; otherwise DDG ≠ 0, which means that the mutations are dependent on
each other.
One very interesting benefit arising from this knowledge is how the association
rate is dependent on the electrostatic interactions. Using rational design, it has been
shown possible to design faster association without affecting the dissociation (Selzer
et al. 2000). The method is based on increasing the electrostatic attraction between the
26
proteins by incorporating charged residues in the vicinity of the binding interface.
Improving the steering region, by changing the electrostatic interaction between the
molecules, the association phase changes from random diffusion to directional
movement towards the complex formation. This could be a more advantageous
approach for enhancing binding affinity than affinity maturation by creating a library
and going through a selection procedure.
How important is the association and dissociation for the biological activity in the
different events? A number of previous studies have indicated that the individual
kinetic constants are indeed important; for example the human growth hormone
receptor (hGH) requires an increase in dissociation of 30 fold compared to its wild
type in order to bring about a linear dependence in EC50 for cell proliferation (Pearce
et al. 1999). Similar results have also been observed for interleukin-4 and interferon
(Piehler et al 2000; Wang et al 1997).
Measuring protein-protein interactions
A number of techniques currently exist for investigating protein-protein interactions.
Determination of the binding region through structural analysis of co-complexes, by
for example X-ray crystallography and nuclear magnetic resonance (NMR), are two
examples (Deisenhofer 1981; Wider and Wüthrich 1999). Measurements of the
strengths of interactions between the two proteins could be done for example with
isothermal titration calometry (ITC), surface plasmon resonance (SPR) and optical
spectroscopy (Lakey and Raggett 1998). In combination with site-directed mutations,
all of these could provide an excellent platform for investigating interactions.
One technique for measuring protein-protein interactions that has also been greatly
relied on in this thesis is SPR-based biosensor technology (Biacore). This
instrumentation monitors the complex formation and dissociation between
macromolecules in real time by transducing the accumulation of mass of an analyte
molecule at the sensor surface that is coated with a ligand molecule. The instrument
has been used to investigate numerous different biomolecular systems, including:
cytokine growth-factor-receptor recognition (Cunningham et al. 1989; Cunningham
and Wells 1989; 1993), coagulation factor assembly (Fan et al. 1998) and virus-cell
docking (Rux et al. 1998; Willis et al. 1998). There are several advantageous with
using optical biosensors, such as the possibility of real-time measurements allowing
27
for dissection of the interaction into association rate and dissociation rate components,
dispensing the need for labeling the biomolecules, Therefore the technique is very
useful in the design of antagonists and ligands whose efficacy depends on their
binding dynamics (Myszka 1997; Canziani et al. 1999). Sometimes it may not be
necessary to conduct a complete kinetic study, but rather an affinity and rate ranking
of the analytes, to investigate the relative affinity of two biomolecules to the same
target. To facilitate the interpretation it is advantageous if these different binding
molecules have approximately the same molecular weights.
A number of research groups have shown that using optical biosensor in
combination with site-directed mutagenesis provides a powerful technique for
identifying structural elements that are key determinants of specificity and affinity
(Bass et al. 1991; Albeck and Schreiber 1999; Gårdsvoll et al. 1999).
Bacterial surface receptors
Several pathogenic Gram-positive bacteria interact with host proteins through
receptors expressed as anchored to the bacterial surface. The biological significance
of this phenomenon in relation to pathogenicity and the immunogenic response is not
fully clear, but most probably the pathogenic bacteria create a layer of host proteins
around themselves (Achari et al. 1992; Sauer-Eriksson et al. 1995; Starovasnik et al.
1996). Surface proteins that are capable of binding to host specific proteins include
for example streptococcal protein G (SPG) and staphylococcal protein A (SPA). SPA
and SPG have both high affinities for immunoglobulin G (IgG) from different species,
and SPG can also bind serum albumin from a variety of species. SPA and SPG have
been thoroughly investigated for various biotechnology purposes such as
immunological tools in a vast array of immunoassays, and purification of
immunoglobulins (Amersham Biosciences 1997). Interestingly, the HSA-binding
domains from SPG and the IgG binding domains from SPA share the same scaffold
despite the fact that SPG’s IgG binding domain has a different scaffold. The Fc
binding parts of SPA and SPG are example of convergent evolution, where two
proteins have found two different structural solutions for binding similar proteins with
similar affinity.
28
Staphylococcal protein A
SPA is a cell-wall associated receptor exposed on the surface of the Gram-positive
bacterium Staphylococcus aureus. SPA has high affinity to IgG from various species,
for instance human, mouse, rabbit and guinea pig. (Richman et al. 1982; Amersham
Biosciences 1997). This indicates that SPA facilitates the ability of the bacteria to also
infect animals other than humans. The gene encoding SPA was sequenced by Uhlén
and co-workers in 1984 (Uhlén et al. 1984). SPA consists of three different regions; S,
being the signal sequence that is processed during secretion (Abrahmsen et al. 1985),
five homologous IgG binding domains E, D, A, B and C (Moks et al. 1986) and a cell
anchoring region XM (Guss et al. 1984; Schneewind et al. 1995) (see Figure 4).
A number of features of the IgG-binding domains on SPA; such as being highly
soluble, proteolytically stable, and devoid of cysteins have made these suitable for use
as affinity gene fusion partners for production and purification of recombinant
proteins (Ståhl 1999). In addition to the most used expression host E. coli, SPA has
been successfully expressed also in yeasts, insect cells and mammalian cells (Ståhl
and Nygren 1997).
Figure 4. The staphylococcal protein A shown here is a cell-wall associated receptor
consisting of a signal sequence (S) processed during secretion, five homologous IgG-binding
domains (E, D, A, B and C), and a cell-wall attaching structure (XM). Also shown is the
commonly used Z domain, corresponding to an engineered version of the B domain of SPA
(Nilsson et al. 1987).
Staphylococcal protein A (SpA)
S DE A B C X M
Z
57 kDa
7 kDa
Immunoglobulin binding
29
Each of the five domains in SPA is arranged in an antiparallell three-a-helical bundle
of approximately 58 aa. The structure is stabilized via a hydrophobic core. Each
domain has high affinity for the Fc part of IgG1, IgG2 and IgG4, estimated to be
approximately Kaff =10-8 (M), but shows only weak interaction with IgG3 (Kronvall
and Williams 1969; Ankerst et al. 1974; Jendeberg et al. 1997). In addition, each
domain has high affinity for the Fab part of certain antibodies (Potter et al. 1996;
Jansson et al. 1998). The binding site for the Fc part of the IgG molecule has been
shown in a study of the B domain, to involve 11 residues of helix 1 and helix 2
(Deisenhofer 1981). In addition, another study using the D domain showed that the
Fab-binding part was located distinctly apart from the Fc-binding part. The 11
residues involved in the Fab interaction are situated on the second and third helices
(Graille et al. 2000). Domain B is closest to a hypothetical consensus of the five SPA
domains (Moks et al. 1986) and was therefore chosen for further improvements.
In order to increase domain B’s own tolerance towards site-specific chemical
cleavage of fusion proteins using the chemical cleavage agent hydroxylamine, the
sensitive Asn-Gly dipeptide in the B domain at residues 28-29 was changed to Asn-
Ala by site directed mutagenesis (Nilsson et al. 1987), resulting in an engineered
domain denoted Z. This allowed for development of bioprocesses where after an
initial purification step of ZZ-target fusion proteins with IgG-affinity purification,
hydroxylamine could be used to cleave off Z from the target protein via an Asn-Gly
dipeptide sequence genetically introduced between ZZ and the target protein. In a
second IgG affinity purification step, the cleaved target protein was collected in the
flow through, while Z-domain proteins were captured in the column (Moks et al.
1987).
While introducing the single mutations A29G to the B domain the Fab interaction
diminished, probably due to the fact that the Ala would perturb the interaction
between the two molecules (Jansson et al. 1998; Graille et al. 2000). For the
application as immobilized affinity ligand for capture of IgG, previous work indicate
that a head-to-tail dimer construct of the Z domain has a similar molar binding
capacity for IgG as the native SPA molecule, which has five repetitive domains
(Ljungquist et al. 1989). The Z scaffold has also been used in protein engineering to
introduce new properties. For example 13 surface exposed amino acids at the binding
site could be randomized in a phage display library and several new binders were
possible to select (Nord et al. 1995; Nord et al. 1997).
30
Streptococcal protein G
In 1984 Björck and Kronvall isolated and named the protein G receptor from
Streptococcus strain G148 (Björck and Kronvall 1984). SPG is exposed on the surface
of the bacteria and consists of a signal peptide that is processed during secretion and
repetitive regions capable of binding immunoglobulins and serum albumin from
different species, respectively. The albumin-binding region is separated from the
immunoglobulin-binding region by a spacer region and a cell-wall anchoring region
named W is located in the C-terminus (Olsson et al. 1987) (Figure 5).
Figure 5. Schematic presentation of SPG. The albumin and IgG- binding regions consist of
three albumin and IgG-binding domains respectively (Olsson et al 1987), with a spacer
region, S between these two regions. The signal peptide Ss is processed during secretion
and W is the cell-anchoring region. The albumin-binding region has been cloned in different
constructions denoted BB, ABP and ABD containing 2.5, 2 and 1 domains respectively.
HSA binding region
The HSA-binding region of SPG consists of three homologous albumin-binding
domains (ABDs) separated by linkers of approximately 30 residues each (Olsson et al.
1987). Different parts of the albumin-binding region have been cloned and
characterized, (BB, ABP and ABD) with 2.5, 2 and 1 domains respectively (Ståhl and
Nygren 1997) (Figure 5). Each ABD domain consists of approximately 46 amino
acids. The domain has no additional stabilizing features such as bound ligands, metal
ions or disulphide bridges (Kraulis et al. 1996). HSA is postulated to contain one
binding site for protein G, formed by loops 6-8 (Falkenberg et al. 1992). Protein G
Streptococcal protein G
Ss E A1 B1 A2 B2 A3 S C1 D1 C2 D2 C3 W
Serum albumin binding
63 kDa
BB
ABP
ABD
25 kDa
15 kDa
5 kDa
Immunoglobulin binding
214 aa
121 aa
46 aa
31
shows strong interaction with serum albumin from different species including rat,
mouse, rabbit and human, but very low interaction to bovine serum albumin (Nygren
et al. 1990; Falkenberg et al. 1992; Johansson et al. 2002). These results imply that
streptococcus strain 148 could also be pathogen for rat and mouse.
Many of the positive features associated with the Z-domain; for example, stability
to proteolysis, high-level production, ability to be secreted, and a solubilization of the
fused protein can also be related to ABD (Nygren et al. 1988; Ståhl et al. 1997).
The ability of the ABD to bind serum albumin is also of interest from a therapeutic
perspective. Various difficulties have been encountered when administering proteins
for therapy purposes, such as low efficacy due to a rapid clearance rate from the
blood. Because kidneys generally filter out molecules below 60 kDa, efforts to reduce
clearance rates have focused on increased molecular size through glycosylation or the
addition of polyethylene glycol polymers (PEG) (Dennis et al. 2002). Alternatively,
the HSA binding ABD has been investigated as a gene fusion partner to produce
ABD-tagged proteins capable of binding to circulating serum albumin after
administration. Serum albumin is a protein with a long half-life exemplified by HSA,
which has an in vivo T1/2 of 19 days in humans (Peters 1985) Hence the half-life of
ABD would be extended by the binding to serum albumin. By fusing the human
soluble complement receptor type 1 (sCR1) to the albumin binding part of the SPG
Makrides with co-workers were able to an extended half-life of the sCR1 in rats
(Makrides et al. 1996).
Furthermore, the albumin-binding region BB seems to have immunopotentiating
properties when genetically fused to an immunogen (Power et al. 1997; Sjölander et
al. 1997; Libon et al. 1999). This property has not been fully elucidated yet, but it has
been proposed that it might result from T-cell epitopes (Goetsch et al. 2003) or the
serum albumin-binding affinity (Makrides et al. 1996; Sjölander et al. 1997). In a
recent study, it was proposed that the region involved in serum albumin binding also
contained a T cell epitope (Goetsch et al. 2003).
32
IgG binding region
The IgG-binding region of SPG consists of three individual IgG-binding domains,
where each one has high affinity for the Fc and the Fab regions of IgG. In contrast to
protein A, SPG exhibits binding to all human subclasses of IgG, including IgG3. SPG
also has a high affinity for IgG from several animals, including mouse, rabbit and
sheep (Åkerström et al. 1985; Amersham Biosciences 1997). The domains consist of
about 55 amino acids and the structure is constituted of two b-hairpins that are
associated to form a four stranded mixed antiparallel/parallel b-sheet with a single a-
helix lying across one face of the sheet. No extra stabilizing features such as metal
ions or disulfide bridges is needed for the stability of the domains as in the case of the
three helical scaffold of SPG and SPA (Åkerström et al. 1985; Gronenborn et al.
1991). Interestingly, the IgG binding domains of SPG show clear structural
similarities with the immunoglobulin light chain binding protein L from
Peptostreptococcus magnus (Wikström et al. 1994), despite the fact that their
sequence homology is low. The overall folds of proteins L and G are similar, though
the two proteins also demonstrate significant differences, the orientation of the a-
helices in protein L run nearly parallel to the b-sheet, while the helices in protein G
run diagonally across the b-sheet (Wikström et al. 1995). The Fc binding part of the
SPG molecule is located mainly in charged and polar residues of the helix and the
loop connecting the helix with the third b-strand (Gronenborn and Clore 1993).
Protein G binds Fc at the region that connects the CH2 and CH3 domains, thus SPA
and SPG bind to overlapping sites of the Fc-molecule. Interestingly, the Fab binding
region is almost non-overlapping with the Fc binding part of the molecule, located
mainly in the second b-strand and in the loop between the first and second b-strand
(Lian et al. 1994).
In summary, the bacterial domains originating from the surface receptors of SPA and
SPG are small, easy to produce, stable, and can be secreted. In addition, several
studies have shown that it is possible to change a number of amino acids at the
surface and retain the native structure (Klemba et al. 1995; Nord et al. 1995; Gräslund
et al. 2000). These features make the domains very interesting for protein engineering.
33
Affinity chromatography purification
A number of different protein purification techniques exist today, including ion-
exchange chromatography, reverse-phase and gel filtration, which take advantage of
differences in electrostatic characteristics, hydrophicity or the size of proteins in order
to separate them. One very powerful technique for protein purification is based on
biospecific interactions, namely affinity purification. A number of different
interactions have proven successful in this area, including for example interactions
between enzyme and substrate, bacterial receptor and serum protein, and antigen and
antibody (Nilsson et al. 1997). Some of the most commonly used affinity partners
have been listed in Table 1.
Table 1. Commonly used affinity fusion systems, modified from Nilsson et al. 1997.
Affinity tag Ligand Elution ReferencesProtein A hIgG low pH Ståhl and Nygren. 1997Z hIgG low pH Nilsson et al. 1987
Albumin binding protein
(ABP)
HSA low pH Nygren et al. 1988
Glutathione S-tranferase
(GST)
Glutathione Reduced
glutathione
Smith and Johnson 1988
Polyhistidine tag Me2+/Chelator Imidazole/low
pH
Porath et al. 1975
Maltose binding protein Amylose Maltose di Guan et al. 1988
FLAG peptide mAb1, mAb2 EDTA/low pH Hopp 1988
These different systems all have various characteristics, which have to be taken into
consideration when selecting purification strategy. Common for all listed systems is
that the target protein needs to be modified to include the affinity gene fusion partner,
which, if a native target product is desired, calls for efficient means to release the
affinity tag after the purification. In other and more attractive formats of affinity
chromatography, native target proteins can be directly purified, which obviously
requires that ligands recognizing such native targets are available. By usingcombinatorial chemistry, it is possible to generate new specific binders that could be
used as affinity ligands (Nord et al. 1997). Affinity chromatography has a number of
advantages over other purification techniques currently available; for instance it is an
easy, fast and selective means of capturing biomolecules. This allows the introduction
of an affinity-purification step early in the purification chain, and the number of
successive unit operations can be reduced, which would be a benefit in industrial
purification (Harakas 1994; MacLennan 1995). Achieving the final product in large-
scale industrial applications often requires the overall purification procedure to
include several consecutive unit operations. Previously it has been shown to be
34
advantageous to conduct initial purification before the affinity chromatography step,
for example precipitation or ion-exchange chromatography (Cutler 1996) for
removing some of the major contaminants and thereby increasing the column lifetime.
Purification of plasma proteins, such as human serum albumin (HSA) or
Immunoglobulin (IgG) has for a long time been employed for therapeutic
applications. In the mid-1940s, ethanol fractionation was introduced and is still in use
today together with other separations techniques, such as ion-exchange and affinity
chromatography (Foster 1992). Recently, affinity purification has been applied in fine
and rapid capture of plasma proteins in large-scale production. Some of the proteins
produced and purified in this process include factors VIII, IX and XI, von Willebrand
factor, protein C and antithrombin III (Burnouf and Radosevich 2001). Using affinity
techniques has dramatically improved the purity of the products, and thus unwanted
side effects, such as hemolysis, hypotension and fever is considered to be very rare
(Burnouf and Radosevich 2001). Development of affinity chromatography for
purification of plasma products in large-scale production faces a number of different
issues, such as the selection and development of ligands, leaching problems, the
stability of ligands exposed to cleaning procedures, and the capacity of the column
(Burnouf and Radosevich 2001).
In an industrial plant, the cleaning in place CIP solution is routinely applied
throughout the process after each purification procedure. This is done to diminish
contamination between different processes or batches. A universal chemical agent that
has been shown to be successful in the inactivation of most microorganisms, such as
bacteria, viruses, yeasts and also destroys endotoxins is NaOH in solution (Girot et al.
1990; Burgoyne et al. 1993; Asplund et al. 2000). However, the harsh conditions
associated with such CIP procedures involving high pH will decrease the performance
of many proteinaceous ligands in an affinity-chromatography process. The most
sensitive amino acids to alkaline treatments in several studies have been shown to be
Asn and Glu (Geiger and Clarke 1987; Kossiakoff 1988; Lura and Schirch 1988). The
overall stability of the protein is also dependent on secondary structure elements
surrounding these amino acids and neighboring amino acids (Robinson and Robinson
1991; Wright 1991; Kosky et al. 1999; Xie et al. 2000; Robinson and Robinson
2001). A more detailed description about the susceptibly of asparagine residues in
alkaline conditions can be found in the section of the thesis entitled tolerance to
alkaline condition. Improving the stability of a protein in alkaline treatment will not
35
only improve its performance as an industrial affinity purification ligand, it might also
decrease the leaching problem. As a result, the costs of using a proteinaceous ligand
in a large-scale purification scheme will be reduced. The use of affinity-based
chromatography has as a consequence of the above issues, hitherto not been as
extensively used as predicted.
36
Present InvestigationThe research presented in this thesis covers a number of different applications of
protein engineering technology where site-directed mutagenesis has been used to
study and improve the performance of bacterial domains in biotechnological
applications.
In order to explore the binding surface of ABD originating from SPG, a number of
surface exposed amino acids were substituted and the different mutants were analyzed
with SPR technology. Thereby, the contribution from the different amino acid on the
affinity to HSA was discovered.
To improve the ABD for biotechnology applications, amino acids sensitive to
alkaline conditions were replaced to obtain an increased tolerance to alkaline
conditions. In addition, different connective linkers were analyzed, for the production
of divalent ligands. Since the stabilization strategy worked successfully in improving
the alkaline stability of ABD, a similar strategy was investigated for alkaline
stabilization of two other protein domains, namely the IgG-binding C2 domain
originating from SPG and the Z domain originating from SPA.
HSA binding domain (I)
Mutational analysis of an albumin binding domain
An alanine scanning procedure was carried out to localize the surface on ABD
responsible for the interaction with HSA. Initially, residues in positions E3, Y20, E32
and E40 were replaced. These amino acids were chosen as they were surface-exposed,
located on all three a-helices, and pointing in different directions. In order to ensure
an easy purification procedure, all ABD constructs were fused to the IgG- binding Z-
domain. Of the four first residues chosen, Y20A was determined to contribute most to
the interaction (see Table 2). To determine more precisely which amino acids were
involved in the interaction, further alanine substitutions were made in helix 2.
Residues in positions S18, D19, Y21, K22, N23, L24 and K29 were replaced by
alanine to determine their respective contributions to the interaction with HSA. To
analyze the effect of multiple mutations on structure and affinity, three additional
mutants were made, ABD(Y20A, E40A), ABD(Y20A, E32A) and ABD(S18, Y20A,
37
K22A). An extensive biosensor-based binding study was performed to analyze the
affinity of the different mutated protein domains to HSA.
The CD spectra of the mutated proteins were recorded to analyze the effect on the
secondary structure, as this has proven to be suitable for detecting structural changes
in a-helical proteins (Johnson 1990; Nord et al. 1995). The various mutants of ABD
were subjected to a subtractive CD spectroscopic analysis in which the signal
contribution from the Z domain was subtracted (Nord et al. 1997). The results from
the CD measurements show that the backbone configuration is similar for all
constructs. However, because the exact structures of the different mutants are
unknown, minor changes in the structure due to the mutations cannot be ruled out
(Clackson et al. 1998; Vaughan et al. 1999).
Table 2 presents the results of the kinetic study with the SPR technology (Biacore).
Residues in the second helix give a larger contribution than residues in the first and
third helices. In the same table, it can be seen that the two tyrosines at positions Y20
and Y21 located in the second helix, are the residues that have the largest effect on the
affinity between ABD and HSA. These two tyrosines are both located in the N-
terminal part of the second helix, and are also surface-exposed. Interestingly, residue
D19, which is close to both tyrosines, does not appear to contribute to the interaction.
Both HSA and ABD are negatively charged at the pH used in the binding studies.
This can explain why replacing a positively charged Lys with an Ala in position 29
decreased the association rate, and accordingly why replacing the negatively charged
Glu acids in positions 32 and 40 with an Ala increased the association rate.
In order to further verify the position of the binding surface, three mutants were
constructed through changing three neighbouring amino acids at a time. Alanine
substitutions were made in helices one and three, in positions where the amino acids
were pointing away from the postulated binding site. The resulting proteins were:
ABD*(E3A, V6A, L7A), ABD*(R10A, E11A, K14A) and ABD*(K35A, I38A,
D39A). More information about ABD* can be found in the section of the thesis
entitled Stabilization of ABD towards alkaline conditions. All three mutants were
shown to have similar or better affinity to HSA than the parental molecule. Hence, the
conclusion is that the main part of the binding site is located in the second helix, and
the two tyrosines have the greatest impact on the stability of the interaction between
ABD and HSA. Interestingly, Johansson and co-workers found in an NMR study that
a larger part of the ABD molecule was found to be affected while binding to HSA
38
(Johansson et al. 2002). This could be explained by the fact that in the NMR
experiment, interaction surfaces described by chemical shift perturbation methods are
usually larger than the region in direct contact (Spitzfaden et al. 1992; Foster et al.
1998). This illustrates the differences between using these two methods and how they
could complement each other.
Table 2. An overview of the kinetic study of the ABD variants carried out on the Biacore.
koff kon Kaff DDG
[vs wt]ZABD variant [10-3 s-1] [105 M-1s-1] [107M-1] [kcal/mol]
wt 0.6 (0.2) 1.4 (0.2) 25.9 0.0 (0.2)E3A 0.6 (0.3) 1.4 (0.7) 22.2 0.1 (0.1)
S18A 3.5 (1.6) 1.3 (0.3) 3.9 1.1 (0.1)
D19A 0.8 (0.3) 1.5 (0.3) 20.9 0.1 (0.3)
Y20A 5.1 (2.1) 0.9 (0.2) 1.9 1.5 (0.2)
Y21A 3.9 (2.4) 0.1 (0.07) 0.3 2.6 (0.2)
K22A 1.3 (0.7) 0.7 (0.2) 5.6 0.9 (0.2)
N23A 0.9 (0.3) 1.0 (0.1) 12.7 0.4 (0.1)
L24A 0.6 (0.4) 0.3 (0.02) 4.5 1.0 (0.2)
K29A 1.1 (0.4) 0.3 (0.1) 3.4 1.2 (0.6)
E32A 2.4 (0.9) 2.5 (0.3) 12.2 0.4 (0.3)
E40A 1.2 (0.5) 2.6 (1.5) 29.5 -0.1 (0.6)
Y20E32A 17 (11) 0.5 (0.2) 0.5 2.3 (0.1)
Y20E40A 6.8 (2.1) 1.4 (0.1) 2.1 1.5 (0.1)
S18Y20K22A 6 0.0001 0.0002 7
Standard deviations are given in brackets. Note that as the very low affinity of the triple
mutant leads to problems in the detection of the binding, no standard deviation is given for
that specific mutant.
Electrostatic interactions have been found to be an important tool for the association
of biomolecules (Selzer and Schreiber 1999; Selzer et al. 2000; Schreiber 2002). This
could also be seen in the interaction between ABD and HSA. Some of the mutations
that seem to affect the association could be explained by removal or addition of
charges, for example E32A and E40A. Interestingly, when exchanging a glutamatic
acid for an alanine in position 32, both the association rate and dissociation rate
increase (see figure 6). It has been shown in previous studies that a mutation can have
a specific effect on either kon or koff (Schreiber and Fersht 1995) giving an unchanged
39
affinity constant despite large changes in the on- and off-rate. In the third helix,
substitution both in position 32 and 40 results in a slightly increased kon.
The importance of the electrostatic interactions could also be seen when alanines
were introduced into the three different ABD* variants where the side chains are
located on the opposite side of the postulated binding site. The binding analyses show
that the off-rate is almost identical for all three mutants; indicating that the stability of
the ABD-HSA complex has not been affected. However, one of the mutants shows an
increased on-rate. This can be explained by the change of charge of the molecule
resulting from changing negatively charged aspartic acid to an uncharged alanine,
which might increase the electrostatic attraction between HSA and ABD, as both are
negatively charged at the pH used in the binding studies. Furthermore, in this triple
mutant, a positively charged lysine was also exchanged for an alanine. This might
help to direct the HSA-binding surface of ABD to the HSA molecule. These two
mutations could thereby increase the “steering region”, as described in the paper by
Seltzer and co-researchers (Selzer et al. 2000). The steering volume is defined as the
volume surrounding a molecule in which it through electrostatic interactions could
change its movement from random diffusion to directional movement towards the
complex formation.
40
Figure 6. The three-dimensional structure of ABD displaying the effect of different mutations,
where: (A) shows the change in kon by mutation, with orange indicating a decreased on-rate,
green an increased on-rate, and yellow an unchanged on-rate where changing a residue to
alanine; (B) shows the change in the off-rate when replacing certain residues for alanine, with
orange indicating that the off-rate increases upon mutation and yellow that the exchange to
alanine does not affect the koff
Stabilization of ABD towards alkaline conditions (II & III)
A chemically stable protein ligand with high affinity for albumin would be interesting
from a biotechnological point of view, due to the fact that HSA is the most abundant
protein in clinical use worldwide. HSA is used to restore colloidal osmotic pressure in
severe burn damages, and to treat the of loss of albumin in traumatic accidents. HSA
for industrial purposes is produced by fractionation from serum, though a
recombinant process in yeast is also available (Quirk et al. 1989).
The work presented in Papers II and III includes a protein engineering strategy to
stabilize and optimize proteinaceous ligands for large-scale applications, namely
ABD. The model chosen for this thesis was an ABD domain originating from SPG
(Kraulis et al. 1996). A more detailed description of this domain can be found in the
chapter of the thesis entitled Bacterial surface receptors. The asparagine residues that
are known to be sensitive to alkaline conditions (Geiger and Clarke 1987; Kossiakoff
1988) were replaced by comparing the ABD-domain to homologous sequences (see
Figure 7), i.e other albumin binding domains. This procedure suggested that,
asparagines in positions 9 and 27 could be replaced by leucine and lysine, while
A B
41
asparagine in positions 23 and 26 could be replaced with aspartic acids. The new
mutant ABD (N9L,23D,26K,27D) was denoted ABD*. The single domain was then
characterized with respect to its affinity, stability and function as an affinity ligand.
LAEAKVLANRELDKYGVSDYYKNLINNAKTVEGVKALIDEILAALP ABDwt--K--AD-LK-FN----------------------D-QAQVVESAK SPG ABD-1--------------------H-----K------IME-QAQVVES SPG ABD-2-DN--NA-LK-F-R------------K------IME-QAQVVES DG12 ABD-1-S---EM-I----AN----F--DK-DD-------V--K-L--NS DG12 ABD-2--------L-------------D--DK------------------- ABD*
Figure 7. The primary sequence of ABD (here denoted ABDwt) (Kraulis et al. 1996) and
ABD*. Shown are also homologous sequences of albumin binding domains derived from
other strains of Streptococcus as well as the homologous domains from SPG. These
homologous sequences were referred to when constructing ABD*. SPG is derived from
Streptococcus G148 (Olsson et al. 1987), DG12 from Streptococcus DG12 (Sjöbring 1992)
and PAB (ALB-strains) from Peptostreptococcus magnus (de Chateau and Björck 1994).
After substituting amino acids in a protein scaffold, it is important to characterize how
the mutations affect the protein. A kinetic study was carried out with the Biacore, and
the structure along with the thermal and chemical stabilities were analyzed with CD.
The kinetic parameters for binding ABDwt and ABD* to HSA is shown in Table 3.
The binding behavior of the mutated protein was similar to the binding behavior of
the native protein. The dissociation rate constant was almost identical, while a
decrease could be seen in the association rate constant. An explanation could be that
the introduced mutations affect the “steering region”, as has been shown by Selzer
and co-workers and is discussed in the chapter of the thesis entitled Protein-protein
interactions (Selzer et al. 2000; Selzer and Schreiber 2001).
42
ka
[M-1 s-1]
kd
[s-1]
KA
[M-1]
DDG
[kcal mol-1]
ABD 11x104 1.2x10-3 9.0x107 -
ABD* 2.5x104 1.3x10-3 1.9x107 0.9
Table 3. Parameters of the binding of ABD and ABD* to HSA. ka is an association rate
constant. kd is a dissociation rate constant. KA is the affinity constant. DDG is the difference
in binding free energy between ABDwt and ABD*.
The ABD* molecule also appears to have a similar secondary structure to ABDwt
according to the CD measurement. However the a-helical content seems a little
decreased in ABD* compared to ABDwt. The thermal and chemical stabilities were
analyzed with a CD spectropolarimeter. Both proteins show high stability to both
types of denaturation and consequently a defined unfolded state was hard to reach
during the measurements (see Figure 8). Therefore the midpoint values of temperature
or denaturant-induced transition have been used as estimations for melting points. The
Cm value for ABDwt, when denaturating with GdnHCl, was estimated to be 4.2M,
and more than 5 M for ABD*. When analyzing thermal stability, the mutant was
found to be more stable than the native molecule. The Tm value was estimated to be
70 ºC for ABDwt , and over 80 ºC for ABD*.
43
Figure 8. CD-analysis of ABD and ABD*, for a comparison of the structural stability. The
protein concentration was 0.5 mg ml-1 in a phosphate buffer of pH 7. The signals at 222 nm
have been transformed to MRE. (A) Stability towards chemical denaturation. The
temperature is 20°C and concentration of chemical denaturant, GdnHCl, is varied between 2
and 6 M. (B) Stability towards thermal denaturation. The temperature was varied between 40
and 95ºC.
Stability to alkaline treatment was analyzed by three different approaches. In order to
analyze the functionality and stability of ABD* the protein was immobilized to a
standard affinity matrix by N-hydroxysuccinimide (NHS) amine coupling chemistry.
An analysis of the capacity of the new column was done by loading an excess of HSA
into the column then measuring the amount of eluted material to determine the total
capacity.
44
The selectivity of the mutated protein was analyzed and compared with the wild type
by mixing the HSA with protein extract from E. coli. A washing step was included
between each purification cycle, wherein a solution containing 0.5 M NaOH was
pumped through the column for two minutes. After 34 minutes of exposure to high
pH, the ABDwt column showed a 50% decrease in capacity, while the ABD* column
on the other hand, seemed to retain almost all capacity despite the harsh treatment.
After rounds 2, 8 and 15, the eluted material was analyzed with SDS-PAGE and
compared with pure HSA to examine how the specificity had been affected (see
Figure 9). The results indicated that the column with immobilized ABD* retained its
HSA selectivity.
Figure 9. Analysis of different protein fractions after affinity purification with an integrated
CIP-step using ABD* as affinity ligand coupled to the matrix. SDS-PAGE gel (4-20%
gradient) under reducing conditions. Lane 1 and 2, ABD and ABD* respectively; lane 3, a
molecular weight standard; lane 4, E. coli disintegrate spiked with HSA before column
loading. The purification procedure was repeated several times; lane 5, 6 and 7, show the
eluted material after round 2, 8 and 15 respectively; lane 8 shows HSA reference.
After the work with the single domain was done, an optimization approach was
undertaken to increase the capacity for HSA. In order to improve the ABD* domain
as an affinity ligand in HSA purification, a head-to-tail dimeric version was
constructed through genetic engineering. A divalent capturing ligand could potentially
contribute here by creating advantageous avidity effects in the binding between the
ligand and the target, possible binding of two HSA molecules, as well as by providing
a spacer between the solid phase and the solution. Hence, a larger ligand would have a
beneficial effect on the presentation of the ligand to the surrounding solution. The
1 2 3 4 5 6 7 8
94
kDa
67
43
30
2014
45
divalent ABD* motif was also equipped with a unique C-terminal cysteine residue,
providing a tool for directed coupling of the ligands to the solid chromatographic
resins.
Previous work done on linker regions connecting domains has shown that these
regions are important for the stability and folding of the protein (Robinson and Sauer
1998) and careful consideration has to be taken when designing them (Alfthan et al.
1995; Arai et al. 2001; George and Heringa 2002). These regions are highly flexible
and therefore susceptible towards proteases (Hubbard 1998) and CIP conditions
(Kosky et al. 1999). Three different linkers were investigated, VDANS, VDADS and
GGGSG (each given a single amino acid letter code), referred to as A, B and C
respectively. The first linker (A) was a result of the cloning procedure. In the second
linker (B), the asparagine was replaced by an aspartic acid according to the previously
reported fragility of Asn-Ser sequences (Geiger and Clark 1987). The third linker (C)
was composed of glycine and serine residues that in previous reports have been found
to be stable and highly flexible (Argos 1990; Alfthan et al. 1995; Takeda et al. 2001).
The length of these designed linkers are about five residues, which can be compared
to the naturally occurring linkers in SPG, which are about 15 to 30 residues (Olsson et
al. 1987). On the other hand, in SPA the linkers between the domains are
approximately 8 to 13 amino acids (Uhlén et al. 1984).
Binding studies were performed to elucidate differences in the binding capacity
between the monovalent original construct ABD* and the divalent variant, the ABD*
dimer A. Additionally, two different chemistries were used to examine the importance
of the coupling-chemistry when attaching the domains to a solid phase. The non-
specific amine coupling was compared to directed immobilization through the C-
terminal cysteine. As can be seen in Figure 10, the directed coupling gives a higher
overall binding capacity than when non-directed chemistry was used. The divalent
variant shows a higher proportion of active domains than the monomer does, when
using non-direct coupling chemistry. Interestingly using a directed-coupling
chemistry, the divalent variant shows the same proportion of active domains as the
monovalent variant.
46
Figure 10. Biosensor analysis of the interactions between injected HSA and different ABD
constructs. The monovalent ABD* and one divalent variant (ABD*dimerA) were immobilized
on the chip surface by (A) NHS-chemistry (non-directed) or (B) thiol-chemistry (directed),
respectively. The amount immobilized ABD*-domains was similar in all cases (for NHS-
chemistry: ABD* 970 RU, and ABD*dimerA 900 RU; for thiol-chemistry: ABD* 905 RU, and
ABD*dimerA 894 RU). A 300 nM HSA solution was injected over the different surfaces. Mean
values from duplicate samples are shown.
The different divalent ABD* variants as well as the monovalent ABD* domain were
coupled separately to activated sepharose by recruiting their C-terminal cysteines,resulting in directed coupling. The different affinity media were packed into columns
and used in affinity purification experiments for HSA-binding capacity studies. Theresults have been summarized in Table 4. These results were in agreement with the
biosensor studies that the divalent and monovalent proteins were equally accessible
for HSA molecules when directed-coupling chemistry was used for immobilization.Furthermore, the data indicate that it might be possibly to increase the capacity of an
0
200
400
600
800
1000
1200
1400
1600
0 200 400 600 800 1000 1200 1400
Time[sec]
Response[RU]
[RU]
ABD*dimerAABD*monomer
0
100
200
300
400
500
600
700
800
0 200 400 600 800 1000
1200
1400
Time[sec]
Responsnse[RU]
ABD*dimerA
ABD*monomer
47
affinity column by immobilizing a divalent ligand to increase the amount of coupled
ligands on the surface of the matrix. In the experiments conducted here, theABD*dimerB (13 mg) exhibits more than twice the capacity of the monovalent
variant ABD* (5 mg).
Table 4. Dynamic binding capacity of the different ABD* chromatography matrices.
ConstructLiganddensity[mg/ml]
Columnvolume
[ml]
CoupledABD*domain
[nmol]
HSA[nmol]
BoundHSA/
coupledligand
HSA[mg/ml]**
ABD* 3.0 1.06 440 71 0.16 5
ABD*dimerA 3.4 1.00 534 95 0.18 6
ABD*dimerB 5.1 0.82 656 159 0.24 13
ABD*dimerC 2.6 0.98 406 86 0.21 6
Mw for ABD* and ABD*dimer A, B, and C are 7221.3, 12753.7, 12051.7, and 12585.7
respectively.
** The values have been weighed to the total column volume, i.e. capacity of the
column/volume of the column.
Further, the different affinity media with their attached monovalent and divalent
affinity ligands were subjected to a stability study. The results of this study have been
summarized in Figure 11. All the ligands possess a high tolerance to alkaline
exposure, however the ligands containing the VDADS linker show the highest
tolerance. Even after as long exposure as 7 h in 0.1 M NaOH, the capacity of the
ABD*dimerB remained at about 95% compared to approximately 85% for all the
other ligands. It is interesting that a divalent ligand could be more tolerant to alkaline
conditions than the monovalent ABD* ligand. The reason for this remains elusive, but
it can be speculated that the two domains in a divalent ligand could exert a mutual
stabilizing effect relating to refolding after exposure to alkaline conditions (Robinson
and Sauer 1998; Wenk et al. 1998).
48
Figure 11. Influence of alkaline sanitation on the HSA binding capacity of an affinity column.
The monovalent ABD* ligand and the three divalent ABD* ligands were separately analyzed
in a column chromatography protocol in order to explore the tolerance to repeated alkaline
sanitization (0.1 M NaOH). After injection of HSA, the captured protein were eluted and the
binding capacity determined. In order to clean the affinity purification device, 0.1 M NaOH
was pumped though the column for 20 minutes between each purification round. The
ligands were immobilized using thioether chemistry by taking advantage of the C-terminal
cysteine. ◊;ABD*dimerA, o; ABD*dimerB, D; ABD*dimerC, x; ABD*monomer.
0,0
20,0
40,0
60,0
80,0
100,0
0 50 100 150 200 250 300 350 400 450 Time of exposure [min]
Capacity[%]
Linker BLinker ALinker CABDmonomer
49
IgG binding domains
Stabilization of C2 towards alkaline conditions (IV)
The same strategy that was applied to enhance ABD for industrial applications was
investigated for alkaline stabilization of the IgG-binding domain C2 originating from
SPG. The sensitivity of these domains to alkaline pH has earlier been reported
(Goward et al. 1991). Although this structure differs considerably from the ABD-
domain worked with earlier, the same stabilizing strategy could possibly still be
applied. First, the sensitive Asn residues were replaced and then a divalent variant
was constructed in order to increase the capacity of an affinity matrix for IgG capture.
Instead of replacing all the asparagines simultaneously, each asparagine was replaced
one by one, to investigate their contribution to the deactivation during alkaline
treatment (Stephenson and Clarke 1989; Wright 1991). In addition, the aspartates and
glutamines were replaced to investigate whether the tolerance to alkaline conditions
could be increased even further (Stephenson and Clarke 1989; Wright 1991;
Tomizawa et al. 1995). The amino acid composition of C2 is shown in figure 12, with
the sensitive asparagines highlighted.
Three single mutants were designed to resolve the contribution of each asparagine
to the deactivation rate, C2N7A,C2N34A and C2N36A. In addition, one variant was
constructed with two asparagines exchanged for alanine (denoted C2N7,36A), and one
constructed with three asparagines exchanged for alanine (denoted C2N7,34,36A). A
second generation of mutants was then generated using the most stable mutated
variant (C2N7,36A) as a scaffold. Two single mutants and one triple mutant were
designed yielding a protein where the aspartate residues were substituted for
glutamate residues in order to retain the overall charge, and these were designated:
C2N7,36AD35E, C2N7,36AD39E and C2N7,36AD21,45,46E respectively . In order to explore the
sensitivity of the single glutamine in the structure, C2N7,36A was used as a scaffold
again and the glutamine was substituted for alanine resulting in C2N7,36AQ31A.
50
Figure 12. The 55-residue sequence of the C2 domain (Olsson et al. 1987). The aspargagine
were replaced with alanine.
The different mutants of C2 were analyzed regarding affinity, structure and stability
using Biacore, CD and isoelectric focusing gel electrophoresis (IEF). In addition, an
affinity chromatography scheme was used to analyze their tolerance to alkaline
treatment.
The strategy involved the replacement of each asparagine residue on a one-by-one
basis to investigate and assess each individual asparagine’s contribution to function
and stability as an affinity ligand. Mutations N7A and N36A were found to be optimal
for increasing the tolerance of the IgG-binding domain C2 to alkaline treatment. In
addition, genetically fused dimers of this double mutant were designed and exhibited
same tolerance as the monovalent double mutant.
SPR technology was used to investigate the interaction between the Fc fragment of
IgG and the C2 variants. As can be seen in Table 5, C2, C2N7A, C2N36A and C2N7,36A
all had approximately the same kinetic properties.
Table 5. Parameters of the interaction of C2 and C2 mutants to Fc from human IgG,
measured by SPR. All calculations have been done with Fc immobilized on the surface.
ka [M-1 s-1] kd [s
-1] KA [M-1]
C2 2.9x105 27.0x10-3 1.1x107
C2N7A 2.3x105 21.1x10-3 1.1x107
C2N36A 2.0x105 13.2x10-3 1.5x107
C2N7,36A 2.2x105 13.4x10-3 1.7x107
ka is the association rate constant, kd is the dissociation rate constant and KA is the affinity
constant (ka/kd).
Potentially, a divalent ligand also could beside the availability of two affinity sites
lead to advantageous avidity effects in the binding between the ligand and the target.
It could also provide a beneficial effect by effectively presenting the immobilized
ligand, by providing a spacer.
A
TYKLVINGKTLKGETTTEAVDAATAEKVFKQYANDNGVDGEWTYDDATKTFTVTE
AA
51
A CD study was carried out to investigate the structural impact the different mutations
had. These CD results indicated that all variants exhibited similar secondary structure
contents as the parental protein G fold, although the CD signal was slightly decreased
for some of the variants compared with the wild-type C2, indicating that only small
changes arose in the secondary structure on mutation. The variant C2N7,36A and the
wild-type C2 were subjected to thermal and chemical denaturation with GdnHCl in
order to analyze their structural stabilities. The change in signal upon denaturation
was measured at 217 nm (a typical minima for a b-sheet proteins). In both studies, all
proteins adopted clearly defined pre and post transitions, and subsequently the signals
could be transformed to Fapp. For the wild-type C2, the thermal Tm1/2
was 77 ºC and
Cm1/2 was 2.9 M; The mutant C2N7,36A had a slightly lower Tm
1/2 of 71 ºC, and also a
lower Cm1/2 of 2.5 M.
As has been shown elsewhere (Geiger and Clark 1987; Tyler-Cross and Schirch
1991) the Asn residues can be modified in alkaline conditions to Asp or isoAsp. This
results in an increased negative charge on the protein, which can be studied by
isoelectric focusing (IEF). The IEF study indeed showed that after two hours of
exposure in 0.1M NaOH, the C2 protein undergoes a transformation to a new more
negatively charged species. The double mutant on the other hand revealed no
additional charge indicating that the deamidation-susceptible residues were
substituted.
The ability of C2 and all mutated-C2-variants to function as affinity ligands in an
ordinary purification scheme for IgG antibodies was investigated by immobilization
of the different domains on HiTrap‘ columns (Amersham Biosciences). Between the
different cycles, a two-minute CIP step consisting of 0.1 M NaOH was integrated.
The results of the capacity study presented in figure 13 show that after a total of 18
minutes of exposure to NaOH, the C2 column had only about 30% capacity left. The
C2N7A column showed a similar loss of binding capacity, while the C2N34A column
lost capacity even faster. The C2N36A column showed a significantly higher stability;
as did the double mutant C2N7,N36A column. In an attempt to increase the stability even
further, several mutants were designed in which the electrostatic nature of the domain
was intentionally retained through replacement of aspartate with a glutamate. The
double mutant C2N7,36A was used as a scaffold for introducing an alanine to the single
glutamine residue substitution. However, the different aspartate and glutamine
52
substitutions revealed no further tolerance to the CIP treatment (see Figure 13). In
conclusion, it was possible to stabilize one of the IgG-binding domains from
streptococcal protein G in respect to alkaline conditions, by employing a protein
engineering strategy.
Figure 13. Comparison of capacity after repeated CIP-treatment following a standard affinity
chromatography protocol on C2 and all the mutated variants C2-variants as immobilized
ligands. The cleaning agent was 0.1 M sodium hydroxide.
0
20
40
60
80
100
120
2 4 6 8 10 12 14 16 18 20 22 24 26 28
Capacity[%]
Time of exposure [min]
C2N7,36AdimC2N36AC2N7,36AC2N7,36AD35EC2N736AD39EC2N7,36AD21,45,46EC2N7,36AQ31A
C2dimC2C2N7A
C2N34A
53
Stabilization of Z towards alkaline conditions (V)
SPA is one of the most widely used affinity ligands in affinity chromatography.
Previous studies have shown that SPA-based chromatography media are relatively
stable in CIP conditions. A loss of about 1% in binding capacity with exposure to 0.5
M NaOH for 15 minutes has been reported (Hale et al. 1994). However for large-scale
applications it would it be valuable to have an even more stable ligand. As a starting
scaffold for further stabilization, the Z domain originating from the B domain in SPA
was used. The three-dimensional structure of the Z domain has been illustrated in
Figure 14, indicating all the asparagines and the different substitutions made in this
study. The Z domain consists of 58 amino acids, which includes eight asparagines in
positions: 3, 6, 11, 21, 23, 28, 43 and 52 (Nilsson et al. 1987).
Figure 14. The three-dimensional structure of the Z domain (Tashiro et al. 1997). All
asparagines and the different substitutions are indicated.
In an initial trial, phage display technology was used as a means to select Z variants
with retained IgG binding capacity after substitutions. The library was designed with
randomizations at positions 21, 29 and 52. Position 29 was chosen to investigatewhether it was possible to retain the Fab interaction with an increased alkaline
stability. The selection procedure consisted of three rounds of panning with IgG as
bait. After the selection, a number of colonies were sequenced and analyzed. Since
N3N6A
N11S
N21A
N23T
N28AN43E
N52A
54
the Z-domain already is significantly stable to alkaline conditions it was not possible
to introduce alkaline treatment in the selection procedure. Therefore none of theselected binders achieved an increased alkaline stability compared to the native Z
domain.
An alternative strategy to phage display is to use a by-pass mutagenesis method
(Kotsuka et al. 1996). This strategy involves the use of a domain analogue as starting
template, into which a destabilizing mutation has been introduced to simplify the
search for variants of increased stability. Secondary mutations are then introduced and
the effects analyzed. Mutations that improve stability of the destabilized molecule are
then grafted into the original protein. Previous studies on the Z domain have shown
that a mutation of phenylalanine 30 to an alanine, destabilize the structure about 3.5
kcal/mol (Cedergren et al. 1993). The original phenylalanines side chain contributes
to the stability by being part of the hydrophobic core.
Z MKAIFVL GTAD NKFNKEQQNAFYEILHLPNLNEEQRNAFIQSLKDDPSQSANLLAEAKKLNDAQAPKZ(F30) -------NAQHDEAVD ---------------------------A----------------------------
E AQHDEA------QV-NM----AD---G--------------V-G--Q----S----D ADAQQ-N---D--S------NM---------G----------------G------ES----A AD -N-------------NM---------G----------------S------ES----B AD --------------------------G-----------------------------C AD --------------------T-----G----------V-KEI--------------
Figure 15. Amino acid alignment of the Z, Z(F30A) and five homologous domains (E,D,A,B,
and C). The horizontal lines indicate amino acid identity. The replaced asparagines and
glycine in the B domain are underlined. Z(F30A) and all its mutants include the same N-
terminal as Z(F30A). Z(N23T) was constructed with the same N-terminal as Z.
A comparison of the amino acid sequence in the different homologous domains in
SPA, suggests that asparagines on position 11, 23 and 43 could be replaced by serin,
threonin and glutamic acid respectively. The asparagines in position 6, 21 and 28
were replaced by alanines, as no obvious alternative amino acid exists in the
homologous domains. As can be seen in Figure 15, there is an asparagine in position
3. As this is in the flexible N-terminal end of the domain and outside the ordered part
of the structure, it was reasoned that this would probably not contribute to the alkaline
tolerance of the entire domain, and was therefore excluded from the study. However
55
this position will still be very important to investigate if multimeric constructs are
desired.
When the single mutants had been constructed, a study was undertaken to
investigate how the introduced point mutations affected the function of the Z variants
as affinity ligands. Before this investigation could proceed, a careful study was
necessary to characterize how the single mutations affected structure and affinity.
Structure analysis was performed using CD, and the affinity was elucidated with a
Biacore where different Z domains were compared to the native Z molecule.
The structural analyses using CD showed that all constructs exhibited CD spectra
similar to the native Z molecule. All spectra had typical a-helical characteristics with
a minimum of 208 and 222 nm, in combination with a maximum of around 195 nm.
However Z(F30A, N52A) seemed to have a somewhat lower a-helical content than
their parental Z molecule, and the other mutants thereof. This might be due to the
postulated hydrogen bond between dO of N52 and the backbone amide proton of
N21, and that the side chain of N21 is hydrogen postulated to bind the carbonyl
oxygen of N52 (Starovasnik et al. 1996).
Biospecific affinity interaction analysis demonstrated no dramatic effect in the
affinity of any of the variants (see Table 6). As can been seen in the same table, the
suppressor mutation F30A did not seem to decrease the affinity between the Z domain
and IgG. Rather the opposite can be seen, which is in accordance with earlier results
reporting that a small increase in affinity could be measured (Cedergren et al. 1993;
Jendeberg et al. 1995).
56
Table 6. Overview of the kinetic study on the different Z domains carried out using the
Biacore.
Mutant ka kd KA ∆∆G ∆∆G[vs Z] [vs Z[F30A]]
[105 M-1 s-1] [10-3 s-1] [107 M-1] [kcal/mol] [kcal/mol]
Z 1.5 3.7 4.0 0Z(N23T) 2.7 3.9 7.0 -0.3
Z(F30A) 1.9 4.2 4.5 -0.1 0
Z(F30A,N6A) 7.0 21 3.3 0.1 0.2
Z(F30A,N11S) 1.6 4.9 3.2 0.1 0.2
Z(F30A,N21A) 1.0 3.8 2.6 0.3 0.3
Z(F30A,N23T) 2.1 3.8 5.6 -0.2 -0.1
Z(F30A,N28A) 3.1 9.9 3.2 0.1 0.2
Z(F30A,N43E) 1.3 5.1 2.6 0.3 0.3
Z(F30A 1.5 4.9 3.0 0.2 0.2
Z(F30A,N23T,N43E) 0.8 3.8 2.0 0.4 0.5
Z was used as an internal standard during the different measurements. The differences in
free binding energy were calculated relative to Z and Z(F30A) respectively.
The aim of the study was to investigate the effect of the various different single
mutations on the alkaline resistance of the Z domains. The results of the affinity
chromatography experiments using amine coupled monomeric domains are shown in
figure 16. The suppressor mutated ZF30A was still quite stable to alkaline conditions.
Even after 7.5 hours of exposure to 0.5 M NaOH, the column remained functional,
though with reduced capacity. The most important mutation was shown to be the
asparagine to threonin substitution in the loop between helices one and two, leading to
ZF30AN23T. This mutation increased the alkaline tolerance of Z(F30A) remarkably.
Also, the mutation was able to stabilize the native Z molecule when it was grafted
into the parental Z-domain. This agrees with earlier results showing that asparagines
located in unstructured regions are more susceptible to covalent modifications than
those located in structurally more inflexible regions (Kosky et al. 1999; paper IV).
57
Figure 16. Comparison of capacity after repeated CIP-treatment with a 0.5 M NaOH
cleaning agent, following an ordinary affinity chromatography scheme. The protocol was run
16 times and the duration for the alkaline exposure was 30 minutes in each round. The total
time of exposure to 0.5 M NaOH was 7.5 hours.
To investigate the structural stability of Z and different mutants thereof in alkaline
conditions, CD-spectra at two different pH, 7.6 and 13.7, were measured. The
parental Z possesses a remarkably high stability at high pH-values, almost appearing
unaffected. In addition, Z(F30A) shows lower secondary structure content in high pH
solution. The results imply that the N23T-mutation slightly stabilizes the secondary
structure of Z(F30A). Comparing the CD data for Z with the C2 scaffold, both
domains showed high thermal stability while CD measurements in GdnHCl solutions
indicated that the Z domain showed higher stability than C2 (Gülich et al. 2000). In
addition, the Z domain also showed high a-helicity at high pH, while CD
measurements on the C2 domain indicated no secondary structure at all in the same
conditions (data not shown).
0
10
20
30
40
50
60
70
80
90
100
0 100 200 300 400 5000 1 2 3 4 5 6 7 80
Capacity [%]
Time of Exposure
[h]
Z(F30A,N6A)
Z(F30A,N23T,N43E)
Z(F30A,N28T)
Z(F30A,N23T)
Z(F30A,N11S)Z(F30A,N11S,N23T)Z(F30A,N6A;N23T)Z(F30A)Z(F30A,N43T)Z(F30A,N52A)
Z(F30A,N21A)
58
Concluding remarksIn this thesis, attempts have been made to illustrate the benefits of using protein
engineering for biotechnological applications. Discussions have emphasized site-
directed mutagenesis for exploring protein-protein interactions, and improving the
performance of small protein receptor domains from bacteria.
A mutagenesis strategy was applied to investigate the binding surface of the HSA
binding domain originating from SPG. The residues contributing to the affinity where
found to be located mainly in the second helix. Additionally, electrostatic interactions
were found to be important for the association between ABD and HSA. This has also
been shown to be important for other protein-protein interactions (Clackson et al,
1998; Schreiber and Fersht 1996). The localization of the HSA-binding region at
ABD should provide new ways to enhance and improve ABD for different
applications; including the possibility to introduce new binding specificities into the
small domain, while still retaining the affinity for HSA.
In the stabilization projects, three different bacterial domains were analyzed, ABD
and the C2 domain originating from SPG and the Z domain originating from SPA. In
all cases, the most sensitive asparagines were found to be located in loops between a-
helices, or between a a-helix and a b-strand. This agrees with previous reports that
the fragility of asparagine towards modifications is dependent on different secondary
structure elements. In two cases, the stabilized variant of ABD, and C2 were
genetically fused to provide dimers to increase the column capacity during affinity
chromatography. The rational design strategies used to increase the tolerance to
alkaline pH levels, clearly show upon the benefit of understanding underlying reasons
for degradation. This strategy might also be applicable to increase the alkaline
tolerance of other proteins and expand the use of proteinaceous ligands in different
biotechnological applications.
59
Acknowledgements
I would like to thank all my former and current friends and colleagues at theDepartment of Biotechnology; not only for all their research-related input includingseminars, but also for the fantastic camaraderie we enjoyed, with “musik-kvällar”,social activities, conferences and science.
I wish to specially thank the following people:
Professor Mathias Uhlén, for accepting me as a PhD student, and for your inspirationover the years. Sophia Hober, my amazing supervisor. It has been a great pleasureworking with you. Per-Åker Nygren for valuable discussion regarding science and forproofreading of this thesis. My laboratory colleagues at EDEN - Maria and Nina. Myproject support in Kaspar and Anneli, for their well performed “exjobb”, without yourhelp I would definitely not have come this far. Thanks also to Karin, Elin and Anna atAffibody AB for valuable collaboration. To Dr Sussie Gülich for helping and guidingme through my “exjobb”.
I would also like to thank all of my friends outside the lab, especially Morgan, Petra,Kaj, Lisa, Jonas, Björn J, Björn H, Annica H, Staffan, Magnus and Annica O - for lotsof laughs.
Also the “K93 årgång” - Stoffe, Henrik, Anna B. and Stina - imagine 11 years havegone by just like that!
Thanks too to my family - Mum, Bengt, Dad, Sonja, both my brothers with families,Claes, Johan, Malin, Sunna and the juniors - Lina, Orm and Lova, for just being there.Also my “bonus” siblings with families- Petter, Anna, Eva and Mille. Good luckAnna and Mille!
My thanks here also to the “Forshaga family”- Gunno, Yvonne, Martin, Markus,Zandra and Sandra.
My beloved Caroline, for your love and encourage through the years.
My daughter Elvira, for remanding me it is a world outside the lab.
Tusen tack!
60
AbbreviationsABD albumin binding domainC2 protein G domainCD circular dichroismCH2 constant heavy chain 2CH3 constant heavy chain 3CIP cleaning in placeCm midpoint of denaturant induced transtitionC-terminal carboxy-terminalDa DaltonELISA enzyme linked immunosorbent assayEDTA ethylenediaminetetraacetic acidFab- fragment antigen bindingFc fragment crysttizableFRET Fluorescence resonance energy transferFv fragment variableGdnHCl guanidine hydrochlorideHSA human serum albuminIgG immunoglobulin Gka association rate constantkd dissociation rate constantKa affinity constantKd dissociations constantMab monoclonal antibodiesNHS N-hydroxysuccinimideNMR nuclear magnetic resonanceN-terminal amino- terminalPCR- polymerase chain reactionRU resonance unitSDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresisSPA staphylococcal protein ASPG streptococcal protein GTm midpoint of temperature-induced transitionZ engineered protein A domain
61
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