Convergent evolution among immunoglobulin G-binding bacterial proteins

Streptococcal protein H forms soluble complement-activating complexes with IgG, but inhibits complement activation by IgG-coated targets

Protein H, a surface protein of Streptococcus pyogenes interacting with the constant Fc region of IgG, is known to be released from the streptococcal surface by a cysteine proteinase produced by the bacteria. Poststreptococcal glomerulonephritis and rheumatic fever are conditions in which immune complexes and autoimmune mechanisms have been suggested to play pathogenetic roles. The present study demonstrates that addition of protein H to human serum produces complement activation with dose-dependent cleavage of C3. The activation was IgG-dependent and the result of complexes formed between IgG and protein H. These complexes were size heterogeneous with molecular masses of 400 kDa to 1.4 MDa. Using complement-depleted serum reconstituted with complement proteins, the activation by protein H was found to be dependent of the classical, but independent of the alternative pathway of complement. In contrast to results of experiments based on soluble protein H.IgG complexes, complement activation was inhibited by protein H when IgG was immobilized on a surface. The interaction between C1q and immunoglobulins represents the first step in the activation of the classical pathway, and protein H efficiently inhibited the binding of C1q to IgG immobilized on polyacrylamide beads. Protein H reduced C3 deposition on the IgG-coated beads and inhibited immune hemolysis of IgG-sensitized erythrocytes. Finally, significantly less C3 was deposited on the surface of protein H-expressing wild-type streptococci than on the surface of isogenic mutant bacteria devoid of protein H. The results demonstrate that protein H.IgG complexes released from the streptococcal surface can produce complement breakdown at the sites of infection, whereas complement activation on bacterial surfaces is inhibited. This should have important implications for host-parasite relationships. In addition, soluble protein H.IgG complexes might contribute to immunological complications of streptococcal infections.

Solution structure of the albumin-binding GA module: a versatile bacterial protein domain

The albumin-binding GA module is found in a family of surface proteins of different bacterial species. It comprises 45 amino acid residues and represents the first known example of contemporary module shuffling. Using 1H NMR spectroscopy we have determined the solution structure of the GA module from protein PAB, a protein of the anaerobic human commensal and pathogen Peptostreptococcus magnus. This structure, the first three-dimensional structure of an albumin-binding protein domain described, was shown to be composed of a left-handed three-helix-bundle. Sequence differences between GA modules with different affinities for albumin indicated that a conserved region in the C-terminal part of the second helix and the flexible sequence between helices 2 and 3 could contribute to the albumin-binding activity. The effect on backbone amide proton exchange rates upon binding to albumin support this assumption. The GA module has a fold that is strikingly similar to the immunoglobulin-binding domains of staphylococcal protein A but it shows no resemblance to the fold shared by the immunoglobulin-binding domains of streptococcal protein G and peptostreptococcal protein L. When the gene sequences, binding properties and thermal stability of these four domains are analysed in relation to their global folds an evolutionary pattern emerges. Thus, in the evolution of novel binding properties mutations are allowed only as long as the energetically favourable global fold is maintained.

Structure of a group C streptococcal protein that binds to fibrinogen, albumin and immunoglobulin G via overlapping modules

Pathogenic streptococci express surface proteins that bind to host serum proteins. A novel multiple-ligand-binding protein has now been identified in a species belonging to serotype C streptococci. This protein binds to fibrinogen, albumin and IgG and was therefore designated FAI protein. The structure of the fai gene has been determined, and deletion analysis and expression of FAI fusion polypeptides revealed that the binding domain for fibrinogen and IgG is located within the nonrepetitive N-terminal half of the protein. A 93-amino acid peptide retained the ability to bind both proteins, whereas a 56-amino acid subpeptide only bound fibrinogen. IgG-binding activity required the complete fibrinogen-binding domain and an additional 37 amino acids C-terminal to it, and albumin-binding activity was only obtained with a polypeptide reflecting the complete surface-exposed region of FAI protein indicating that the binding sites for each ligand were located on overlapping modules. Signal sequence, C repeat region and C-terminus revealed high homology to group A streptococcal M proteins whereas the N-terminal region containing the fibrinogen/IgG-binding domains is completely different and exhibits no similarity to any other previously characterized protein. Thus FAI protein exhibits a framework structure that might have evolved in group C streptococci via fusion of unrelated sequences, thereby generating an albumin-binding domain in the functional context of multiple-ligand-binding activity.

Equilibrium and pre-equilibrium fluorescence spectroscopic studies of the binding of a single-immunoglobulin-binding domain derived from protein G to the Fc fragment from human IgG1

A single-immunoglobulin-binding protein based upon the C2 domain of Protein G from Streptococcus has been shown to bind tightly to the Fc fragment of IgG1. The binding interaction results in a decrease in the fluorescence intensity from the sole Trp residue (Trp-48) in this domain. This spectral change has been used to monitor the binding interactions between the two proteins using equilibrium and pre-equilibrium fluorescence spectroscopy. Comparison of the data from the two techniques suggests that a conformational change occurs after the initial formation of the complex. Mutagenesis studies have shown that the Trp residue is important for binding and that replacement by a Phe residue is important for binding and that replacement by a Phe residue leads to a 300-fold decrease in the affinity for Fc gamma 1. Determination of the rate constants kon and koff at different values of pH between 4.0 and 9.0 suggest that variations in Kd are mediated predominantly by changes in kon. Competition experiments between SpG1 and a single-IgG-binding domain from Protein A from Staphylococcus aureus have been used to determine the affinity of the latter for Fc gamma 1.

Structures of bacterial immunoglobulin-binding domains and their complexes with immunoglobulins

Three-dimensional structures are now available for several immunoglobulin binding domains from bacterial proteins A, G, and L. X-ray diffraction and NMR experiments on complexes of these domains with portions of immunoglobulins have revealed common structural themes used in these interactions. These data expand our understanding of structure/function relationships in these molecular recognition processes and provide the basis for rational design of artificial immunoglobulin-binding molecules.

A protein G-related cell surface protein in Streptococcus zooepidemicus

This work describes the cloning and sequencing of a gene encoding a plasma protein receptor from Streptococcus zooepidemicus. This receptor, termed protein ZAG, is a 45-kDa protein that binds alpha 2-macroglobulin (alpha 2M), serum albumin, and immunoglobulin G (IgG). The IgG-binding activity is located in the C-terminal part of the molecule and is mediated by two repeated domains highly homologous to each other as well as to the corresponding domains in streptococcal type III Fc receptors. The IgG-binding profile of protein ZAG is similar to that previously reported for S. zooepidemicus. Binding to serum albumin is mediated by a short amino acid sequence in the middle of the molecule. This domain shows homology to previously described albumin-binding proteins from streptococci, and the albumin-binding profile of protein ZAG is similar to that of streptococcal protein G. The N-terminal part of protein ZAG, which mediates binding to the plasma proteinase inhibitor alpha 2M, is composed of a unique stretch of amino acids. Protein ZAG competes for the same, or nearby, binding site(s) in alpha 2M as do two recently described Streptococcus dysgalactiae receptors, although the sequences of the alpha 2M-binding domains in these three receptors show only minor sequence similarities.

Crystal structure of the C2 fragment of streptococcal protein G in complex with the Fc domain of human IgG

BACKGROUND

Streptococcal protein G comprises two or three domains that bind to the constant Fc region of most mammalian immunoglobulin Gs (IgGs). Protein G is functionally related to staphylococcal protein A, with which it shares neither sequence nor structural homology.

RESULTS

To understand the competitive binding of these two proteins to the Fc region, the crystal structure of a single Ig-binding domain of streptococcal protein G was determined at 3.5 A resolution in complex with the Fc fragment of human IgG and compared with the structures of protein A:Fc and protein G:Fab complexes. Protein G binds to the interface between the second and third heavy chain constant domains of Fc, which is roughly the same binding site used by protein A. Protein G comprises one alpha-helix packed onto a four-stranded beta-sheet. Residues from protein G that are involved in binding are situated within the C-terminal part of the alpha-helix, the N-terminal part of the third beta-strand and the loop region connecting these two structural elements. The identified Fc-binding region of protein G agrees well with both biochemical and NMR spectroscopic data. However, the Fc-binding helices of protein G and protein A are not superimposable.

CONCLUSIONS

Protein G and protein A have developed different strategies for binding to Fc. The protein G:Fc complex involves mainly charged and polar contacts, whereas protein A and Fc are held together through non-specific hydrophobic interactions and a few polar interactions. Several residues of Fc are involved in both the protein G:Fc and the protein A:Fc interaction, which explains the competitive binding of the two proteins. The apparent differences in their Fc-binding activities result from additional unique interactions.

Display of peptides and proteins on the surface of bacteriophage lambda

The display of peptides or proteins on the surface of viruses is an important technology for studying peptides or proteins and their interaction with other molecules. Here we describe a display vehicle based on bacteriophage lambda that incorporates a number of features distinct from other currently used display systems. Fusions of peptides or protein domains have been made to the amino terminus of the 11-kDa D protein of the lambda capsid. These fusions assemble onto the viral capsid and appear to be accessible to ligand interactions, based on the ability of a monoclonal antibody to recognize an epitope fused to the D protein on phage heads. To produce large D fusion display libraries and yet avoid the cumbersome task of cloning many fragments into lambda DNA, we have used the Cre-loxP site-specific recombination system in vivo to incorporate plasmids encoding the D fusions into the phage genome. Finally, we show that D fusion proteins can be added in vitro to phage lacking D protein and be assembled onto the viral capsid.

Model for the complex between protein G and an antibody Fc fragment in solution

BACKGROUND

Streptococcal protein G and staphylococcal protein A are bacterial antibody-binding proteins, widely used as immunological tools, whose antibody-binding domains are structurally quite different. The binding of protein G to Fc fragments is competitive with respect to protein A, suggesting that the binding sites for protein A and protein G on Fc overlap, notwithstanding the fact that they lack sequence or structural similarity.

RESULTS

To resolve this issue, the residues involved in the interaction between an IgG-binding domain of protein G (domain II) and the Fc fragment of mouse IgG2a have been identified by use of 13C and 15N NMR. Binding of protein G domain II selectively perturbed resonances from residues between the CH2 and CH3 domains of Fc, whereas in domain II the residues affected are primarily those on the alpha-helix and the third strand of the beta-sheet. This information was used, together with the structures of the two uncomplexed proteins, to construct a model of the complex, using Monte Carlo minimization techniques. In this model, the alpha-helix of protein G lies in the same position as helix 1 of protein A in the crystal structure of the protein A:Fc complex, but its orientation differs from the latter by 180 degrees.

CONCLUSIONS

The interactions of the bacterial antibody-binding proteins with their 'target' immunoglobulins involve a very versatile set of protein-protein interactions. First, the IgG-binding domains of protein A and protein G have quite different three-dimensional structures, but bind to sites on the Fc fragment that overlap extensively. Secondly, protein G employs two quite different regions of its surface to bind to the Fab and Fc regions of IgG.

Thermodynamic genetics of the folding of the B1 immunoglobulin-binding domain from streptococcal protein G

A method has been developed to select proteins that are thermodynamically destabilized yet still folded and functional. The DNA encoding the B1 IgG-binding domain from Group G Streptococcus (Strp G) has been fused to gene III of bacteriophage M13. The resulting fusion protein is displayed on the surface of the phage thus enabling the phage to bind to IgG molecules. In addition, these phage exhibit a small plaque phenotype that is reversed by mutations that destabilize the Strp G domain. By selecting phage with large plaque morphology that retain their IgG-binding function, it is possible to identify mutants that are folded but destabilized compared with wild-type Strp G. Such mutants can be divided into three general categories: 1) those that disrupt packing of hydrophobic side chains in the protein interior; 2) those that destabilize secondary structure; and 3) those that alter specific hydrogen bonds involving amino acid side chains. A number of the mutants have been physically characterized by circular dichroism and nuclear magnetic resonance and have been shown to have structures similar to wild-type Strp G but stabilities that were decreased by 2-5 kcal/mol.

Three-dimensional solution structure of an immunoglobulin light chain-binding domain of protein L. Comparison with the IgG-binding domains of protein G

Protein L is a multidomain protein expressed at the surface of some strains of the anaerobic bacterial species Peptostreptococcus magnus. It has affinity for immunoglobulin (Ig) through interaction with framework structures in the variable Ig light chain domain. The Ig-binding activity is located to five homologous repeats called B1-B5 in the N-terminal part of the protein. We have determined the three-dimensional solution structure of the 76 amino acid residue long B1 domain using NMR spectroscopy and distance geometry-restrained simulated annealing. The domain is composed of a 15 amino acid residue long disordered N-terminus followed by a folded portion comprising an alpha-helix packed against a four-stranded beta-sheet. These secondary structural elements are well determined with a backbone atomic root mean square deviation from their mean of 0.54 A. The B domains of protein L show very limited sequence homology to the domains of streptococcal protein G interacting with the heavy chains of IgG. However, despite this fact, and their different binding properties, the fold of the B1 domain was found to be similar to the fold of the IgG-binding protein G domains [Wikström, M., Sjöbring, U., Kastern, W., Björck, L., Drakenberg, T., & Forsén, S. (1993) Biochemistry 32, 3381-3386]. In the present study, the solution structure of the B1 domain enabled a more detailed comparison which can explain the different Ig-binding specificities of these two bacterial surface proteins. Among the differences observed, the alpha-helix orientation is the most striking.(ABSTRACT TRUNCATED AT 250 WORDS)

Context is a major determinant of beta-sheet propensity

Residues in beta-sheets occur in two distinct tertiary contexts: central strands, bordered on both sides by other beta-strands, and edge strands, bordered on only a single side by another beta-strand. The delta delta G values for beta-sheet formation measured at an edge beta-strand of the IgG-binding domain of protein G(GB1) are quite different from those obtained previously at a central position in the same protein. In particular, there is no correlation at the edge position with statistically determined beta-sheet-forming preferences. The differences between beta-sheet propensities measured at central and edge beta-strands, delta delta delta G values, correlate with the values of water/octanol transfer free energies and side-chain non-polar surface area for the amino acids. These results strongly suggest that, unlike alpha-helix formation, beta-sheet formation is determined in large part by tertiary context, even at solvent-accessible sites, and not by intrinsic secondary structure preferences.

M1 protein and protein H: IgGFc- and albumin-binding streptococcal surface proteins encoded by adjacent genes

M1 protein and Protein H are surface proteins simultaneously present at the surface of certain strains of Streptococcus pyogenes, important pathogenic bacteria in humans. The present study concerns the structure, protein-binding properties and relationship between these two molecules. The gene encoding M1 protein (emm1) was found immediately upstream of the Protein H gene (sph). Both genes were preceded by a promoter region. Comparison of the sequences revealed a high degree of similarity in the signal peptides, the C repeats located in the central parts of the molecules and in the C-terminal cell-wall-attached regions, whereas the N-terminal sequences showed no significant similarity. Protein H has affinity for the Fc region of IgG antibodies. Also M1 protein, isolated from streptococcal culture supernatants or from Escherichia coli expressing emm1, was found to bind human IgGFc. When tested against polyclonal IgG from eight other mammalian species, M1 protein and Protein H both showed affinity for baboon, rabbit and pig IgG. M1 protein also reacted with guinea-pig IgG, whereas both streptococcal proteins were negative in binding experiments with rat, mouse, bovine and horse IgG. The two proteins were also tested against other members of the immunoglobulin super family: human IgM, IgA, IgD, IgE, beta 2-microglobulin, and major histocompatibility complex (MHC) class-I and class-II antigens. M1 protein showed no affinity for any of these molecules whereas Protein H reacted with MHC class-II antigens. M1 protein is known to bind albumin and fibrinogen also. The binding sites for these two plasma proteins and for IgGFc were mapped to different sites on M1 protein. Thus albumin bound to the C repeats and IgGFc to a region (S) immediately N-terminal of the C repeats. Finally, fibrinogen bound further towards the N-terminus but close to the IgGFc-binding site. On the fibrinogen molecule, fragment D was found to mediate binding to M1 protein. The IgGFc-binding region of M1 protein showed no similarity to that of Protein H. Still, competitive binding experiments demonstrated that the two streptococcal proteins bound to overlapping sites on IgGFc.

The functional units of a peptostreptococcal protein L

Protein L is a cell-surface protein from Peptostreptococcus which interacts with immunoglobulin kappa light chains. A gene from Peptostreptococcus strain 3316 coding for protein L and fragments thereof were expressed in Escherichia coli. The peptides were examined for binding to immunoglobulin and serum albumin. The four C units were shown to be responsible for binding to immunoglobulin and the four D units for binding to albumin. This protein L molecule therefore binds to albumin at a site separate from that involved in binding to immunoglobulin. The albumin-binding units have high amino acid sequence identity with the albumin-binding units of streptococcal cell-surface proteins. The gene contains three sites available for internal initiation of translation resulting in three active proteins. The protein L molecule presented in this report was compared with a previously reported protein from Peptostreptococcus strain 312. The two proteins differ in several respects, including size and the number and types of repeat units.

Hydrogen-deuterium exchange in the free and immunoglobulin G-bound protein G B-domain

Hydrogen-deuterium exchange experiements have been used to measure backbone amide proton (NH) exchange rates in the free and IgG-bound protein G B2-domain (GB2). Exchange rates were analyzed in terms of the free energy required for transient opening of an H-bonded NH (delta Gop), and exchange mechanisms were interpreted in the context of local and global opening motions. In free GB2 at 22 degrees C, 28 detectable NHs have delta Gop values which approximate the free energy of thermal unfolding (delta Gu) obtained from calorimetry. This indicates that the majority of detectable NHs exchange through a global unfolding mechanism, reflecting the cooperative two-state unfolding behavior observed thermodynamically [Alexander et al. (1992) Biochemistry 31, 3597-3603]. IgG binding results in a broadening of exchange rates and delta Gop values, consistent with a less cooperative exchange mechanism than in free GB2. The large range of protection factors (1.3 to > 210) also indicates that exchange does not occur cooperatively for all detectable NHs in bound GB2. Nineteen of the detectable NHs have significantly slowed exchange rates in the complex with protection factors > 5. Residues with protection factors of the order of 100 or more occur in both the helix region (F30, K31, A34) and in the central core of the beta-sheet (V6, F52, V54). The highest protection factors are consistent with a binding constant of approximately 10(8) M-1. The pattern of high protection observed in the helix overlaps with the putative binding site suggested from previous studies.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of immunoglobulin A-binding sites within M or M-like proteins of group A streptococci

Many strains of group A streptococci are capable of binding human immunoglobulin A (IgA) by a nonimmune mechanism. M or M-like proteins constitute a family of structurally diverse molecules which form surface fibrillae, and some of the M or M-like protein forms are responsible for the IgA-binding activity. In this report, the binding site for IgA is localized within two structurally distinct M or M-like proteins, ML2.2 and Arp4. Apart from those structural domains which are common to all M and M-like proteins, ML2.2 and Arp4 lack significant levels of amino acid sequence homology, with the exception of a short segment (ALXGENXDLR) located at residues 21 to 30 of the mature ML2.2 protein. Recombinant fusion polypeptides containing portions of the ML2.2 and Arp4 proteins were expressed in Escherichia coli and tested for binding of human myeloma IgA. A 58-residue polypeptide containing residues 14 to 71 of ML2.2 bound human IgA. The IgA-binding site of Arp4 could be localized to a 53-residue polypeptide containing residues 43 to 95, which encompasses the ALXGENXDLR consensus sequence of Arp4 positioned at residues 50 to 59. Site-specific mutagenesis at three codons within the ALXGENXDLR coding sequence of both the ML2.2 and Arp4 recombinant polypeptides leads to a loss in IgA-binding activity. Thus, the ALXGENXDLR consensus sequence is essential for the nonimmune binding of IgA by both ML2.2 and Arp4. However, the failure to bind IgA by polypeptides which partially overlap the 58- and 53-residue IgA-binding polypeptides of ML2.2 and Arp4, yet contain the ALXGENXDLR consensus sequence, strongly suggests that flanking regions are also critical for IgA binding. In summary, the results indicate that common functional domains bearing significant sequence homology are distributed within regions of M or M-like molecules that are otherwise highly divergent.

Protein H--a surface protein of Streptococcus pyogenes with separate binding sites for IgG and albumin

Protein H, a molecule expressed at the surface of some strains of Streptococcus pyogenes, has affinity for the constant (IgGFc) region of immunoglobulin (Ig) G. In absorption experiments with human plasma, protein H-sepharose could absorb not only IgG but also albumin from plasma. The affinity constant for the reaction between albumin and protein H was 7.8 x 10(9) M-1, which is higher than the affinity between IgG and protein H (Ka = 1.6 x 10(9) M-1). Fragments of protein H were generated with deletion plasmids and polymerase chain reaction (PCR) technology. Using these fragments in various protein-protein interaction assays, the binding of albumin was mapped to three repeats (C1-C3) in the C-terminal half of protein H. On the albumin molecule, the binding site for protein H was found to overlap the site for protein G, another albumin- and IgGFc-binding bacterial surface protein. Also IgGFc-binding could be mapped with the protein H fragments and the region was found N-terminally of the C repeats. A synthetic peptide (25 amino acid residues long) based on a sequence in this region was shown to inhibit the binding of protein H to immobilized IgG or IgGFc. This sequence was not found in previously described IgGFc-binding proteins. However, two other cell surface proteins of S. pyogenes exhibited highly homologous regions. The results identify IgGFc- and albumin-binding regions of protein H and further define and emphasize the convergent evolution among bacterial surface proteins interacting with human plasma proteins.

Proton nuclear magnetic resonance sequential assignments and secondary structure of an immunoglobulin light chain-binding domain of protein L

The 1H NMR assignments have been made for the immunoglobulin (Ig) light chain-binding B1 domain of protein L from Peptostreptococcus magnus. The secondary structure elements and the global folding pattern were determined from nuclear Overhauser effects, backbone coupling constants, and slowly exchanging amide protons. The B1 domain was found to be folded into a globular unit of 61 amino acid residues, preceded by a 15 amino acid long disordered N-terminus. The folded portion of the molecule contains a four-stranded beta-sheet spanned by a central alpha-helix. The fold is similar to the IgG-binding domains of streptococcal protein G, despite the fact that the binding sites on immunoglobulins for the two proteins are different; protein G binds IgG through the constant (Fc) part of the heavy chain, whereas protein L has affinity for the variable domain of Ig light chains.