Streptococcal protein G. Gene structure and protein binding properties

Protein G was solubilized from 31 human group C and G streptococcal strains with the muralytic enzyme mutanolysin. As judged by the mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the binding patterns of the solubilized protein G molecules in Western blot experiments, the strains could be divided into three groups, represented by the group G streptococcal strains G148 and G43 and the group C streptococcal strain C40. The 65-kDa G148 protein G and the 58-kDa C40 protein G showed affinity for both immunoglobulin G (IgG) and human serum albumin (HSA), whereas the 40-kDa G43 protein G bound only IgG. Despite the different molecular patterns, the three protein G species had identical NH2-terminal amino acid sequences. Apart from the 65-kDa peptide, digestion of G148 streptococci with mutanolysin also produced a 52-kDa IgG- and HSA-binding peptide and a 14-kDa HSA-binding peptide. It was demonstrated that these peptides resulted from cleavage of 65-kDa protein G by proteolytic components in the mutanolysin preparation. The protein G genes of the C40 and G43 strains were cloned and sequenced, and their structure was compared to the previously published sequence of the G148 protein G gene. As compared to G148, both the C40 and G43 genes lacked a 210-base pair fragment in the IgG-binding region, accounting for the 10-fold lower affinity of these proteins for IgG. The G43 gene also lacked a 450-base pair fragment in the 5'-end of the gene, explaining why the G43 protein G did not bind HSA. The differences in protein G structure did not correlate with the clinical origin of the strains used in this study. The IgG-binding region of protein G was further mapped. Thus, a peptide corresponding to a single IgG-binding unit was obtained by the cloning and expression of a 303-base pair polymerase chain reaction-generated DNA fragment. The affinity of this 11.5-kDa peptide for human IgG was 8.0 x 10(7) M-1, as determined by Scatchard plots. Finally, a 55-amino acid-long synthetic peptide, corresponding to one of the three repeated domains in the COOH-terminal half of strain G148 protein G, effectively blocked binding of protein G to IgG.     

Purification and some properties of streptococcal protein G, a novel IgG-binding reagent

Protein G, a bacterial cell wall protein with affinity for immunoglobulin G (IgG), has been isolated from a human group G streptococcal strain (G148). Bacterial surface proteins were solubilized by enzymatic digestion with papain. Protein G was isolated by sequential use of ion-exchange chromatography on DEAE-cellulose, gel filtration on Sephadex G-100, and affinity chromatography on Sepharose 4B-coupled IgG. The presence of protein G in various pools and fractions during the isolation was followed by their ability to inhibit the binding of radio-labeled IgG to G148 bacteria. A highly purified protein G was obtained. On polyacrylamide gel electrophoresis in sodium dodecyl sulfate, the apparent m.w. was 30,000, and on agarose gel electrophoresis the purified protein gave rise to a single band in the alpha 1-region. Protein G was found to bind all human IgG subclasses and also rabbit, mouse, and goat IgG. On the IgG molecule, the Fc part appears mainly responsible for the interaction with protein G, although a low degree interaction was also recorded for Fab fragments. IgM, IgA, and IgD, however, showed no binding to protein G. This novel IgG-binding reagent promises to be of theoretical and practical interest in immunologic research.     

A physicochemical study of protein G, a molecule with unique immunoglobulin G-binding properties

Protein G, an IgG-binding molecule, was prepared from the cell walls of a group G streptococcal strain, G-148. The protein could be extracted from the cells by papain digestion and purified by the sequential use of ion-exchange chromatography on DEAE-Sephadex, affinity chromatography on Sepharose-coupled human IgG, and gel chromatography on Sephadex G-200. Two protein bands with similar molecular weight, 34,000 and 36,000, were obtained when analyzing the pure protein G on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The yield using this purification scheme was 27% of the protein G solubilized from the cells or 70 micrograms/ml packed bacteria. The Stokes radius and frictional ratio of protein G were determined to 3.53 nm and 1.64, respectively, suggesting an elongated fibrous molecule. The protein did not contain any intrachain disulfide bonds. The amino acid composition of protein G was determined and was found to be different from that of protein A, the well known staphylococcal IgG-binding protein. The equilibrium constants of the reactions between protein G and human, rabbit, mouse, and goat polyclonal IgG, determined by Scatchard plots, ranged between 1 X 10(10) and 7 X 10(10), for rat polyclonal IgG 1.4 X 10(9), and human monoclonal IgG1, IgG2, IgG3, and IgG4 between 2 X 10(9) and 6 X 10(9). These affinity constants were always greater than the corresponding values for protein A. The binding between protein G and various polyclonal and monoclonal IgG was pH dependent between 2.8 and 10, strongest at pH 4 and 5, and weakest at pH 10.     

Structure of the IgG-binding regions of streptococcal protein G.

The gene encoding the IgG-binding protein G from Streptococcus G148 was isolated by molecular cloning. A subclone containing a 1.5-kb insert gave a functional product in Escherichia coli. Protein analysis of affinity-purified polypeptides revealed two gene products, both smaller than protein G spontaneously released from streptococci, but with identical IgG-binding properties. The complete nucleotide sequence of the insert revealed a repeated structure probably evolved through duplications of fragments of different sizes. The deduced amino acid sequence revealed an open reading frame extending throughout the insert, terminating in a TAA stop codon. Analysis of the two gene products by N-terminal amino acid determination suggests that two different TTG codons are recognized in E. coli for initiation of translation to yield the two products. Based on these results several truncated gene constructions were expressed and analysed. The results suggest that the C-terminal part of streptococcal protein G consists of three IgG-binding domains followed by a region which anchors the protein to the cell surface. Structural and functional comparisons with streptococcal M protein and staphylococcal protein A have been made.     

Expression and characterization of a tripartite fusion protein consisting of chimeric IgG-binding receptors and beta-galactosidase.

Using protein engineering, a tripartite fusion protein was constructed consisting of five IgG-binding regions of protein A from Staphylococcus aureus, two IgG-binding regions of protein G from Streptococcus strain G148 and beta-galactosidase from Escherichia coli. The resulting protein lacks the serum albumin binding regions of native protein G. The fusion protein, which is a tetramer of approximately 660 kDa, was designed as a tool for immunological assays taking advantage of its broad spectrum of antibody affinity. The gene was placed under control of two promoters, the PR promoter and the lac UV5 promoter and the expression from the two promoters was studied in a bioreactor. Induction of the PR promoter gave an intracellular product concentration corresponding to 20% of the cell dry weight. By utilizing the properties of beta-galactosidase, the protein was purified by extraction in an aqueous two-phase system. The fusion protein was not proteolytically degraded during the cultivation and purification steps. The biological activity of all three parts of the protein was demonstrated with a competitive ELISA.     

Analysis of Bacterial Immunoglobulin-Binding Proteins by X-Ray Crystallography

Protein crystallography offers a powerful means of analyzing the molecular mechanisms that underlie the action of bacterial immunoglobulin-binding proteins. Successful approaches used to date involve the isolation of individual IgG-binding domains from the immunoglobulin-binding protein under study and the crystallization of these on their own or in complex with Fc or Fab fragments. Two structures of complexes that have been determined to high resolution by protein crystallography are compared. A single IgG-binding domain from protein A (from Staphylococcus) binds to a human Fc fragment through formation of two α-helices, which bind in the cleft between the CH2 and the CH3 domains. Recognition is mediated by side chains on protein A which interact with conserved side chains on the surface of the antibody, ensuring binding to IgG molecules from different subclasses and species. A similar analysis of the complex of a single IgG-binding domain from protein G (from Streptococcus) with an Fab fragment from mouse IgG1 reveals that the same problem in molecular recognition is tackled in a different way. Protein G binds via an antiparallel alignment of β-strands from the IgG-binding domain and the CH1 domain in Fab: this main chain-main chain interaction is supported by a number of specific hydrogen bonds between the side chains in both proteins. By recognition of a high proportion of main-chain atoms, protein G minimizes the effects of IgG sequence variability in a way that is distinct from that adopted by protein A.     

Relative quantitative comparisons of the extracellular protein profiles of Staphylococcus aureus UAMS-1 and its sarA, agr, and sarA agr regulatory mutants using one-dimensional polyacrylamide gel electrophoresis and nanocapillary liquid chromatography coupled with tandem mass spectrometry

One-dimensional polyacrylamide gel electrophoresis followed by nanocapillary liquid chromatography coupled with mass spectrometry was used to analyze proteins isolated from Staphylococcus aureus UAMS-1 after 3, 6, 12, and 24 h of in vitro growth. Protein abundance was determined using a quantitative value termed normalized peptide number, and overall, proteins known to be associated with the cell wall were more abundant early on in growth, while proteins known to be secreted into the surrounding milieu were more abundant late in growth. In addition, proteins from spent media and cell lysates of strain UAMS-1 and its isogenic sarA, agr, and sarA agr regulatory mutant strains during exponential growth were identified, and their relative abundances were compared. Extracellular proteins known to be regulated by the global regulators sarA and agr displayed protein levels in accordance with what is known regarding the effects of these regulators. For example, cysteine protease (SspB), endopeptidase (SspA), staphopain (ScpA), and aureolysin (Aur) were higher in abundance in the sarA and sarA agr mutants than in strain UAMS-1. The immunoglobulin G (IgG)-binding protein (Sbi), immunodominant staphylococcal antigen A (IsaA), IgG-binding protein A (Spa), and the heme-iron-binding protein (IsdA) were most abundant in the agr mutant background. Proteins whose abundance was decreased in the sarA mutant included fibrinogen-binding protein (Fib [Efb]), IsaA, lipase 1 and 2, and two proteins identified as putative leukocidin F and S subunits of the two-component leukotoxin family. Collectively, this approach identified 1,263 proteins (matches of two peptides or more) and provided a convenient and reliable way of identifying proteins and comparing their relative abundances.     

Comparative characteristics of protein G gene in Streptococci of groups C and G isolated from humans

The treatment of streptococci, groups C and G, with bromocyanogen made it possible to isolate surface G protein, capable of binding human serum albumin (HSA) and polyclonal IgG. In this work the presence of G protein in all staphylococcal strains, groups C and G, is shown. The differences between the strains by the level of expression, molecular weight and functional activity of G protein, extracted from streptococci of groups C and G, permitted the identification of 3 groups of strains, containing the molecules of G protein with different numbers of IgG- and HSA-binding domains: with 3 IgG- and HSA-binding domains, with 2 IgG- and HSA-binding domains and with only 2 IgG-binding domains. Each strain under study expressed only one of the molecule of G protein. The work shows the possibility of the identification of streptococci, groups C and G, by the molecular characteristics of G proteins themselves and their respective coding genes.     

Sequential 1H NMR assignments and secondary structure of an IgG-binding domain from protein G

Protein G is a member of a class of cell surface bacterial proteins from Streptococcus that bind IgG with high affinity. A fragment of molecular mass 6988, which retains IgG-binding activity, has been generated by proteolytic digestion and analyzed by 1H NMR. Two-dimensional DQF-COSY, TOCSY, and NOESY spectra have been employed to assign the 1H NMR spectrum of the peptide. Elements of regular secondary structure have been identified by using nuclear Overhauser enhancement, coupling constant, and amide proton exchange data. The secondary structure consists of a central alpha-helix (Ala28-Val44), flanked by two portions of beta-sheet (Val5-Val26 and Asp45-Lys62). This is a fundamentally different arrangement of secondary structure from that of protein A, which is made up of three consecutive alpha-helices in free solution (Torigoe et al., 1990). We conclude that the molecular mechanisms underlying the association of protein A and protein G with IgG are different.     

Chimeric IgG-binding receptors engineered from staphylococcal protein A and streptococcal protein G

Chimeric Fc receptors, consisting of the IgG-binding domains of both staphylococcal protein A and streptococcal protein G, were constructed. An efficient bacterial expression system was used to produce the recombinant proteins, which vary in size and number of IgG-binding domains. The purified receptors were analyzed by immunodiffusion and a competitive enzyme-linked immunosorbent assay to establish the relative binding strength to various polyclonal and monoclonal immunoglobulins from different species. The results demonstrate that protein A and protein G have complementary binding patterns and that the chimeric receptors retain the binding capacities of both the parental constituents. This suggests that these novel chimeric receptors might be versatile reagents for immunochemical assays.     

Structure and evolution of the repetitive gene encoding streptococcal protein G

The complete sequence of the structural gene encoding the immunoglobulin G binding protein from Streptococcus G148 has been determined, as well as its 5' and 3' flanking sequences. The sequence reveals an open reading frame encoding a putative preprotein with a relative molecular mass of 63294. N-Terminal sequencing of the mature protein, spontaneously released from streptococcal cells, demonstrates that the signal peptide consists of 33 amino acids. The DNA sequence reveals extensive internal homologies similar to other cell-wall-bound receptors from gram-positive bacteria. Comparisons with a related gene previously isolated from another strain of streptococci revealed large differences in size, due to variations in the number of internal repeats. The structure of the gene suggests an evolution through multiple duplications.     

Evidence for functional heterogeneity in IgG Fc-binding proteins associated with group A streptococci

A number of group A streptococcal isolates have been compared for their nonimmune reactivity with each human IgG subclass, and rabbit, pig, or horse IgG. The results obtained demonstrate considerable heterogeneity in the expression of type II IgG-binding proteins among and within group A isolates. Extraction and analysis of type II IgG-binding proteins from selected strains demonstrate the existence of five functionally distinct IgG-binding proteins. The type IIo IgG binding protein displayed the greatest range of reactivities, binding to all four human IgG subclasses, and rabbit, pig, and horse IgG. A variant of this protein, designated type II'o, bound all four human subclasses and rabbit IgG, but failed to react with pig or horse IgG. A type IIa protein was recovered from certain group A strains which bound human IgG1, IgG2, IgG4, as well as reacting with rabbit, pig, and horse IgG. A functionally related type IIc activity that displayed all of the reactivities of the type IIa protein but did not bind with human IgG2 was also identified. The final functional form of group A IgG-binding protein, the type IIb protein, bound exclusively to human IgG3. Comparison of these functionally different type II IgG-binding proteins demonstrated no simple structure-function relationship. These studies underscore the heterogeneity of type II Ig-binding proteins expressed by different group A streptococci and document that a single strain can change its pattern of expression of type II IgG-binding protein both quantitatively and qualitatively.     

A structurally novel staphylococcal protein A from the V8 strain

Protein A from the Staphylococcus aureus strain V8 has a molecular mass about 8000 Da less than that of known proteins A. The corresponding gene was cloned and expressed in Escherichia coli. Sequence analysis of this structurally new protein A revealed that it lacked an IgG-binding domain (58 amino acids), and that it also lacked two octapeptide repetitions located in the membrane/wall attaching region. Contrary to what had been proposed previously, the first translated amino acid is probably not a leucine, but very likely a methionine located 12 residues upstream.     

Purification and characterization of a 52-kilodalton immunoglobulin G-binding protein from Streptococcus suis capsular type 2.

We previously reported that group D streptococci exhibited immunoglobulin G (IgG)-binding activity and that a 52-kDa IgG-binding protein was present in all Streptococcus suis strains examined (B. Serhir, R. Higgins, B. Foiry, and M. Jacques, J. Gen. Microbiol. 139:2953-2958, 1993). The objective of the present study was to purify and characterize this protein. Pig IgG were immobilized through their Fab fragments to ECH-Sepharose 4B, and the protein was purified by affinity chromatography. Electron microscopy observations of the purified material showed filamentous structures with a diameter of approximately 4 nm; these structures were not observed when the material was treated with either urea or ethanolamine. Electrophoretic and Western immunoblot analyses showed that the 52-kDa protein constituted the bulk of the recovered material. This protein was stained with either Coomassie brilliant blue or silver nitrate; it reacted with a large variety of mammalian IgG, human IgG (Fc) fragments, human IgA, and other human plasma proteins. The 52-kDa protein exhibited lower IgG-binding affinities than protein A and protein G. However, it was able to compete with protein A and protein G for binding to human IgG. In addition, it bound chicken IgG with high affinity. This last property differentiated the 52-kDa protein of S. suis from the six IgG-binding proteins described to date. The 52-kDa protein displayed similar affinities for untreated and deglycosylated pig IgG. The N-terminal amino acid sequence (SIITDVYAXEVLDSXGNPTLEV) revealed no homology with any bacterial proteins in the Swiss-Prot database. Its isoelectric point of approximately 4.6 and its amino acid composition, rich in aspartic and glutamic acids, showed that it had some similarities with other IgG-binding proteins. In this report, we have purified and characterized a 52-kDa IgG-binding protein from S. suis capsular type 2. Although this protein shares some similarities with other IgG- and/or IgA-binding proteins, it is unique in reacting with chicken IgG.     

Isolation of a protein from the parasporal crystal of Bacillus thuringiensis var,kurstaki toxic to the mosquito larva,Aedes taeniorhynchus

The parasporal crystal produced by a strain of Bacillus thuringiensis var. kurstaki (HD-1) contains two serologically distinct proteins. These proteins were isolated from a preparation of the parasporal crystal by Sephacryl S-300 column chromatography. Their molecular weights were estimated as 135,000 and 65,000. Both proteins were toxic to the cabbage looper, Trichoplusia ni, but only the 65,000-dalton protein was toxic to larvae of the mosquito, Aedes taeniorhynchus. Biochemical comparisons based on isoelectric focusing and peptide mapping by two-dimensional gel electrophoresis indicated that the two toxins were distinctly different.     

A study of the interactions between an IgG-binding domain based on the B domain of staphylococcal protein a and rabbit IgG

The nonantigenic interaction between a recombinant immunoglobulin G (IgG)-binding protein based on the B domain of Protein A fromStaphylococcus aureus (termed SpA¹) and the Fc fragment of rabbit IgG has been investigated. The contribution to binding of four putative hydrogen bond contacts between SpA¹ and IgG-Fc were examined by the individual substitution of the residues in SpA¹ involved in these interactions by others unable to form hydrogen bonds. It was found that the most important of the hydrogen bonds involved Tyr 18 which, when replaced by Phe, resulted in a twofold decrease in IgG-binding affinity. The residues of SpA¹ proposed to make close, mainly hydrophobic, contacts with Fc were replaced by residues with potential electrostatic charge to establish the importance of the hydrophobic interaction in the complex. The IgG-binding affinities of the mutant proteins were compared to the wild-type protein by a competitive enzyme-linked immunosorbant assay. The replacement of individual hydrophobic residues by His generated a number of novel IgG-binding proteins with reduced binding affinity at pH 5.0 but which maintained strong binding affinities at pH 8.0. The elution profile of human IgG₁-Fc (Fc fragment of human IgG₁) from a column made from an immobilized two-domain mutant protein shows that the complex dissociates at a higher pH relative to that of the non-mutated protein thus offering favorable elution characteristics.     

Immunodominant semen proteins I: New patterns of sperm proteins related to female immune infertility

Infertility affects approximately 10% of couples at reproductive age. Semen constituents may be potential immunogenic structures for women. The aim of our work is to detect and identify sperm proteins interacting with serum IgG antibodies from women with fertility disorders. The biochemical characterization of sperm antigens was performed using one and two dimensional gel electrophoresis, both of which were followed by immunoblotting. The IgG-binding proteins of interest were identified using mass spectrometry. From the serum pool of 30 infertile women, we detected sperm antigens within a relative molecular mass range between 30–80 kDa with an isoelectric point of 4–7. No antigens were detected using the serum pool from 10 fertile women (control group). Heat shock proteins (HSP 70) were identified as major sperm antigens associated with female immune infertility. Additionally, we report for the first time that alpha-enolase is a significant sperm antigen from the serum pool of infertile women. We suggest that the IgG-binding proteins identified in our study are related to immune infertility in the case of certain women with abnormally high levels of IgG antibodies linked to sperm proteins. Our results might be useful in the diagnoses of female immune infertility and may provide potential targets for further therapeutic treatment.     

Hyperproduction of a bifunctional hybrid protein, metapyrocatechase-protein A, by gene fusion.

A hybrid protein between metapyrocatechase and Staphylococcal protein A was produced by recombinant DNA techniques. A plasmid carrying the fusion gene that encodes the hybrid protein was constructed and expressed in E. coli. Over 70% of soluble proteins of the cell extracts was estimated to be the hybrid protein. This fusion protein is about 65,000. Both the IgG-binding activity of protein A and the metapyrocatechase activity were found in the hybrid protein. The optimum pH of metapyrocatechase in the fusion protein was at around 6.5 and Km was 1.3 X 10(-5) M. A simple immuno-enzymometric assay was developed for anti-BSA antibody using the fusion protein.     

Occurrence of Coagulase Serotype among Staphylococcus aureus Strains Isolated from Healthy Individuals —Special Reference to Correlation with Size of Protein-A Gene—

One-hundred-and-nineteen strains of Staphylococcus aureus isolated from healthy individuals for 3 years between 1991 and 1993 were subjected to an investigation on the producibility of proteins including protein A, coagulase, enterotoxins and toxic-shock syndrome toxin-1. Especially, protein A was the center of our interest. Among these strains, 69, 43, 3 and 1 strains were found to have the protein-A gene containing 5, 4, 3 and 2 IgG-binding domains, respectively. On the other hand, only one strain was devoid of the protein-A gene. There were some differences in the profile of the coagulase serotype between the group with 4 IgG-binding domains and that with 5 IgG-binding domains. Differences in the profile of toxin production were also observed between the two groups.     

Different mRNAs induced by interferon in cells from inbred mouse strains A/J and A2G

Treatment of cells from inbred mouse strains A/J and A2G with interferon resulted in the development of different antiviral states for influenza viruses. A2G mice-derived cells that carry the resistance gene Mx were efficiently protected by interferon against influenza viruses, whereas the interferon protection against the same viruses in wild-type A/J mice-derived cells was only marginal. The two cell types, however, were equally protected by interferon against vesicular stomatitis virus and other non-orthomyxoviruses. The interferon-induced mRNAs of mouse embryonic fibroblast cells that carried either homozygous wild-type alleles or homozygous Mx alleles were compared. The isolated polysome-bound mRNAs from A/J (+/+) and A2G (Mx/Mx) cells were translated in a cell-free translation system, and the translation products were analyzed after two-dimensional gel electrophoresis. New mRNAs coding for at least eight proteins with molecular weights (MW) ranging from 30,000 to 80,000 were found in interferon-treated cells but not in control cells. Differences in the interferon-induced mRNAs from A/J and A2G cells were also found. An mRNA coding for a 72,000-MW protein was found in interferon-treated A2G cells but not in interferon-treated A/J cells. Interferon-treated A/J cells, on the other hand, contained an mRNA coding for a 65,000-MW protein that was not found in interferon-treated A2G cells. The in vitro-synthesized 65,000-MW protein efficiently bound to GMP. Cytoplasmic extracts prepared from interferon-treated A/J cells also contained a GMP-binding 65,000-MW protein that was undetectable in similarly treated A2G cells.