Immunochemical analysis of intact M protein secreted from cell wall-less streptococci

Genomic sequence of C1, the first streptococcal phage

C(1), a lytic bacteriophage infecting group C streptococci, is one of the earliest-isolated phages, and the method of bacterial classification known as phage typing was defined by using this bacteriophage. We present for the first time a detailed analysis of this phage by use of electron microscopy, protein profiling, and complete nucleotide sequencing. This virus belongs to the Podoviridae family of phages, all of which are characterized by short, noncontractile tails. The C(1) genome consists of a linear double-stranded DNA molecule of 16,687 nucleotides with 143-bp inverted terminal repeats. We have assigned functions to 9 of 20 putative open reading frames based on experimental substantiation or bioinformatic analysis. Their products include DNA polymerase, holin, lysin, major capsid, head-tail connector, neck appendage, and major tail proteins. Additionally, we found one intron belonging to the HNH endonuclease family interrupting the apparent lysin gene, suggesting a potential splicing event yielding a functional lytic enzyme. Examination of the C(1) DNA polymerase suggests that this phage utilizes a protein-primed mechanism of replication, which is prominent in the phi29-like members of Podoviridae. Consistent with this evidence, we experimentally determined that terminal proteins are covalently attached to both 5' termini, despite the fact that no homology to known terminal proteins could be elucidated in any of our open reading frames. Likewise, comparative genomics revealed no close evolutionary matches, suggesting that the C(1) bacteriophage is a unique member of the Podoviridae.

Anchor structure of staphylococcal surface proteins. IV. Inhibitors of the cell wall sorting reaction

Surface proteins of Staphylococcus aureus are covalently linked to the bacterial cell wall by a mechanism requiring a COOH-terminal sorting signal with a conserved LPXTG motif. Cleavage between the threonine and the glycine of the LPXTG motif liberates the carboxyl of threonine to form an amide bond with the amino of the pentaglycine cross-bridge in the staphylococcal peptidoglycan. We asked whether antibiotic cell wall synthesis inhibitors interfere with the anchoring of surface proteins. Penicillin G, a transpeptidation inhibitor, had no effect on surface protein anchoring, whereas vancomycin and moenomycin, inhibitors of cell wall polymerization into peptidoglycan strands, slowed the sorting reaction. Cleavage of surface protein precursors did not require a mature assembled cell wall and was observed in staphylococcal protoplasts. A search for chemical inhibitors of the sorting reaction identified methanethiosulfonates and p-hydroxymercuribenzoic acid. Thus, sortase, the enzyme proposed to cleave surface proteins at the LPXTG motif, appears to be a sulfhydryl-containing enzyme that utilizes peptidoglycan precursors but not an assembled cell wall as a substrate for the anchoring of surface protein.

Surface proteins of gram-positive bacteria and mechanisms of their targeting to the cell wall envelope

The cell wall envelope of gram-positive bacteria is a macromolecular, exoskeletal organelle that is assembled and turned over at designated sites. The cell wall also functions as a surface organelle that allows gram-positive pathogens to interact with their environment, in particular the tissues of the infected host. All of these functions require that surface proteins and enzymes be properly targeted to the cell wall envelope. Two basic mechanisms, cell wall sorting and targeting, have been identified. Cell well sorting is the covalent attachment of surface proteins to the peptidoglycan via a C-terminal sorting signal that contains a consensus LPXTG sequence. More than 100 proteins that possess cell wall-sorting signals, including the M proteins of Streptococcus pyogenes, protein A of Staphylococcus aureus, and several internalins of Listeria monocytogenes, have been identified. Cell wall targeting involves the noncovalent attachment of proteins to the cell surface via specialized binding domains. Several of these wall-binding domains appear to interact with secondary wall polymers that are associated with the peptidoglycan, for example teichoic acids and polysaccharides. Proteins that are targeted to the cell surface include muralytic enzymes such as autolysins, lysostaphin, and phage lytic enzymes. Other examples for targeted proteins are the surface S-layer proteins of bacilli and clostridia, as well as virulence factors required for the pathogenesis of L. monocytogenes (internalin B) and Streptococcus pneumoniae (PspA) infections. In this review we describe the mechanisms for both sorting and targeting of proteins to the envelope of gram-positive bacteria and review the functions of known surface proteins.

Mechanism of stimulation of T cells by Streptococcus pyogenes: isolation of a major mitogenic factor, cytoplasmic membrane-associated protein

Our previous studies established that heat-killed Streptococcus pyogenes, as well as other gram-positive cocci, when incubated with human peripheral blood leukocytes (PBLs) in culture, induced polyclonal activation of T lymphocytes. The activated T lymphocytes included CD4+ CD8- helper T cells and CD3+ and CD4- CD8- double-negative T cells with gamma delta T-cell receptors. In the present study, we isolated a major factor with this unique mitogenic activity against human T lymphocytes from S. pyogenes. This active fraction was found in the cytoplasmic membrane (CM) of the heat-killed organisms but not in other cellular fractions such as cell walls, peptidoglycan, lipoteichoic acids, or cytoplasmic soluble fractions. An active molecule(s) was further isolated from the CM by cholic acid extraction followed by Sephacryl S-200 chromatography. The molecule was protease labile but highly resistant to heat, had a pI of greater than or equal to 9.3 and a molecular weight of 10,000 to 15,000 according to gel filtration experiments, and was termed CM-associated protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the protein purified by anion-exchange chromatography showed a single band with a molecular weight of 15,000, corresponding to mitogenically active regions. Purified CM-associated protein induced activation of T lymphocytes, which consisted of CD4+ CD8- T cells and CD4- CD8- double-negative T-cell receptor gamma/delta + T-cell populations, as did the whole cells of S. pyogenes.

Platelet-interactive products of Streptococcus sanguis protoplasts

To isolate a more native, platelet-interactive macromolecule (class II antigen) of Streptococcus sanguis, cultured protoplasts were used as a source. Protoplasts were optimally prepared from fresh washed cells by digestion with 80 U of mutanolysin per ml for 75 min at 37 degrees C while osmotically stabilized in 26% (wt/vol) raffinose. Osmotically stabilized forms were surrounded by a 9-nm bilaminar membrane, as shown by transmission electron microscopy. Protoplasts were cultured in chemically defined synthetic medium and osmotically stabilized by ammonium chloride. Spent culture media were harvested daily for 7 days. Each day, soluble proteins were isolated from media, preincubated with platelet-rich plasma, and tested for inhibition of platelet aggregation induced by S. sanguis cells. Products released from S. sanguis protoplasts and reactive with an anti-class II antigen immunoaffinity matrix were able to inhibit S. sanguis-induced platelet aggregation. As resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, anti-class II-reactive protoplast products included silver-stained bands of 67, 79, 115, 216, and 248 kDa. The 115-kDa protein fraction was isolated by gel filtration and ion-exchange chromatography. This form of the class II antigen contained N-formylmethionine at its amino terminus. Rhamnose constituted 18.2% of the total residual dry weight and nearly half of its carbohydrate content. Diester phosphorus constituted 1% of this fraction. After trypsinization of the protoplast products from either preparation, a 65-kDa protein fragment was recovered. This protoplast protein fragment and the S. sanguis cell-derived 65-kDa class II antigen, previously implicated in the induction of platelet aggregation, were shown to be functionally and immunologically identical.

Coregulation of type 12 M protein and streptococcal C5a peptidase genes in group A streptococci: evidence for a virulence regulon controlled by the virR locus

Group A streptococci express at least two surface-associated virulence factors, the antiphagocytic M protein and the antichemotactic streptococcal C5a peptidase (SCP). Preliminary evidence suggested that the biosynthesis of these two proteins is coordinately controlled and subject to simultaneous phase variation. To explore this possibility further, a series of phase-switching and phase-locked M- variants were assayed for SCP by enzyme-linked immunosorbent assay inhibition and for SCP-specific mRNA by dot blot hybridization. All M- cultures produced diminished amounts of SCP antigen and specific mRNA, whereas revertants produced quantities equivalent to those of the wild-type M+ culture. A phase-locked strain that harbors a deletion in a region upstream of the M12 and SCP genes, termed the virR locus, failed to produce SCP antigen or SCP-specific transcripts. The SCP-specific transcript produced by M+ bacteria was shown by Northern (RNA) blot hybridization to be 4 kilobases in size, distinguishing it from the transcript which encodes M protein. These data demonstrate that phase switching of both SCP and M12 proteins is at the transcriptional level and that expression is under the control of the upstream virR locus. We propose that the genetic determinants of these proteins and of colony morphology comprise a virulence regulon.

Identification of an endogenous membrane anchor-cleaving enzyme for group A streptococcal M protein. Its implication for the attachment of surface proteins in gram-positive bacteria

How streptococcal M protein or other surface proteins of gram-positive bacteria are anchored to the cell is poorly understood. Previously, we reported that M protein released after cell wall removal with a muralytic enzyme lacked the COOH terminal hydrophobic amino acids and charged tail predicted from DNA sequence. An endogenous membrane anchor-cleaving enzyme has now been identified with the ability to release M protein from isolated streptococcal protoplasts. At pH 5.5 in the presence of 30% raffinose, the streptococcal cell wall may be removed with a muralytic enzyme without releasing M protein from the resulting protoplasts indicating that the M molecule is attached through the bacterial cytoplasmic membrane. Release of M molecules occurs when the M protein-charged protoplasts are placed in raffinose buffer at pH 7.4. Although Zn2+, Cd2+, Ca2+, PHMB, and pHMPS inhibit the activity of the releasing enzyme, the blocking activity of Zn2+, Cd2+, and Ca2+ are reversible while PHMB and pHMPS are irreversible. PHMB-treated protoplasts are unable to release M protein at pH 7.4. However, M protein is liberated from these protoplasts when mixed with those prepared from M- streptococci serving as an enzyme source. The supernatant from M- protoplasts is unable to release M protein from PHMB-inactivated M+ protoplasts, confirming that the anchor-cleaving enzyme is membrane bound. Thus, the M protein releasing activity appears to be the result of a thiol-dependent anchor-cleaving enzyme. Streptococcal membranes treated with sodium carbonate and Triton X-114 still retain the M protein verifying that it is an integral membrane molecule. Evidence also is presented indicating significant sequence similarity between M protein and certain GPI-anchored proteins in the region responsible for protein anchoring.

Streptococcal M protein: molecular design and biological behavior

M protein is a major virulence determinant for the group A streptococcus by virtue of its ability to allow the organism to resist phagocytosis. Common in eucaryotes, the fibrillar coiled-coil design for the M molecule may prove to be a common motif for surface proteins in gram-positive organisms. This type of structure offers the organism several distinct advantages, ranging from antigenic variation to multiple functional domains. The close resemblance of this molecular design to that of certain mammalian proteins could help explain on a molecular level the formation of epitopes responsible for serological cross-reactions between microbial and mammalian proteins. Many of the approaches described in the elucidation of the M-protein structure may be applied for characterizing similar molecules in other microbial systems.

Streptococcus pyogenes type 12 M protein gene regulation by upstream sequences

A partial nucleotide sequence that included 1,693 base pairs of the M12 (emm12) gene of group A streptococci (strain CS24) and adjacent upstream DNA was determined. Type 12 M protein-specific mRNA of strain CS24 is transcribed from two promoters (P1 and P3) separated by 30 bases. The transcription start sites of the emm12 gene were located more than 400 bases downstream of a deletion that causes decreased M-protein gene transcription in strain CS64. Deletion analysis of M protein-expressing plasmids indicated that an upstream region greater than 1 kilobase is required for M-protein gene expression. The M-protein gene transcriptional unit appears to be monocistronic. Analysis of the emm12 DNA sequence revealed three major repeat regions. Two copies of each repeat, A and B, existed within the variable 5' end of the gene; repeat C demarcated the 5' end of the constant region shared by emm12 and emm6.

Molecular analysis of the M protein of Streptococcus equi and cloning and expression of the M protein gene in Escherichia coli

A Streptococcus equi gene bank was constructed in the bacteriophage lambda gt11 cloning vector, and hybrid phage plaques were screened with S. equi M protein antiserum. A hybrid phage expressing the S. equi M protein (lambda gt11/SEM7) was identified and lysogenized into Escherichia coli Y1089. The cloned M protein appeared in immunoblots as three polypeptides with relative molecular weights of 58,000, 53,000, and 50,000. When reacted with S. equi M protein antiserum in an agar double-diffusion assay, the cloned M protein formed a line of identity with a protein in an acid extract of S. equi. Furthermore, lambda gt11/SEM7 protein inhibited opsonization of S. equi by antiserum to S. equi M protein. In addition, the recombinant protein expressed determinants of the antigen in the immune complexes of purpura hemorrhagica. Native M protein obtained from S. equi and recombinant M protein showed very similar molecular weight distributions on immunoblots, appearing as multiple closely spaced bands with molecular weights ranging from 52,000 to 60,000. Antisera prepared separately against each of the acid-extracted polypeptides shown to be important in serum bactericidal responses (molecular weight, 29,000) and nasopharyngeal local antibody responses (molecular weights, 41,000 and 46,000) of the horse each reacted with all three polypeptides in an acid extract. Moreover, antisera against protoplasts and against recombinant M protein of S. equi also reacted with these polypeptides. These results suggest that the entire M protein molecule of S. equi is present in these preparations and that the fragments in acid extracts carry overlapping segments.

Size variation of the M protein in group A streptococci

In addition to the type-specific antigenic variation that is a well-known characteristic for the group A streptococcal M protein, we have now found that the M molecules vary with respect to their molecular size, both between M types and within an M type. By the use of an M6 monoclonal antibody, which crossreacts with 20 different M protein types, and antibodies to the N-acetyl glucosamine determinant of the cell wall, we have been able to identify the M protein molecules released from the streptococcal cell wall with muralytic enzymes, particularly group C phage-associated lysin. Immunoblot analysis of the cell extract identified M protein molecules bound to various cell wall fragments, suggesting a peptidoglycan linkage for the M molecule. M protein extracted from 20 different streptococcal serotypes revealed size variations from 41,000 to 80,000 in molecular weight. This extreme variation is unusual for related proteins. Similar size variations in the M molecule were also found in random clinical isolates of type 6 streptococci. No size change was seen in M6 protein isolated from: (a) strains within a limited epidemic, (b) a strain passaged in mice 192 times, and (c) a strain passaged in the laboratory for 156 generations, suggesting that the observed variation is not a rapid process. The results indicate that, within the broad limits observed in this study, the size of the M protein may not be critical to the antiphagocytic activity of the molecule.

Immunologically reactive proteins of Streptococcus equi

Immunologically reactive proteins in acid extracts and culture supernatants of Streptococcus equi were recognized through a combination of chromatographic and immunologic procedures. Both high- and low-molecular-weight components of each of these protein preparations were protective for mice and were, therefore, presumed to contain a variety of hydrolytic products or fragments of the M protein of S. equi. Convalescent horse sera that exhibited strong bactericidal activity for S. equi always reacted with polypeptides in the molecular weight range of 24,000 to 29,000, whereas preinfection sera did not. Rabbit antisera to affinity-purified S. equi protein also reacted with these polypeptides, as well as with a polypeptide of about 36,000 to 37,000 molecular weight. M protein in acid extract and culture supernatant did not cross-react in immunodiffusion, but rabbit antiserum to affinity-purified M protein from an acid extract of S. equi reacted strongly with culture supernatant proteins of approximate molecular weights of 67,000, 58,000, and 43,000. We suggest, therefore, that the M protein in culture supernatant is masked by other sequences that are removed by hot acid during preparation of acid extracts. Polypeptides common to acid extracts of S. equi and Streptococcus zooepidemicus were also identified. These polypeptides had molecular weights of about 55,000 and 31,000.

Expression of protective and cardiac tissue cross-reactive epitopes of type 5 streptococcal M protein in Escherichia coli

The immunochemical properties of type 5 M protein antigens that were expressed in Escherichia coli K-12 by recombinant lambda bacteriophages isolated from a gene bank of serotype 5 Streptococcus pyogenes have been analyzed in detail. M proteins from partially purified bacteriophage lysates displayed precipitin lines of identity with a purified peptic extract of type 5 M protein (pep M5) in immunodiffusion assays. Immunoblot analyses of the M protein-positive lysates demonstrated that the cloned M protein component resided in five polypeptides with relative molecular weights of 57,900 (57.9K), 55.4K, 52.9K, 40.0K, and 32.6K. The hybrid lambda phage (lambda M5)-produced M protein contained immunoprotective epitopes; lambda M5 protein inhibited opsonization of type 5 streptococci by pep M5 antibodies, and antiserum raised against lambda M5 lysates opsonized type 5 streptococci. Each of the five antigenic polypeptides of the recombinant phage M protein also shared epitopes with human heart tissue, as demonstrated by the reactivity of immunoblots of lambda M5 antigens separated on sodium dodecyl sulfate gels with anti-pep M5 antibodies absorbed to and eluted from human heart sarcolemmal membranes. Moreover, antiserum raised against the lambda M5 lysates reacted with sarcolemmal membrane proteins with relative molecular weights of 200K, 59K, 55K, 53K, and 27K as determined by immunoblot analyses. These results demonstrate that the structural gene coding for type 5 streptococcal M protein which was inserted into lambda DNA expresses immunoprotective epitopes, some of which are shared with human heart tissue.

The type-specific polysaccharide and the R protein antigens of the L-phase from a group B, type III Streptococcus

The type-specific polysaccharide and the R protein antigens from filtered culture supernatants of the bacterial phase and L-phase of the group B, type III streptococcal strain 76-043 were studied by several immunological methods. In the L-phase of growth, the two antigens were separate and distinct molecules which were found principally in the culture supernatant even on the 254th serial subculture in the cell-wall-defective state. Only trace amounts of these antigens were detected in extracts of L-phase cells. The type III polysaccharide antigens in the supernatant of cultures of the parent bacterium and the L-phase gave reactions of identity in immunodiffusion. Precipitin bands obtained by immunoelectrophoresis (IEP) revealed that the type-specific antigen of the bacterial phase of growth migrated toward the anode, whereas that of the L-phase remained near the antigen well. The R protein antigen in the L-phase supernatant was immunologically identical to the R protein of the supernatant and 1% trypsin-extracted antigens from whole cells of the parent bacterial strain, and other groups A, B and C streptococcal strains sharing a common R antigen. Immunologically, the R antigen appeared to be the species R4. The R protein of the L-phase and bacterial phase cultures was resistant to 5% trypsin but sensitive to 0.5% pepsin at 37 degrees C/2hr. Antiserum prepared in rabbits against L-phase cells contained an antibody reactive with the R protein antigens of the bacterial and L-phase cultures. The soluble, naturally released type III and R protein streptococcal antigens of the L-phase of growth permitted immunological confirmation of its bacterial origin.

Streptococcal M6 protein expressed in Escherichia coli. Localization, purification, and comparison with streptococcal-derived M protein

Type 6 streptococcal M protein produced by E. coli bearing plasmid pJRS42.13 (ColiM6) accumulates in the periplasmic space of this new host. No immunoreactive M protein was found either on the surface of the organism or in the culture medium. The ColiM6 protein was purified from the periplasm and the final preparation consisted of three protein bands of apparent molecular weight 55,000, 57,000, and 59,000. These three bands were identical in migration in SDS PAGE to that of the M protein present in freshly prepared crude periplasm. The amino acid composition of the ColiM6 protein was nearly identical to that of M protein isolated from streptococci with phage lysin (LysM6). Furthermore, except for the amino terminal residue of the LysM6 molecule, the amino terminal sequence of the ColiM6 molecule was identical to those of both LysM6 and M protein released from the streptococcus by limited peptic digestion (PepM6). These results reveal that the molecule produced in the E. coli and transported into the periplasm may be the complete M protein as it exists on the streptococcus. The results also indicate that the systems that process M protein for transport through the cytoplasmic membrane are similar in the streptococcus and E. coli. The purified ColiM6 protein was able to remove opsonic antibodies from both human and rabbit serum, as well as to stimulate the production of opsonic antibodies in rabbits, indicating that the immunodeterminants on this molecule are the same as those found on streptococcal-derived M molecules.

Expression of streptococcal M protein in Escherichia coli

The structural gene for group A streptococcal M protein, the fibrillar surface molecule enabling the organism to resist phagocytosis, has been cloned into Escherichia coli. The molecule produced by Escherichia coli is slightly larger than the M protein isolated by solubilization of the streptococcal cell wall, but is similar in size to that secreted by streptococcal protoplast and L forms. Immunologically, the molecule synthesized by Escherichia coli has the same type-specific determinants as the streptococcal M protein.

Hybridoma antibodies against protective and nonprotective antigenic determinants of a structurally defined polypeptide fragment of streptococcal M protein

Hybridoma technology was used to produce a set of monoclonal antibodies against a purified polypeptide fragment of type 24 streptococcal M protein to delineate the protective determinants of M protein exposed on the surface of the virulent streptococci. Several hybridoma antibodies were found to be opsonic against the homologous type streptococci. At least two of these antibodies (IIC3.7 and IIC4.6) protected mice against challenge infections with the homologous, but not a heterologous, serotype of bacteria. One of the hybridoma antibodies that reacted in high dilution (1:204,800) with the isolated M protein failed to react with the M protein on the surface of type 24 streptococci, and thus did not opsonize the homologous organisms or protect mice against challenge infections. Because hybridoma antibodies are directed against a single distinct immunodeterminant, these results indicate that protective immunity may be directed at any one of several distinct antigenic determinants of M protein exposed on the surface of virulent group A streptococci.

Streptococcal M protein: alpha-helical coiled-coil structure and arrangement on the cell surface

The conformation and molecular dimensions of purified type 6 streptococcal M proteins establish the close structural relationship of these molecules to tropomyosin. Ultracentrifuge studies reveal that the M molecules exist as stable dimers; circular dichroism spectra indicate that the molecules contain about 70% alpha helix; and fiber x-ray diffraction diagrams show the characteristic reflections of the alpha-helical pattern. Electron microscopic images of M protein shadowed with platinum reveal rod-shaped molecules having the same width as tropomyosin. However, the lengths of the M molecules are about 30% shorter than lengths predicted by assuming a completely alpha-helical molecule. These findings indicate that the structure of the M6 protein is primarily alpha-helical coiled coil. Comparison of the lengths of the fibers on the surface of the streptococcus and the isolated M proteins suggests that each fiber on the cell wall consists of a single M-protein molecule approximately 500 A long. The structure determined for these fimbriae is the first alpha-helical coiled-coil conformation to be demonstrated for bacterial surface projections.