Surface receptors for serum albumin in group C and G streptococci show three different types of albumin specificity

Distinct Immunologic Properties of Soluble Versus Particulate Antigens

Antigens in particulate form have distinct immunologic properties relative to soluble antigens. An understanding of the mechanisms and functional consequences of the distinct immunologic pathways engaged by these different forms of antigen is particularly relevant to the design of vaccines. It is also relevant regarding the use of therapeutic human proteins in clinical medicine that have been shown to aggregate, and perhaps as a result, elicit autoantibodies.

Autologous albumin enhances the humoral immune response to capsular polysaccharide covalently coattached to bacteria-sized latex beads

Abundant autologous proteins, like serum albumin, should be immunologically inert. However, individuals with no apparent predisposition to autoimmune disease can develop immune responses to autologous therapeutic proteins. Protein aggregation is a potential major trigger of these responses. Adsorption of proteins to particles provides macromolecular size and may generate structural changes in the protein, resembling aggregation. Using aldehyde/sulfate latex beads coated with murine serum albumin (MSA), we found that BALB/c mice mounted MSA-specific IgG responses that were dependent on CD4(+) T cells. IgGs were specific for MSA adsorbed to solid surfaces and noncross-reactive with human, bovine, or pig albumins. T cells induced in response to MSA augmented the primary and induced boosted secondary IgG and IgM responses specific for the T cell-independent antigen, capsular polysaccharide of Streptococcus pneumoniae type 14 (PPS14), when the latter was attached to the same bead. Similar to the anti-MSA IgG response, the boosted PPS14-specific IgG secondary response was CD4(+) T-cell dependent, displayed a typical carrier effect, and was enhanced by, but did not require, Toll-like receptor stimulation. These results provide a potential mechanism for the induction of responses to autoantigens unable to induce specific T-cell responses, and provide new insights into polysaccharide-specific immunity.

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.

Further studies on immunoglobulin G- and albumin-binding properties of streptococci of serological group L

In this study, all 88 streptococci of serological group L isolated from cows, pigs, poultry and humans bound 125I-immunoglobulin G, and, in addition, 22 cultures interacted with 125I-albumin. IgG- and albumin-binding sites were solubilized from the streptococcal surface by heat extraction at an acid pH and also by mutanolysin treatment of the bacteria. Western blot analysis of these binding proteins revealed that almost identical protein bands were responsible for 125I-IgG and -albumin binding. Certain protein fractions of the cultures interacted exclusively with 125I-IgG, indicating that there are two groups of IgG receptors among streptococci of this serogroup.

Distribution of presumptive pathogenicity factors among beta-hemolytic streptococci isolated from Ethiopia

Beta-hemolytic streptococci are known to bind several mammalian proteins, which are presumed to be important in pathogenicity. The distribution of such binding structures was examined for mouse albumin, human serum IgA, human IgG, human fibrinogen, and human plasminogen. A total of 218 group A beta-hemolytic streptococci (GAS) were studied: 5 isolates from children with acute rheumatic fever (ARF), 18 from acute post-streptococcal glomerulonephritis (APSGN), 57 from tonsillitis, 52 from skin infections, and 86 from healthy carriers. Sixty-eight Streptococcus equisimilis and 20 group G streptococci were also included. Most of the S. equisimilis (60/68) and group G (14/20) were obtained from apparently healthy carriers. The results were evaluated with respect to T type, serum opacity reaction (SOR), site of isolation, and disease type. No direct correlation was detected between the protein-binding structures studied. There was no apparent correlation between any particular protein-binding structure and specific T type. Albumin-binding and IgA-binding activities were inversely correlated among skin and nephritis GAS isolates. A strong correlation was demonstrated between IgA-binding activity and SOR production, while albumin-binding activity correlated with SOR-negative strains. Albumin-binding levels in isolates from ARF, APSGN and tonsillitis were significantly higher than in isolates from healthy carriers (P < 0.001). A higher albumin-binding capacity was shown in skin isolates from APSGN than in isolates from impetigo (P < 0.001).

Comparison of albumin receptors expressed on bovine and human group G streptococci

The albumin receptor expressed by bovine group G streptococci was extracted and affinity purified. The protein was characterized for species reactivity, and monospecific antibodies were prepared to the purified receptor. The bovine group G albumin receptor was compared functionally, antigenically, and for DNA homology with the albumin-binding protein expressed by human group G streptococci. In agreement with previous reports, the albumin-binding activity of human strains was mediated by a unique domain of the type III immunoglobulin G-Fc-binding molecule, protein G. The albumin receptor expressed by bovine group G strains was found to lack any immunoglobulin G-binding potential but displayed a wider profile of species albumin reactivity than protein G. Both albumin receptors could inhibit the binding of the other to immobilized human serum albumin, and each displayed similar binding properties. Antigenic comparison of the two albumin receptors demonstrated a low level of cross-reactivity; however comparison at the DNA level, using an oligonucleotide probe specific for the albumin-binding region of protein G, demonstrated that the two albumin receptors expressed by human and bovine group G streptococcal strains do not display significant homology.

Bacterial infection of wounds: fibronectin-mediated adherence group A and C streptococci to fibrin thrombi in vitro

Adherence of group A, B, and C streptococci to fibrin thrombi was studied by using a novel fluorochrome microassay carried out in microdilution plates in which fibrin thrombi had been prepared by clotting citrated human, cattle, or horse plasma. Substantial adherence was observed with various strains of group A and C streptococci, whereas little was observed with group B streptococci. Adherence of all group A and C streptococcal strains decreased by up to 40% when fibronectin was depleted from the plasmas used for preparing fibrin thrombi, and fibronectin repletion increased adherence of streptococci in a dose-dependent manner. Addition of the 210-kilodalton C-terminal fragment of fibronectin to fibronectin-depleted plasma restored the adherence of group C but not group A streptococci, whereas addition of the 29-kilodalton N-terminal fragment was without any effect for all tested streptococcal strains. Prior incubation of group A and C streptococcal strains with fibronectin markedly increased their adherence, but treatment with proteases abolished their ability to adhere to fibrin thrombi. Adherence of group B streptococci was not affected by either fibronectin depletion or proteolytic digestion. These results indicate that both fibronectin incorporated into the fibrin matrix of thrombi and soluble fibronectin can mediate adherence of group A and C streptococci to fibrin thrombi and that binding sites for fibronectin located on the bacterial surface mediate this adherence.

Binding of immunoglobulin G and albumin to Streptococcus dysgalactiae

All 24 cultures of Streptococcus dysgalactiae investigated bound 125I-IgG, 13 cultures additionally interacted with 125I-albumin. Inhibition experiments with unlabelled IgG and albumin preparations from humans and various animal species indicated the specificity of the binding sites which showed characteristics of IgG Fc-receptors of type III and albumin-receptors of type c. IgG and albumin-binding proteins could be removed from the streptococcal surface by solubilization and subsequently isolated by affinity chromatography. The isolated binding proteins of S. dysgalactiae strains C 12 and C 8 obtained from IgG and albumin sepharose precipitated with IgG in immunodiffusion reactions, and in immunoelectrophoretic studies, and they reacted, after transfer onto nitrocellulose, with 125I-IgG or 125I-albumin and vice versa. Antisera produced against IgG-binding proteins of S. dysgalactiae C 12 inhibited binding of 125I-IgG and 125I-albumin. Solubilization of binding proteins by trypsinization yielded low molecular weight fragments with 125I-IgG but not with 125I-albumin binding activities. IgG-binding proteins isolated from S. dysgalactiae C 26 reacted with 125I-IgG but not with 125I-albumin, indicating the presence of 2 groups of type III Fc-receptors among S. dysgalactiae strains.

Protein G genes: structure and distribution of IgG-binding and albumin-binding domains

Protein G (also designated Fc receptor type III) is the IgG-binding protein of group C and G streptococci. Protein G has also been shown to bind human serum albumin but at a site that is structurally separated from the IgG-binding region. From the known gene sequence of protein G, two synthetic oligonucleotides were constructed for use as probes in DNA-hybridization experiments to study the structure and distribution of the albumin- and IgG-binding regions in bacterial strains belonging to different species. Thus, one of the probes corresponded to repeats within the IgG-binding region (I) and the other corresponded to repeats in the albumin-binding encoding region (II). Probe I showed strong hybridization to DNA isolated from 31 human group C and G strains, whereas hybridization to probe II was variable. With the three restriction endonucleases used, three restriction patterns were found in Southern blot experiments. No fundamental difference could be detected in hybridization experiments, either between strains of group C and G streptococci, or between isolates of different clinical origin. No hybridization to DNA from other bacterial species was found.

Binding of fibronectin and albumin to Enterococcus (Streptococcus) faecalis

Binding of human fibronectin (FN) and albumin to Enterococcus (Streptococcus) faecalis was investigated. Scatchard analysis showed that the cells could bind a maximum of 1300 molecules of FN with an association constant of 4.8 x 10(6) M-1. Binding did not appear to involve lipoteichoic acid. Heating the cells or pretreatment with protease or periodate reduced the binding, suggesting the involvement of protein and/or carbohydrate-containing components as the surface receptor. The cells could bind a maximum of 50,000 molecules of albumin but with a much lower affinity than FN (association constant 10.8 x 10(3) M-1). Surface hydrophobicity of E. faecalis was markedly decreased by albumin but not by FN.

Isolation and characterization of a specific receptor for human albumin on a group L Streptococcus

Certain group L streptococci demonstrate surface receptors for human albumin. Binding of 125I-albumin to group L streptococci could be inhibited by unlabelled albumin preparations from humans, dogs, mice and bovines, but not by albumin from rabbits. The albumin-binding proteins (ABP) could be solubilized from the streptococcal surface by hot acid treatment of the bacteria and isolated by affinity chromatography on human-albumin sepharose. ABP and specific antisera produced against ABP inhibited 125I-albumin binding to group L streptococci. The molecular weight of ABP determined by SDS-PAGE and Western blotting, was approximately 48,000 Dalton. ABP preparations of group G streptococci isolated from bovines and humans demonstrated cross reactivity with antiserum produced against group L streptococcal ABP.

Bindings of plasma proteins to streptococci of serological group L with special reference to their immunoglobulin G Fc-receptor activity

Of 33 streptococcal cultures belonging to serological group L, all bound human immunoglobulin (Ig) G, fibrinogen, and fibronectin; 32 bound bovine IgG; 31 bound alpha 2-macroglobulin; 5 bound albumin; and none bound either haptoglobin or IgA. The binding sites for IgG could be isolated from the L streptococci by trypsinization and purified by affinity chromatography on human IgG-Sepharose. The purified Fc receptors reacted with IgG subclasses 1, 2, 3, 4 of humans, 1 and 2 of bovines, ovines, and caprines as well as a, b, c, and T of equines. They had a molecular mass of approximately 49,000 Da. Thus, the Fc receptors from L streptococci corresponded to type III Fc receptors of Streptococcus dysgalactiae.

Binding of albumin fragments to surface receptor in A, C, and G streptococci

Fragments of human and bovine serum albumin were produced by treatment with trypsin at pH 8.15 and with pepsin at pH 3.5 and 3.7 in the presence of octanoic acid. A large fragment which included the C-terminal part of the native molecule was produced by trypsin treatment. The tryptic digest was subsequently treated with pepsin, resulting in smaller fragments. The ability of the fragments to bind to albumin-receptors on streptococci was investigated. According to Western blots only fragments with a mol. wt. of 23 kDa or more were able to bind to albumin-binding structures obtained from streptococci. The 23 kDa fragment was radiolabelled and tested for binding to whole bacteria. The fragment was capable of binding to albumin-reactive structures on group A, C, and G streptococci with the same species-specificity as native human and bovine serum albumin, respectively. Both the large 45 kDa tryptic fragment and the small 23 kDa fragment could bind to streptococci and could be dissociated by 2 M KSCN.

Isolation of a specific albumin receptor from a group G streptococcal strain

The albumin receptor, a bacterial cell-wall protein with affinity for albumin, has been isolated from a bovine group G streptococcal strain (DG-8). Bacterial surface proteins were solubilized by boiling in 0.6M HCl for 5 min. The albumin receptor was isolated by sequential use of ion-exchange chromatography on DEAE-Sephadex A-50 and affinity chromatography on albumin coupled Sepharose 4B. The presence of albumin receptor in various pools and fractions during the isolation was followed by their ability to inhibit the binding of radiolabelled albumin to DG-8 bacteria. A highly purified albumin receptor was obtained according to Western blot analysis. The albumin binding band obtained showed a molecular weight of about 30,000. The purified receptor did not possess any IgG binding capacity. 50 micrograms albumin receptor was prepared from each gram of bacteria.

Binding of aggregated human serum albumin to M12 and some other types of group A streptococci

In radiobinding tests many group A, C and G streptococci react with IgG and IgA, irrespective of the antigen-combining sites, as well as with various other serum proteins, e.g. human serum albumin (HSA). The present study demonstrated that glutaraldehyde-aggregated, radiolabelled HSA (a*HSA), in comparison to monomeric HSA, binds more avidly to streptococci. Of group A streptococci, strains representing types M6, M12, M18, M46, M55 and M57 displayed pronounced binding of a*HSA whereas a number of other serotypes were non-reactive. The streptococcal sites involved proved to be relatively heat-resistant and highly sensitive to trypsin treatment. Human fibrinogen counteracted the binding of a*HSA. The uptake by M12 was inhibited strongly by rabbit antiserum raised against M12, whereas other antisera were less active. The results suggest that the bacterial structure binding a*HSA is a protein and that, in at least one serotype, M12, the binding occurs to the M-protein.

Interactions of plasma proteins with group A, B, C and G streptococci

Streptococci of serological groups A, B, C and G displayed different binding activities for plasma proteins. Most of the streptococci studied, except those of group B, bound immunoglobulin G. All streptococci reacted with fibrinogen and, except those of group B, with fibronectin. The majority of streptococci, but none of group B, had an affinity for alpha 2-macroglobulin. Albumin was bound by all cultures of group G and a few of group C. Haptoglobulin interacted with only 1 group A culture. None of the streptococci bound transferrin. The specificity of binding sites for 125I-labelled plasma proteins was revealed in a series of inhibition experiments with the unlabelled proteins. The binding sites on streptococci of group G showed different sensitivities to trypsin and pepsin. Reactivities for immunoglobulin G, however, remained unaffected after treatments of the streptococci with trypsin. Exposure to heat (30 min, 80 degrees C) partially inactivated binding activities for the plasma proteins. Sodium dodecyl-sulphate and acetylimidazole strongly reduced binding of albumin and to a lesser extent that of alpha 2-macroglobulin. They had no or little effect on the interaction with the other plasma proteins. Dioxane decreased almost all binding activities. Ethanol partially diminished the binding of immunoglobulin G, fibrinogen, fibronectin and alpha 2-macroglobulin. Treatments of group G streptococci with guanidine, urea, formamide or methanol-HC1 did not affect their plasma protein binding activities.

Demonstration of a receptor for mouse and human serum albumin in Streptococcus pyogenes

A new type of surface receptor for serum albumin was detected in strains of Streptococcus pyogenes (group A). This receptor, called type e, was different from albumin receptors in other streptococcal species. Only mouse and human serum albumin was bound to the receptor. The albumin-binding capacity was high: 2 X 10(8) bacterial organisms bound 11 micrograms of mouse albumin. The receptor was stable even when treated at 100 degrees C for 5 min. Binding of albumin was not mediated by lipoteichoic acid (LTA) because of lack of correlation to surface LTA, restricted albumin reactivity, and positive binding in presence of 2% Tween 20. Presence of albumin receptor type e correlated to presence of M-protein as measured by growth in the bactericidal test. All 51 M-protein positive group A streptococcal strains tested could bind mouse albumin whereas only 3 out of 8 M-protein negative strains showed positive binding (P less than 0.001). The sensitivity to trypsin digestion suggests that the albumin receptor is of protein nature or mediated by a protein.

Variations in the binding of mammalian fibrinogens to streptococci of different animal origin

Binding of 125I-labelled fibrinogen from humans, bovines, equines, canines and ovines by streptococci of serological groups A, B, C and G was determined quantitatively. All 59 randomly selected streptococcal cultures generally bound more human fibrinogen than the other fibrinogens. Only Sc. dysgalactiae had a higher affinity for bovine fibrinogen. In addition, Sc. dysgalactiae bound distinctly more equine, canine and ovine fibrinogen than the other streptococci. Some cultures of Sc. equi and Sc. zooepidemicus had high binding activities for equine fibrinogen. Low binding capacities were exhibited by B-streptococci, particularly with fibrinogens from horses and dogs.

Electron microscopic localization of receptors for aggregated beta 2-microglobulin on the surface of beta-hemolytic streptococci

The presence and location of receptors for aggregated human beta 2-microglobulin (beta 2m) on the surface of group A, C, and G streptococci were studied by electron microscopic techniques. Ferritin-conjugated aggregates of human beta 2m were used in direct binding experiments. Ferritin-conjugated antibodies against beta 2m were employed in a two-step indirect binding assay where the streptococci were incubated with unlabeled beta 2m aggregates before the addition of antibodies. Similar results were obtained with these two methods. Among tested group C and G strains, some showed binding of beta 2m, whereas others were negative. In group A streptococci, beta 2m binding was localized to filamentous structures typical of M protein. In two M protein-negative group A strains, the reactivity was heterogeneous, revealing a majority of unlabeled, but also some heavily labeled streptococci. Morphologically, these beta 2m-binding bacteria exhibited M protein-like projections in contrast to the smooth surfaces of unlabeled cells.