Altered expression of the platelet aggregation-associated protein from Streptococcus sanguis after growth in the presence of collagen.

Certain strains of Streptococcus sanguis adhere selectively to human platelets (Adh+) and, in plasma, induce them to aggregate into in vitro thrombi (Agg+). The induction of aggregation is mediated by the platelet aggregation-associated protein (PAAP) expressed on the cell surface of the streptococcus. In endocarditis, expression of PAAP may be regulated by association with host proteins on damaged heart valves. To begin to test this hypothesis, three strains of S. sanguis were each cultured in the presence or absence of collagens (types I to X), laminin, or PAAP-derived peptide preparations. After harvesting and washing, the platelet-interactive phenotype of strains 133-79 (Adh+ Agg+), L74 (Adh+ Agg-), and 10556 (Adh- Agg-) was unchanged. The cells from each culture were then digested mildly with trypsin to isolate PAAP. PAAP isolated from strain 133-79 (Adh+ Agg+) grown in the absence of added collagen, other proteins, or peptides inhibited platelet aggregation in response to untreated cells of S. sanguis. Platelet aggregation was induced immediately, however, by PAAP from strain 133-79 isolated after growth in the presence of 300 nM type I collagen, while lower concentrations yielded protein fragments that potentiated the response to intact cells. Aggregation-inducing PAAP could be removed by anti-PAAP (PGEQGPK) immunoaffinity chromatography, but only inhibitory activity could be recovered. The agonist effect of PAAP was not associated with collagen itself, since the PAAP preparations did not contain detectable amounts of hydroxyproline. PAAP antigens isolated from cells grown in the presence and absence of collagen had similar apparent molecular weights, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western immunoblotting. When electrophoresis was performed under nondenaturing conditions, however, PAAP isolated from cells grown in type I collagen migrated more slowly. Strain L74 grown with type I collagen yielded tryptic fragments of proteins that inhibited aggregation significantly better than control peptides (no collagen in the medium). Strain 10556 was apparently unaffected by growth in type I collagen. The effect of type I collagen was somewhat unique. Growth in the presence of collagen types II to VI (300 nM) yielded protein fragments that potentiated without inducing platelet aggregation, while other collagens, laminin, and PAAP-derived peptides did not affect platelet aggregation. These results suggest that growth in the presence of type I collagen and, perhaps, collagens II to VI alters the expression and conformation of PAAP in certain strains of S. sanguis.     

Phenotypic characterization of Streptococcus sanguis virulence factors associated with bacterial endocarditis.

Certain strains of Streptococcus sanguis adhere (Adh+) selectively to human platelets and, in plasma, induce them to aggregate (Agg+) into in vitro thrombi. In this study, we examined 18 recent endocarditis and dental plaque isolates of microorganisms that were biotyped as S. sanguis for coexpression of platelet interactivity phenotypes with another possible virulence factor in bacterial endocarditis, dextran synthesis. Detectable production of extracellular glucosyltransferase ranged from 0.2 to 66 mU/mg of culture fluid for 10 representative strains tested. Production of extracellular or cell-associated glucosyltransferase, fructosyltransferase, and soluble or insoluble dextrans was not necessarily coexpressed with platelet interactivity phenotypes, since the levels of production of soluble and insoluble dextrans varied among representative Adh+ Agg+ and Adh- Agg- strains. Analysis of a second panel of 38 fresh dental plaque isolates showed that S. sanguis distributes in a reproducible manner into the possible phenotype groups. Strains with different platelet interactivity phenotypes were distinguished with a panel of four murine monoclonal antibodies (MAbs) raised against Adh+ Agg+ strain 133-79 and screened to rule out artifactual reactions with antigenic components in culture media. The MAbs reacted selectively with Adh+ Agg+ strains in a direct-binding, whole-cell, enzyme-linked immunosorbent assay and also inhibited their interactions with platelets. Analysis of minimal tryptic digests of many strains, including variants that failed to bind the MAbs, suggested that some noninteractivity phenotypes possess cryptic surface determinants. Since the ability to adhere to platelets and induce them to aggregate is relatively stable, these traits may be useful in a phenotyping scheme for these Lancefield nontypeable streptococci.     

Platelet receptors for the Streptococcus sanguis adhesin and aggregation-associated antigens are distinguished by anti-idiotypical monoclonal antibodies.

Platelets aggregate in response to an adhesin and the platelet aggregation-associated protein (PAAP) expressed on the cell surfaces of certain strains of Streptococcus sanguis. We sought to identify the corresponding PAAP receptor and accessory adhesin binding sites on platelets. Since the adhesion(s) of S. sanguis for platelets has not been characterized, an anti-idiotype (anti-id) murine monoclonal antibody (MAb2) strategy was developed. First, MAb1s that distinguished the adhesin and PAAP antigens on the surface of S. sanguis I 133-79 were selected. Fab fragments of MAb1.2 (immunoglobulin G2b [IgG2b]; 70 pmol) reacted with 5 x 10(7) cells of S. sanguis to completely inhibit the aggregation of human platelets in plasma. Under similar conditions, MAb1.1 (IgG1) inhibited the adhesion of S. sanguis cells to platelets by a maximum of 34%, with a comparatively small effect on platelet aggregation. Together, these two MAb1s inhibited S. sanguis-platelet adhesion by 63%. In Western immunoblots, both MAb1s reacted with S. sanguis 133-79 87- and 150-kDa surface proteins and MAb1.2 also reacted with purified type I collagen. The hybridomas producing MAb1.1 and MAb1.2 were then injected into BALB/c mice. Enlarged spleens were harvested, and a panel of MAb2 hybridomas was prepared. To identify anti-ids against the specific MAb1s, the MAb2 panel was screened by enzyme-linked immunosorbent assay for reaction with rabbit polyclonal IgG antibodies against the 87- and 150-kDa antigens. The reactions between the specific rabbit antibodies and anti-ids were inhibited by the 87- and 150-kDa antigens. When preincubated with platelets, MAb2.1 (counterpart of MAb1.1) inhibited adhesion to platelets maximally by 46% and MAb2.2 (anti-MAb1.2) inhibited adhesion to platelets maximally by 35%. Together, both MAb2s inhibited the adhesion of S. sanguis to platelets by 81%. MAb2.2 also inhibited induction of platelet aggregation. MAb2.2 immunoprecipitated a biotinylated platelet membrane antigen of 170 kDa (unreduced); MAb2.1 precipitated membrane antigens of 175- and 230-kDa (unreduced). Therefore, platelet binding sites and the receptor for the S. sanguis adhesin and PAAP, respectively, are distinguished by the anti-id MAb2s.     

Aggregation of human platelets and adhesion of Streptococcus sanguis.

Platelet vegetations or thrombi are common findings in subacute bacterial endocarditis. We investigated the hypothesis that human platelets selectively bind or adhere strains of Streptococcus sanguis and Streptococcus mutans and aggregate, as a result, into an in vitro thrombus. Earlier ultrastructural studies suggested that aggregation of platelets over time by Staphylococcus aureus was preceded in order by adhesion and platelet activation. We uncoupled the adhesion step from activation and aggregation in our studies by incubating streptococci with platelet ghosts in a simple, quantitative assay. Adhesion was shown to be mediated by protease-sensitive components on the streptococci and platelet ghosts rather than cell surface carbohydrates or dextrans, plasma components, or divalent cations. The same streptococci were also studied by standard aggregometry techniques. Platelet-rich plasma was activated and aggregated by certain isolates of S. sanguis. Platelet ghosts bound the same strains selectively under Ca2+- and plasma-depleted conditions. Fresh platelets could activate after washing, but Ca2+ had to be restored. Aggregation required fresh platelets in Ca2+-restored plasma and was inducible by washed streptococcal cell walls. These reactions in the binding and aggregometry assays were confirmed by transmission electron microscopy. Surface microfibrils on intact S. sanguis were identified. These appendages appeared to bind S. sanguis to platelets. The selectivity of adhesion of the various S. sanguis strains to platelet ghosts or Ca2+- and plasma-depleted fresh washed platelets was similar for all donors. Thus, the platelet binding site was expressed widely in the population and was unlikely to be an artifact of membrane aging or preparation. Since selective adhesion of S. sanguis to platelets was apparently required for aggregation, it is suggested that functionally defined receptors for ligands on certain strains of S. sanguis may be present on human platelets. Some differences in the selectivity and rate of the aggregation response were noted among platelet donors, although the meaning of the variability requires further study. Nonetheless, these interactions may contribute to platelet accretion in the initiation and development of vegetative lesions in the subacute bacterial endocarditis.     

Interleukin 1alpha increases the susceptibility of rabbits to experimental viridans streptococcal endocarditis

Major predisposing conditions for infective endocarditis (IE) are the presence of a cardiac platelet-fibrin vegetation and of circulating bacteria with relatively low susceptibility to microbicidal activity of blood platelets. The influence of proinflammatory conditions on development of IE is unknown. We studied the effects of the presence of a catheter, inserted to induce platelet-fibrin vegetations, and of the proinflammatory cytokine interleukin-1alpha in rabbit experimental IE. Leaving the catheter in place after challenge with viridans streptococci predisposed for experimental IE. IE susceptibility rapidly decreased between 0 to 6 h after catheter removal. The catheter did not predispose for IE by providing a site for bacterial adherence, as almost all explanted catheters were culture negative. To mimic the proinflammatory influence of the catheter, rabbits were injected with interleukin-1alpha at 24 h after catheter removal and at 0, 1, and 3 h before bacterial challenge. Interleukin-1alpha injected 3 h prior to challenge significantly increased IE incidence due to a platelet releasate-susceptible Streptococcus oralis strain, with rapidly increasing numbers of bacteria within the vegetations. IE due to the Streptococcus sanguis strain less susceptible to platelet releasate was not enhanced. We conclude that proinflammatory stimuli, either a catheter or interleukin-1alpha, enhanced susceptibility to IE due to the platelet releasate-susceptible S. oralis. As with rabbits, temporary intravascular proinflammatory conditions may predispose for IE in humans at risk for this serious infection.     

Effects of molecular weight of dextran on the adherence of Streptococcus sanguis to damaged heart valves.

Dextran-producing streptococci such as Streptococcus sanguis are the organisms most frequently associated with infective endocarditis in humans. A series of experiments was designed to study how the molecular weight of dextrans affects the adherence of an endocarditis strain of S. sanguis to canine heart valves covered with platelets and fibrin. The data indicated that this adherence was dependent on dextrans of high molecular weight, such as dextran T-2000 or glucans isolated from S. sanguis or S. mutans. The adherence properties of the strain studied were not modified by prior exposure of the bacterial cells of valve leaflets to high-molecular-weight dextrans. Preexposure of bacterial cells or valve leaflets to low-molecular-weight dextrans decreased their adherence. Low-molecular-weight dextrans interfered with adherence of dextran-positive strains to damaged heart valves.     

The rate model of endocarditis

The rat model of endocarditis is a well established experimental protocol which closely approximates human native valve endocarditis. The rat model of endocarditis has been used to examine the role of particular streptococcal virulence factors, to assess immunoprotective strategies, and to evaluate the efficacy of selected antibiotic treatment regimens for streptococcal endocarditis. Like humans, rats are generally susceptible to endocarditis only if the cardiac valves have been damaged. In the rat model of endocarditis, damage to the aortic valve and sterile vegetation formation is accomplished by insertion of a polyethylene catheter through the carotid artery into the left ventricle. Following catheter insertion, an inoculum of streptococci are injected intravenously. Vegetations removed from the heart valves during thoracotomy of euthanized animals are qualitatively cultured for streptococcal infection. The method, including investigator safety considerations, is described in detail.     

Antibodies to capsular polysaccharides are not protective against experimental Staphylococcus aureus endocarditis.

The protective efficacy of antibodies to the Staphylococcus aureus capsular polysaccharide was examined in a rat model of catheter-induced endocarditis. Capsular antibodies were induced either by active immunization with killed S. aureus or by passive immunization with hyperimmune rabbit antiserum to S. aureus. Control rats were injected with phosphate-buffered saline or passively immunized with normal rabbit serum or rabbit antiserum to a nonencapsulated strain. Animals with indwelling catheters were challenged intravenously with 5 x 10(4) to 4 x 10(6) CFU of the homologous S. aureus strain (capsular serotype 5 strain Reynolds or serotype 1 strain SA1 mucoid). Both immunized and control rats developed S. aureus endocarditis. The numbers of S. aureus cells recovered from the blood and aortic valve vegetations of immunized rats were similar to those of control rats, indicating that capsule-specific antibodies were not protective. To determine whether the presence of an indwelling catheter interfered with antibody-mediated protection against S. aureus endocarditis, catheters were removed 2 h after insertion in additional groups of rats. An inoculum of 10(8) CFU of strain Reynolds was needed to provoke endocarditis in rats catheterized for 2 h, compared with 5 x 10(4) CFU for rats with indwelling catheters. Passively transferred capsular antibodies were not protective since both immunized and nonimmunized animals developed endocarditis, and quantitative cultures of blood and valvular vegetations revealed no differences between immunized and control animals. The findings of this study indicate that antibodies to the capsular polysaccharide are not protective in the rat model of experimental S. aureus endocarditis.     

Platelet aggregation induced by serotype polysaccharides from Streptococcus mutans

Platelet aggregation plays an important role in the pathogenesis of infective endocarditis induced by viridans streptococci or staphylococci. Aggregation induced in vitro involves direct binding of bacteria to platelets through multiple surface components. Using platelet aggregometry, we demonstrated in this study that two Streptococcus mutans laboratory strains, GS-5 and Xc, and two clinical isolates could aggregate platelets in an irreversible manner in rabbit platelet-rich plasma preparations. The aggregation was partially inhibited by prostaglandin I(2) (PGI(2)) in a dose-dependent manner. Whole bacteria and heated bacterial cell wall extracts were able to induce aggregation. Cell wall polysaccharides extracted from the wild-type Xc strain, containing serotype-specific polysaccharides which are composed of rhamnose-glucose polymers (RGPs), could induce platelet aggregation in the presence of plasma. Aggregation induced by the serotype-specific RGP-deficient mutant Xc24R was reduced by 50% compared to the wild-type strain Xc. In addition, cell wall polysaccharides extracted from Xc24R failed to induce platelet aggregation. The Xc strain, but not the Xc24R mutant, could induce platelet aggregation when preincubated with plasma. Both Xc and Xc24R failed to induce platelets to aggregate in plasma depleted of immunoglobulin G (IgG), but aggregation was restored by replenishment of anti-serotype c IgG. Analysis by flow cytometry showed that S. mutans RGPs could bind directly to rabbit and human platelets. Furthermore, cell wall polysaccharides extracted from the Xc, but not the Xc24R, strain could induce pseudopod formation of both rabbit and human platelets in the absence of plasma. Distinct from the aggregation of rabbit platelets, bacterium-triggered aggregation of human platelets required a prolonged lag phase and could be blocked completely by PGI(2). RGPs also trigger aggregation of human platelets in a donor-dependent manner, either as a transient and reversible or a complete and irreversible response. These results indicated that serotype-specific RGPs, a soluble product of S. mutans, could directly bind to and activate platelets from both rabbit and human. In the presence of plasma containing IgG specific to RGPs, RGPs could trigger aggregation of both human and rabbit platelets, but the degree of aggregation in human platelets depends on the donors.     

Diminished platelet binding in vitro by Staphylococcus aureus is associated with reduced virulence in a rabbit model of infective endocarditis.

The direct binding of platelets by bacteria is a postulated central mechanism in the pathogenesis of endocarditis. To address the role of binding more definitively, we employed Tn551 insertional mutagenesis of Staphylococcus aureus parental strain ISP479 to generate an isogenic variant (strain PS12) that bound platelets minimally. As compared with the binding of ISP479, the binding of PS12 to platelet monolayers was reduced by 67.2%. Similarly, the binding of PS12 to platelets in suspension was reduced by 71.3%, as measured by flow cytometry. The low-binding phenotype was transducible into both ISP479 and S. aureus Newman. Southern blotting indicated that a single copy of Tn551 was inserted within the chromosomes of PS12 and the transductants. When tested in a rabbit model, animals inoculated with PS12 were significantly less likely to develop endocarditis and had lower densities of organisms (CFU per gram) within vegetations and a decreased incidence of renal abscess formation, as compared with animals inoculated with the parental strain. The diminished virulence of PS12 was not attributable to a reduction in the initial attachment of organisms to the damaged endocardium, since 30 min after inoculation, PS12-infected animals had microbial densities on the valve surface comparable to those seen with the parental strain. These results indicate that the direct binding of Staphylococcus aureus to platelets is a major determinant of virulence in the pathogenesis of endocarditis. Staphylococcus-platelet binding appears to be critical for pathogenetic events occurring after the initial colonization of the valve surface, such as vegetation formation and septic embolization.     

Influence of preformed antibody on experimental Streptococcus sanguis endocarditis.

The influence of preformed, anti-whole organism antibody on the development of Streptococcus sanguis endocarditis was examined in both in vivo and in vitro systems. Antibody prevented, rather than potentiated, endocarditis in rabbits. The infectious dose in 30 control animals was 10(6.5) +/- 0.33 (mean +/- standard deviation); this increased to 10(7.71 +/- 0.05 in 36 immunized animals (P less than 0.01). No differences in bacterial clearance mechanisms were apparent between groups. Antibody also prevented the adherence of S. sanguis to the constituents of nonbacterial thrombotic endocarditis (fibrin and platelets) in vitro. When preincubated in high-titer antisera, adherence of S. sanguis was reduced compared with controls (adherence ratio mean +/- standard error of the mean, X 10(4): 174 +/- 5 versus 427 +/- 10, P less than 0.001). Preadsorption of immune sera with intact S. sanguis restored adherence to normal values, whereas preadsorption with dextran was partially effective. These studies demonstrate that preformed antibody had a protective role in vivo and suggest that a possible mechanism is blockade of adherence, a crucial early step in the pathogenesis of endocarditis.     

Role of granulocytes in the induction of an experimental endocarditis with a dextran-producing Streptococcus sanguis and its dextran-negative mutant.

The role of granulocytes in the induction of endocarditis with a dextran-producing Streptococcus sanguis and a dextran-negative mutant of this strain was studied. The number of colony-forming units of Streptococcus sanguis needed to colonize the vegetations in 50% of the rabbits (ID50) was significantly lower for the parent strain than for the dextran-negative mutant. However, in granulocytopenic rabbits the ID50s of both strains did not differ measurably. Dextran-negative streptococci were more readily cleared from the circulation than dextran-positive, but in this respect no difference was found between control and granulocytopenic rabbits, which indicates that clearance cannot account for the difference in ID50 between the two strains in the control group. At serum concentrations of 5% and lower, in-vitro granulocytes phagocytosed the dextran-negative streptococci more rapidly than the dextran-positive. The intracellular killing of the streptococci was no influenced by dextran production. This study suggests that an impaired phagocytic removal of attached bacteria from the vegetational surface can be a factor promoting the induction of endocarditis by dextran-producing streptococci.     

Role of granulocytes in the induction of an experimental endocarditis with a dextran-producing Streptococcus sanguis and its dextran-negative mutant

The role of granulocytes in the induction of endocarditis with a dextran-producing Streptococcus sanguis and a dextran-negative mutant of this strain was studied. The number of colony-forming units of Streptococcus sanguis needed to colonize the vegetations in 50% of the rabbits (ID50) was significantly lower for the parent strain than for the dextran-negative mutant. However, in granulocytopenic rabbits the ID50s of both strains did not differ measurably. Dextran-negative streptococci were more readily cleared from the circulation than dextran-positive, but in this respect no difference was found between control and granulocytopenic rabbits, which indicates that clearance cannot account for the difference in ID50 between the two strains in the control group. At serum concentrations of 5% and lower, in-vitro granulocytes phagocytosed the dextran-negative streptococci more rapidly than the dextran-positive. The intracellular killing of the streptococci was no influenced by dextran production. This study suggests that an impaired phagocytic removal of attached bacteria from the vegetational surface can be a factor promoting the induction of endocarditis by dextran-producing streptococci.     

Experimental Escherichia coli endocarditis in rats: roles of serum bactericidal activity and duration of catheter placement.

Studies were undertaken to investigate the relationship of the sensitivity of Escherichia coli to the bactericidal properties of serum and the ability of different strains to induce and sustain endocardial infection in rats. Strains of E. coli demonstrated different degrees of serum sensitivity, as determined by a method which employed concentrations of serum from 10 to 95% and periods of incubation as long as 24 h. The greater the serum sensitivity of the E. coli strain, the less able it was to initiate infection and the more rapidly it was spontaneously eliminated from established infections. Endocardial infection with E. coli was established by intravenous challenge in rats with polyethylene catheters passing through the aortic valve into the left ventricle. An E. coli strain of low serum sensitivity was used; the initiation of infection depended upon the length of time the catheter had been in place and, in addition, whether the catheter was in place at the time of bacterial challenge. Removal of the catheter permitted spontaneous sterilization of the endocardial vegetations. The time necessary for sterilization was in direct proportion to the length of time the catheter remained in place following bacterial challenge. If the catheter was not removed, sterilization of the endocardial vegetations did not take place. These studies suggest that serum bactericidal activity is an important host defense mechanism, acting to prevent the initiation of endocarditis in the case of highly serum-sensitive E. coli and to sterilize experimentally induced endocarditis in the case of less-serum-sensitive bacteria. The catheter used to induce nonbacterial endocardial vegetations favored the colonization of vegetations by E. coli, and it delayed the spontaneous sterilization of infected vegetations which occurred in relation to the susceptibility of the strain to the bactericidal properties of the serum. This effect of the catheter was not attributable to bacteria remaining viable in its lumen, nor was it attributable to inhibition of the bactericidal capacity of the serum as measured in vitro. Whatever the mechanism responsible for the catheter effect, experimental studies of the evolution of infections established with this technique must take into consideration the duration of catheter placement and whether and for how long it was present before or after inoculation with test bacteria.     

Role of granulocytes in experimental Streptococcus sanguis endocarditis.

We investigated the role of granulocytes during the induction and course of experimental Streptococcus sanguis endocarditis in rabbits by depleting blood granulocytes with nitrogen mustard. The induction of the endocarditis was not influenced by granulocytopenia: the 50% infectious dose was 5.4 X 10(4) colony-forming units in normal and granulocytopenic rabbits. However, granulocytopenia influenced the curse of the endocarditis, as shown by a significant increase in the number of colony-forming units per gram of vegetation (P less than 0.02) from 24 to 72 h after the injection of 10(5) colony-forming units of S. sanguis. This rise did not occur in the control rabbits. Furthermore, bacteremia was significantly higher in the granulocytopenic rabbits (P less than 0.05) during the first 48 h compared with the control rabbits. This was not because of altered clearance of the streptococcus inoculum or seeding of streptococci from extracardiac bacterial foci. We concluded that granulocytes have no measurable effect on the induction of S. sanguis endocarditis, but during the course of the endocarditis, granulocytes keep the endocardial infection in check.     

Phenotypic resistance to thrombin-induced platelet microbicidal protein in vitro is correlated with enhanced virulence in experimental endocarditis due to Staphylococcus aureus.

Thrombin-induced platelet microbicidal protein (tPMP) is secreted by rabbit platelets following thrombin stimulation, and it kills common endovascular pathogens in vitro, including Staphylococcus aureus. Therefore, pathogens which exhibit tPMP resistance in vitro possess a potential survival advantage in vivo at sites of endovascular damage. We generated an isogenic S. aureus strain pair, differing in tPMP susceptibility, by transposon (Tn551) mutagenesis of a tPMP-susceptible (tPMPs) parental strain (ISP479) to derive a stably tPMP-resistant (tPMPr) strain, ISP479R. ISP479 and ISP479R were equivalent in vitro in the following phenotypes: biotyping, antiobiograms, platelet adherence and aggregation, growth kinetics, cell wall-associated protein A expression, and fibrinogen binding. Genotypic comparisons of chromosomal DNA of strains ISP479 and ISP479R following restriction endonuclease digestion revealed indistinguishable pulsed-field gel electrophoretic patterns. The genotype exhibited by strain ISP479R was linked to the tPMP-resistant phenotype, as it was transducible into the initially tPMP-susceptible parental strain, ISP479. Southern hybridization verified the presence of a single copy of Tn551 in the same chromosomal restriction site of both ISP479R and tPMPr transductants of ISP479. The correlation of in vitro tPMP susceptibility phenotypes with the ability to induce experimental endocarditis (a prototypical endovascular infection) was evaluated. Despite equivalent rates of endocarditis induction, animals infected with strain ISP479R achieved significantly higher vegetation bacterial densities over a 7-day post-challenge period than did animals infected with strain ISP479. These data suggest that tPMPr microbial strains have a selective advantage in experimental staphylococcal endocarditis. Furthermore, the major impact of tPMP resistance upon endocarditis pathogenesis appears to involve a postvalvular adherence event(s), most probably by facilitating bacterial proliferation within vegetations.     

The Abilities of a Staphylococcus epidermidis Wild-Type Strain and Its Slime-Negative Mutant To Induce Endocarditis in Rabbits Are Comparable

The abilities of a parent and mutant pair of Staphylococcus epidermidis strains, the slime-producing parent RP62A and its slime-negative mutant, to establish endocarditis in a rabbit model of aortic valve endocarditis and to accumulate and adhere to surfaces in vitro were compared. Vegetation titer and infection rate depended on the presence or absence of a catheter (P = 0.020) and on inoculum size (P < 0.001) but not on the infecting strain. The ability of the parent strain vis-à-vis its mutant to accumulate in vitro on surfaces as demonstrated in a slime test did not correlate with any enhancement in the development of endocarditis in the rabbit model. In vitro initial adherence rates were identical. Both isolates accumulated to the same reduced extent in vitro in the presence of serum, albumin, or gelatin. Adhesion was equally promoted by addition of fibronectin. These data suggest that the in vitro phenomenon of accumulation described as slime production in the absence of serum may not be an important virulence determinant in vivo.     

Mechanisms of platelet aggregation by viridans group streptococci.

The direct aggregation of platelets is thought to be an important event in the pathogenesis of viridans streptococcal endocarditis, but the mechanisms for platelet activation are unknown. We evaluated the processes by which two endocarditis-producing strains of viridans group streptococci activated human platelets in vitro, as measured by platelet cyclooxygenase activity, secretion, and aggregation. Addition of either streptococcal strain to platelets suspended in whole plasma resulted in a mean lag phase of 15.3 min, followed by platelet secretion and brisk aggregation. The lag phase duration was dependent on the platelet donor and appeared to be a function of direct platelet-bacterial interaction. Aggregation was partially inhibited by 20 muM [corrected] indomethacin and blocked completely by 1 mg of apyrase, an extracellular ADP hydrolase, per ml. Neither strain aggregated washed platelets suspended in Tyrode solution alone. However, both strains produced maximal aggregation when the platelet suspension was supplemented with 10% (final concentration) normal plasma. Studies with factor-deficient plasmas demonstrated that exogenous fibrinogen was required for aggregation. One or more additional plasma components were needed, which eluted with a molecular weight of 67,000 to 130,000 on gel permeation chromatography. These cofactors have not been described for other platelet agonists, which suggests that viridans streptococci may aggregate human platelets by a novel mechanism.     

Cell-free released components of Streptococcus sanguis inhibit human platelet aggregation

To study the role of surface components in the selective binding and aggregation of platelet-rich plasma (PRP) by strains of viridans streptococci, we treated the binding, aggregation strain Streptococcus sanguis I 2017-78 by sonication or trypsinization. Morphologically identifiable electron-dense fibrils were released from the cell wall, apparently from an inner electron-dense layer, under conditions that left cells intact. These controlled conditions were determined to cause submaximal loss in adhesion to platelet ghosts and PRP aggregation by treated, washed S. sanguis. Soluble components were recovered from the controlled sonic or L-(tosylamido 2-phenyl)ethyl chloromethyl ketone-trypsin treatments. Each showed dose-response inhibition of aggregation when preincubated with PRP before challenge with fresh, untreated S. sanguis. The time to onset of PRP aggregation was inhibited by 50% with 0.2 mg of TPCK-trypsin peptides or 1.0 mg of the sonicate per ml per 2 X 10(8) platelets. Components of both preparations were immunologically cross-reactive, but lipoteichoic acid was not a major antigen of either. By weight, the TPCK-trypsin peptides were virtually all protein; the sonicate residues identified were about 50% protein and 7% hexose. Each was a complex mixture of components as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. More than 8 TPCK-trypsin peptides and 16 sonicate components were so identified. In contrast, at least four or five components from either preparation were recognized as surface determinants by a rabbit antiserum to whole homologous microbes. Platelet-binding ligands of S. sanguis could be among these determinants.     

Role of SraP, a Serine-Rich Surface Protein of Staphylococcus aureus, in binding to human platelets

The binding of bacteria to platelets is a postulated central event in the pathogenesis of infective endocarditis. Platelet binding by Streptococcus gordonii is mediated in large part by GspB, a high-molecular-mass cell wall glycoprotein. Although Staphylococcus aureus has a GspB homolog (SraP), little is known about its function. SraP has a calculated molecular mass of 227 kDa and, like GspB, is predicted to contain an atypical N-terminal signal sequence, two serine-rich repeat regions (srr1 and srr2) separated by a nonrepeat region, and a C-terminal cell wall anchoring motif (LPDTG). To assess whether SraP contributes to platelet binding, we compared the binding to human platelets of S. aureus strain ISP479C and of an isogenic variant (strain PS767) in which sraP had been disrupted by allelic replacement. Platelet binding in vitro by PS767 was 47% +/- 17% (mean +/- standard deviation) lower than that of ISP479C (P < 0.001). In addition, a recombinant fragment of SraP containing srr1 and the nonrepeat region was found to bind platelets directly. Binding was saturable, suggesting a receptor-ligand interaction. When tested in a rabbit model of endocarditis, in which each animal was simultaneously infected with ISP479C and PS767 at a ratio of approximately 1:1, the titers of the mutant strain within vegetations were significantly lower than those of the parent strain at 1 and 24 h postinfection. These results indicate that SraP can mediate the direct binding of S. aureus to platelets and that the platelet-binding domain of this glycoprotein is located within its N-terminal region. Moreover, the expression of SraP appears to be a virulence determinant in endovascular infection.