In vitro resistance to platelet microbicidal protein correlates with endocarditis source among bacteremic staphylococcal and streptococcal isolates

Staphylocidal action of thrombin-induced platelet microbicidal protein is influenced by microenvironment and target cell growth phase

Thrombin-induced platelet microbicidal protein (tPMP) is a small, cationic peptide released from rabbit platelets following exposure to thrombin in vitro. This peptide exerts potent in vitro microbicidal activity against a broad spectrum of bloodstream pathogens, including Staphylococcus aureus. It is known that the microbicidal actions of other cationic antimicrobial peptides (e.g., neutrophil defensins) are influenced by environmental factors and target cell growth phase. However, whether these parameters affect tPMP microbicidal activity has not been studied. Thus, we assessed the in vitro bactericidal activity of tPMP against two tPMP-susceptible strains, Bacillus subtilis ATCC 6633 and S. aureus 502A, in various target cell growth phases or under various microenvironmental conditions. The conditions studied included differing bacterial growth phase (logarithmic versus stationary), temperature (range, 4 to 42 degrees C), pH (range, 4.5 to 8.5), cationicity (range, 0.1 mM to 2 M), anionicity (range, 0.08 to 5 microM), and neutral carbohydrates ranging in molecular weight (MW) from 180 to 37,700 (range, 50 to 500 mM) as well as rabbit platelet-free plasma and serum. tPMP staphylocidal activity was greater against logarithmic- than stationary-phase cells. tPMP bactericidal activity against both B. subtilis and S. aureus was directly correlated with temperature and pH, with microbicidal activity exhibited near the physiological range (37 to 42 degrees C and pH 7.2 to 8.5, respectively). The presence of cations (Na+, K+, Ca2+, and Mg2+) decreased tPMP bactericidal activity in a time- and concentration-dependent manner, with complete inhibition at monovalent or divalent cation concentrations of > or = 250 or > or = 10 mM, respectively. Staphylocidal activity of tPMP was also inhibited by the polyanions polyanetholsulfonic acid and polyaspartic acid, at 0.1 and 0.4 microM, respectively. Coincident exposure with low-MW carbohydrates (glucose, sucrose, and melezitose) did not affect tPMP staphylocidal activity. However, higher-MW carbohydrates (raffinose and dextrans) decreased tPMP activity in a manner directly proportional to their concentration and MW. Solute-mediated inhibition of tPMP bactericidal activity was independent of solute osmolality but directly related to the duration of tPMP-solute coexposure. tPMP enhanced the staphylocidal activities of platelet-free plasma and heat-inactivated serum, while the activity of normal serum was not affected. These collective observations suggest that tPMP retains antimicrobial activities under physiological conditions which are likely to be relevant to host defense in vivo.

Platelet-streptococcal interactions in endocarditis

Infective endocarditis is characterized by the formation of septic masses of platelets on the surfaces of heart valves and is most commonly caused by viridans streptococci. Streptococcal virulence in endocarditis involves factors that promote infectivity and pathogenicity. Adhesins and exopolysaccharide (glycocalyx) contribute to infectivity. Although many factors may contribute to pathogenicity, the platelet aggregation-associated protein (PAAP) of Streptococcus sanguis contributes directly to the development of experimental endocarditis. PAAP is synthesized as a rhamnose-rich glycoprotein of 115 kDa and contains a collagen-like platelet-interactive domain, pro-gly-glu-gln-gly-pro-lys. Expressed on the cell wall of platelet aggregation-inducing strains (Agg+) of S. sanguis, PAAP apparently interacts with a signal-transducing receptor complex on platelets, which includes a novel 175-kDa alpha 2-integrin-associated protein and a 65-kDa collagen-binding component. From available data, the role of PAAP in the pathogenesis of experimental endocarditis may be explained by a proposed mechanistic model. On injured heart valves, PAAP first enhances platelet accumulation into a fibrin-enmeshed thrombus (vegetation), within which S. sanguis colonizes. Colonizing bacteria must resist platelet microbicidal protein (PMPR). The aggregation of platelets on the heart valve may be potentiated by an ectoATPase expressed on the surface of the S. sanguis and platelet alpha-adrenoreceptors that respond to endogenous catecholamines. The expression of PAAP may be modified during infection. Collagen is exposed on damaged heart valves; fever (heat shock) occurs during endocarditis. In response to heat shock or collagen in vitro, PAAP expression is altered. After colonization, streptococcal exotoxin(s) may cause fever. Proteases and other enzymes from streptococci and host sources may directly destroy the heart valves. When PAAP is unexpressed or neutralized with specific antibodies, experimental endocarditis runs a milder course and vegetations are smaller. The data suggest strongly, therefore, that the role of PAAP may overlap the colonization function of putative adhesins such as FimA or SsaB. Finally, PAAP also contributes to the development of the characteristic septic mural thrombus (vegetation) of infective endocarditis and the signs of valvular pathology.

Resistance to platelet microbicidal protein results in increased severity of experimental Candida albicans endocarditis

Thrombin-induced platelet microbicidal protein (tPMP) exerts potent in vitro microbicidal activity against pathogens commonly found in the bloodstream, including Staphylococcus aureus, Staphylococcus epidermidis, and Candida albicans. Localized platelet release of tPMP may be important in defense against infections involving the vascular endothelium caused by tPMP-susceptible organisms. In contrast, pathogens capable of surviving in the presence of tPMP could then exploit the platelet as an adhesive surface for attachment to damaged endothelium. To examine these hypotheses, we derived a tPMP-resistant (tPMP(r)) C. albicans strain from its tPMP-sensitive (tPMP(s)) parental strains were equivalent in vitro as assessed by genotyping (electrophoretic karyotype and restriction endonuclease analysis of genomic DNA), biotyping, germination, platelet aggregation, adherence to vascular endothelial cells, and growth characteristics. In addition, the tPMP(r) phenotype was stable following multiple in vitro and in vivo passages. We then investigated the in vivo relevance of tPMP susceptibility on endovascular infection using a rabbit model of endocarditis and hematogenous dissemination. Rabbits with transaortic catheters (n = 15 in each group) were challenged with either the tPMP(s) or tPMP(r) C. albicans strain. All rabbits developed C. albicans-induced endocarditis, as determined by the presence of infected vegetations. In rabbits challenged with tPMP(s) strain (P < 0.001). These results were seen in the absence of differences in either initial adherence of strains to cardiac valves or vegetation weights. Furthermore, although these C. albicans strains induced equivalent rates and extent of hematogenous renal infection, only the tPMP(r) strain disseminated hematogenously to the spleen (15 of 15 rabbits) versus 0 of 15 [tpmp(s) strain]; P < 0.0001). Thus, tPMP(r) C. albicans caused more-severe endocarditis and produced greater metastatic sequelae than the tPMP(s) counterpart.

Staphylocidal action of thrombin-induced platelet microbicidal protein is not solely dependent on transmembrane potential

Thrombin-induced platelet microbicidal protein (tPMP) is a small, cationic, antimicrobial peptide released from rabbit platelets when stimulated with thrombin. We studied the relationship between staphylococcal transmembrane potential (delta psi) and tPMP staphylocidal activity. A genetically related pair of Staphylococcus aureus strains, 6850 and JB1, which differ in delta psi generation (-143 and -97 mV, respectively) were used. Mutant JB-1 was substantially less susceptible to tPMP than the parental strain, 6850. Menadione supplementation, which normalized the delta psi of strain JB-1, did not restore JB-1 tPMP susceptibility. These findings suggest that the staphylocidal activities of tPMP require factors other than or in addition to an intact delta psi.

FimA, a major virulence factor associated with Streptococcus parasanguis endocarditis

Adherence of microorganisms to damaged heart tissue is a crucial event in the pathogenesis of infective endocarditis. In the present study, we investigated the role of the FimA protein as a potential virulence factor associated with Streptococcus parasanguis endocarditis. FimA is a 36-kDa surface protein that is a recognized adhesin in the oral cavity where it mediates adherence to the salivary pellicle. An insertion mutant and a deletion mutant of S. parasanguis were employed in the rat model of endocarditis to determine the relevance of FimA in endocarditis pathogenesis. Catheterized rats were infected with either the fimA deletion mutant VT929, the fimA insertion mutant VT930, or the isogenic, wild-type S. parasanguis FW213. Rats inoculated with FW213 developed endocarditis more frequently (50.9%) than animals inoculated with either the deletion mutant (2.7%) or the insertion mutant (7.6%) (P < 0.001). A series of in vitro assays were performed to explore the mechanism(s) by which FimA enhanced the infectivity of S. parasanguis. FimA did not inhibit the uptake or the subsequent killing of S. parasanguis by phagocytic granulocytes. Similarly, FimA did not play a role in the adherence to or the aggregation of platelets. Significant differences were noted between FW213 and VT929 (P < 0.05) and FW213 and VT930 (P < 0.001) in their abilities to bind to fibrin monolayers. The mean percent adherence of FW213 to fibrin monolayers (2.1%) was greater than those of VT929 (0.5%) and VT930 (0.12%). Taken together, these results indicate that FimA is a major virulence determinant associated with S. parasanguis endocarditis and further suggest that its role is associated with initial colonization of damaged heart tissue.

Influence of aspirin on development and treatment of experimental Staphylococcus aureus endocarditis

Previously, we have shown that a 5-mg/kg of body weight daily dose of aspirin (ASA) caused reductions in the bacterial densities and weights of aortic vegetations in a rabbit model of Staphylococcus aureus endocarditis. We sought to determine (i) whether ASA dosage influences the development of vegetations and (ii) whether ASA given with antimicrobial therapy improves the treatment outcome of infective endocarditis. To study the influence of ASA dosage, animals received either no ASA (control) or oral doses of 2.5, 10, 20, and 50 mg/kg daily. The 2.5- and 10-mg/kg groups had statistically significant reductions in vegetation weight compared with untreated controls. The 10-mg/kg dose also resulted in a significant decrease in bacterial densities compared with those of the controls. Although reductions in weight and bacterial density were observed in other ASA-treated groups, these did not achieve statistical significance. To study the influence of ASA and antimicrobial therapy, the animals received either vancomycin alone or vancomycin with ASA. When ASA was given prior to and during antimicrobial therapy, a significant reduction in vegetation weight was observed. Additionally, the rate of sterilization was directly proportional to this observed reduction in weight. ASA's impact on the reduction of both the bacterial density and the weight of aortic vegetations is a dose-dependent phenomenon. When given with antimicrobial therapy, ASA not only reduces vegetation weight but also improves the rate of sterilization. This study provides additional data regarding the role of ASA in the treatment of endocarditis.

Pharmacodynamics of RP 59500 alone and in combination with vancomycin against Staphylococcus aureus in an in vitro-infected fibrin clot model

The bactericidal activity and emergence of resistance to RP 59500 (quinupristin/dalfopristin) when it was administered alone and in combination with vancomycin against fibrin clots that have been infected with methicillin-susceptible Staphylococcus aureus ATCC 25923 or methicillin-resistant S. aureus (MRSA) 67 were evaluated in an in vitro pharmacodynamic infected fibrin clot model. Fibrin clots were infected with S. aureus to achieve an inoculum of approximately 10(9) CFU/g. Antibiotics were administered to simulate pharmacokinetics in humans: RP 59500 (7.5 mg/kg of body weight) every 8 h and vancomycin (15 mg/kg) every 12 h over 72 h. Preliminary test tube time-kill experiments with an inoculum of approximately 10(5) CFU/ml suggested that RP 59500 was more rapid in achieving a 99.9% reduction in the number of CFU per milliliter than vancomycin against ATCC 25923 (6.94 versus 24 h; P = 0.0003) and MRSA 67 (6.77 versus 17.03 h; P = 0.004). At a higher inoculum (approximately 10(8) CFU/ml), 99.9% kill was achieved only with the combination regimen against ATCC 25923 and MRSA 67 (10.9 and 10.5 h, respectively), with total reductions of 6.35 and 6.33 log10 CFU/ml over 24 h, respectively. In the fibrin clot model, RP 59500 was more effective than vancomycin in reducing organism titers over 72 h. In the fibrin clot model, the most optimal therapy was the combination regimen.

Platelet microbicidal protein alone and in combination with antibiotics reduces Staphylococcus aureus adherence to platelets in vitro

Bacterial adherence to platelets on the cardiac valve surface is believed to be critical in the induction of infective endocarditis. Recent studies have confirmed that thrombin-activated platelets secrete platelet microbicidal protein (PMP), which can both kill and exert nonlethal antiadherence effects against endovascular pathogens. In the present study, we quantified the influence of antibiotic and/or PMP exposures on in vitro platelet adherence of two Staphylococcus aureus strains, identical by DNA restriction and cell wall protein profiles, that differed in their susceptibility to PMP-induced killing (PMPs or PMPr, respectively). Adherence assays were performed by flow cytometry in the presence of sublethal PMP concentrations (1 to 2.5 micrograms/ml) alone or in combination with ampicillin (AMP) alone, sulbactam (SUL) alone, or AMP plus SUL (AMP-SUL), at levels achievable in serum. Exposure of the PMPs and PMPr S. aureus strains to antibiotics (for 2 h at 37 degrees C) prior to flow cytometry resulted in no substantive changes in the percent adherence to platelets compared with that for S. aureus cells not exposed to antibiotics, except for modestly increased adherence of both PMPs and PMPr cells exposed to AMP-SUL (18.5 and 15.8% increases, respectively). Addition of PMP to antibiotic-S. aureus mixtures (final 30 min) caused a significant decrease in S. aureus adherence to platelets, for both the PMPs and PMPr S. aureus strains, compared with antibiotic exposure alone (e.g., reduction in platelet adherence from 57.9 +/- 8.2% to 12.2 +/- 3.6% for PMPs cells exposed to AMP-SUL and PMP [P = 0.01]). Moreover, addition of PMP following exposure of the PMPs and PMPr strains to AMP-SUL reversed the enhanced bacterium-platelet adherence observed with such antibiotic exposures alone (P < or = 0.005). These data demonstrate that PMP exerts a potent antiplatelet adherence effect which is independent of its microbicidal capacity, rendering S. aureus cells less adherent to platelets in the presence or absence of antibiotics. Reduction of microbial adherence to platelets by PMP alone or with antibiotics provides further insight into the mechanism(s) that may be involved in host defense and antibiotic prophylaxis of infective endocarditis and other endovascular infections.