Thirty-three enterococcal strains and 10 Streptococcus bovis strains were investigated for their protein-binding cell surface components. Seven extracellular matrix (ECM) proteins were immobilized on Difco latex beads to detect these components on the surface of all enterococcal strains and eight non-autoaggregating S. bovis strains by a particle agglutination assay (PAA). Twenty-three selected strains were also examined in microtiter plate assays. According to the absorbance readings (A(570nm)), 11 strains were classified as nonadherent (A(570nm) < 0.1), 10 strains as weakly adherent (0.1 < A(570nm) > 0.3), and 2 strains as strongly adherent (A(570nm) > 0.3) in these assays. A direct correlation was found between the values obtained in PAA and A(570nm) readings of microtiter plate assays. Binding of (125)I-labeled bovine lactoferrin to enterococci and streptococci was in the range of 6%-30% and of (125)I-labeled human vitronectin in the range of 9%-33% to streptococci. The binding of(125)I-labeled ECM proteins to selected strains was much more effectively inhibited by sulfated carbohydrates than by non-sulfated hyaluronic acid, indicating the importance of the sulfate groups of these inhibitors. An inhibition effect of heparin on bLf binding to four selected strains was higher in comparison with fucoidan in the microtiter plates. Thirty-five out of 44 strains had agglutinated rabbit erythrocytes. However, these strains showed no ability to agglutinate bovine or sheep erythrocytes.
Attachment of microorganisms to host cells is believed to be a critical early step in microbial pathogenesis. The aim of the study was to determine the role of the known glycosaminoglycan (GAG) binding activity of Staphylococcus aureus and coagulase-negative staphylococci (CoNS) in their attachment to six different eukaryotic cell lines. Three staphylococcal species expressing GAG binding capacity-S. aureus, S. epidermidis, and S. hemolyticus-were chosen for investigation. Six different eukaryotic cell lines, endothelial HUVEC and EA. hy 926 cells, epithelial A549 and HeLa S3 cells, fibroblasts HEL Sp 12 and macrophages J774.A1, were included. A modified ELISA with biotinylated bacteria was used for estimating the adhesion of staphylococci to each of the cell lines. Our results showed that staphylococci adhered to each of the cell lines studied, although the binding of CoNS strains to epithelial cells was lower than to the other cells. The attachment to all cell types could be partially decreased by pretreatment of the bacteria with various polysulfated agents (highest inhibition was 60%), as well as by chlorate and heparitinase treatment of the cells. These observations may suggest that at least one mode of staphylococcal attachment utilizes GAG chains present on the surface of virtually all adherent cells.
A previous study reported the ability of staphylococci to bind heparin and heparindependent host growth factors. The present study isolated and identi®ed heparin-and basic ®broblast growth factor (bFGF)-binding surface components of S. epidermidis strain RP12 and S. haemolyticus strain SM 131. The staphylococcal heparin-binding component(s) were puri®ed by af®nity chromatography on heparin-Sepharose and a major heparin-binding protein, here designated HBP, was identi®ed by immunoblot in these two coagulase-negative staphylococcal (CNS) species. The HBP was shown to be acidic with an approximate pI of 4.6 and a molecular mass around 17 kDa. The binding of heparin to HBP was inhibited by heparin, fucoidan, pentosan polysulphate and various other sulphated polysaccharides, but not by non-sulphated compounds. However, the puri®ed HBP from both S. epidermidis and S. haemolyticus revealed broad speci®city, and also bound bFGF, thrombospondin, von Willebrand factor and, weakly, ®brinogen. The N-terminal sequences of the 17-kDa HBP from S. epidermidis and S. haemolyticus showed only limited identity. Comparison of the ®rst 15 amino acid residues derived from either strain with known sequences in the protein databases revealed no close similarities. Taken together, these results suggest that the adhesion of at least some CNS to host sulphated glycosaminoglycans may be mediated by a previously uncharacterised group of surface proteins.
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