92% for mutant, P ≤ 0 001) In-trans complementation of the Scl1

92% for mutant, P ≤ 0.001). In-trans complementation of the Scl1.41 expression in M41Δscl1-C restored the hydrophobic phenotype of the cells to WT level (hydrophobicity index Selleck Crenigacestat ~105%). In comparison, the contribution of the Scl1.1 and Scl1.28 proteins to GSK2879552 nmr surface hydrophobicity is more substantial, as evidenced by a ~21% and ~22% reduction of the hydrophobicity indices of the mutants as compared to the corresponding WT strains, respectively (P ≤ 0.001 for both). Thus, the Scl1-mediated GAS-cell surface hydrophobicity reported here may contribute to the

ability of this organism to form biofilm, as suggested for other cell surface components [12, 35]. Table 1 Cell surface hydrophobicity of GAS strains GAS Strain M-Type Actual Value† Hydrophobicity Index‡ MGAS6183 WT M41 92.6 ± .86 100 MGAS6183 Δscl1 M41 85.2 ± 2.2 **92 MGAS6183 Δscl1-C M41 98.0 ± .31 105 MGAS5005 WT M1 80.3 ± .89 100 MGAS5005 Δscl1 M1 63.3 ± 3.2 **79 MGAS6143 WT M28 94.3 ± .73 100 MGAS6143 Δscl1 M28 72.6 ± .62 **78 † Actual hydrophobicity values were calculated

based on hexadecane binding as described in Methods. Values are representative of three separate experiments Compound Library in vitro with ten replicates ± SD ‡ Hydrophobicity Index represents the ration of actual hydrophobicity value for each strain to that of the isogenic wild-type (WT) strain multiplied by 100 ** Asterisks denote a statistically significant difference of Δscl1 mutants versus WTs at P ≤ 0.001 Scl1 is sufficient to support biofilm formation in Lactococcus lactis To assess whether Scl1 expression is sufficient to confer the ability for biofilm formation, we chose to express this protein in a heterologous L. lactis system [38, 39]. The wild-type L. lactis strain MG1363 was transformed with plasmid pSL230 encoding the Scl1.41 protein [22] or with the shuttle vector pJRS525 alone. As shown in Figure 5a, PCR amplification of the Quinapyramine scl1.41 gene employing specific primers yielded no product from the WT L. lactis MG1363 (lane 1) and the MG1363::pJRS525 transformant (lane 2). A product of the expected size of 1.4 kb was amplified

from the pSL230 plasmid DNA control (lane 4,) as well as was amplified from the MG1363::pSL230 transformant (lane 3). Surface expression of Scl1.41 was confirmed by immunoblot analysis of cell-wall extracts prepared from L. lactis WT, and the MG1363::pJRS525 and MG1363::pSL230 transformants, as well as MGAS6163 (WT M41 GAS). As shown in Figure 5b, rabbit antiserum raised against purified recombinant Scl1.41 protein P176 lacking the WM region detected the corresponding immunogen (lane 1), and the homologous full length protein in cell-wall extracts of MGAS6183 (lane 5) as well as MG1363::pSL230 L. lactis transformant (lane 4). This band was absent in cell-wall extracts prepared from the WT L. lactis MG1363 (lane 2) and MG1363::pJRS525 transformant (lane 3). Expression of Scl1.41 at the cell surface was further established by flow cytometry. Rabbit anti-p176 antibodies stained Scl1.

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