Dakar and S. Telaviv O-polysaccharides. Lüderitz et al. (1967) also supposed that the presence of O281 was correlated with the presence of N-galactosamine, the presence of O282 with ribose, and the
presence of O283 with rhamnose, but these conclusions were not confirmed by chemical and immunochemical studies. According to literature data (Lindberg & Le Minor, 1984; Grimont & Weill, 2007), S. enterica O28 O-antigens cross-react with antibodies against other Salmonella O-antigens. In addition, there is structural similarity with the repeating units of E. coli O-antigens (Table 2). As already IDH inhibitor review mentioned, Clark et al. (2010) reported that although S. Dakar and S. Pomona (which possess the same subfactors as S. Telaviv) belonged to the same serogroup, their O-antigen gene clusters were quite different. The conclusions of these authors that the O-polysaccharides isolated from the strains belonging to serogroup O:28 and differentiated in the presence of subfactors
O282 and O283 could be structurally different were confirmed by our previous study (Kumirska et al., 2011). Moreover, they suggested that the O-antigen gene clusters of other Salmonella serovars Small molecule library might also be heterogeneous. Comparison of the chemical structures of the cross-reacted Salmonella O-antigens (Table 2) indicates a rather slight similarity of the structures and confirms this suggestion. Another situation is observed when the structures of S. Dakar and S. Telaviv OPSs are compared with those of E. coli O71, O114 and 180/C3 O-antigens (Dmitriev et al., 1983; Urbina et al., 2005; MacLean et al., 2010). As mentioned, a close relationship between E. coli O71 and S. enterica O28 O-antigens was reported by Hu et al.
(2010). The O-antigen gene clusters of E. coli O71 and S. enterica O28 contained the same genes with a high level of similarity. The chemical structures of S. enterica O28 and E. coli O114 and 180/C3 O-antigens are also very similar, providing confirmation that E. coli and S. enterica are closely related species. Salmonella Adelaide Salmonella Mara Salmonella Thompson (O6,7) Salmonella Newport (O6,8) Salmonella Urbana Financial support was provided by a grant from the Medical University of Gdańsk, Grant No. W173, and by the Polish Ministry of Research and Higher Education in the form of grants BW/8200-5-0475-0 Amoxicillin and DS/8200-4-0085-1. “
“We have identified, cloned and characterized a formerly unknown protein from Streptomyces lividans spores. The deduced protein belongs to a novel member of the metallophosphatase superfamily and contains a phosphatase domain and predicted binding sites for divalent ions. Very close relatives are encoded in the genomic DNA of many different Streptomyces species. As the deduced related homologues diverge from other known phosphatase types, we named the protein MptS (metallophosphatase type from Streptomyces).