This conserved histidyl residue

(His232) is present in L. sakei GlpK [20], and Stentz et al. [15] reported that whereas L. sakei can grow poorly on glycerol, this growth was abolished in ptsI mutants. Mannose-PTS As mentioned in the introduction, the PTS plays a central role, in both the uptake of a number of carbohydrates and regulatory mechanisms [20–22]. Encoding the general components, ptsH showed an up-regulation in MF1053 and LS 25 (1.2 and 0.9, respectively), while all the strains up-regulated ptsI (0.8-1.7). The manLMN operon encoding the EIIman complex was surprisingly strongly up-regulated during growth on ribose Pitavastatin supplier in all the strains (Table 1). By proteomic analysis, no regulation of the PTS enzymes was seen [19]. The expression of HPr and EI in L. sakei during growth on glucose or ribose was previously suggested to be constitutive [14], and in other lactobacilli, the EIIman complex was reported to be consistently highly expressed, regardless of carbohydrate source [72–74]. Notably, PEP-dependent phosphorylation of PTS sugars has been detected in ribose-grown cells, indicating that the EIIman complex is active, and since no transport and phosphorylation via EIIman occurs, the complex is phosphorylated, while it is unphosphorylated in the presence of the substrates of the EIIman complex [8, 73]. The stimulating effect exerted by small amounts

of glucose on ribose uptake in L. sakei, which has also been reported in other lactobacilli [74, 75], was suggested to be caused by dephosphorylation of the PTS proteins in the presence of glucose, as a ptsI mutant lacking EI, as well as P-His-HPr, Ruboxistaurin in vitro was shown to enhance ribose uptake [15, 16, 76]. Stentz et al. [15] observed

that a L. sakei mutant (strain RV52) resistant to 2 deoxy-D-glucose, a glucose toxic analog transported by EIIman, and thus assumed to be affected in the EIIman, did not show the same enhanced uptake [15]. It was concluded that EIIman is not involved in the PTS-mediated regulation of ribose metabolism in L. sakei. The mutation was though not reported verified by sequencing [15], and other mutations could be responsible for the observed phenotype. Alanine-glyoxylate transaminase The L. sakei EIIABman, EIICman and EIIDman show 72, 81, and 82% identity, respectively, with the same enzymes in L. casei, in which mutations rendering the EIIman complex inactive were shown to derepress rbs genes, resulting in a loss of the preferential use of glucose over ribose [75]. Furthermore, in L. pentosus, EIIman was shown to provide a strong signal to the CcpA-dependent repression pathway [73]. The hprK gene encoding HPrK/P which controls the phosphorylation state of HPr was strongly up-regulated (1.2-2.0) in all three strains. HPrK/P dephosphorylates P-Ser-HPr when the concentration of glycolytic intermediates drop, which is https://www.selleckchem.com/products/mm-102.html likely the situation during growth on ribose [20, 22, 24].