cereus and GerP proteins of B cereus and B subtilis which

cereus and GerP proteins of B. cereus and B. subtilis which

are also required for proper assembly of the spore coat [71, 72]. No homolog for such genes was identified in D. hafniense DCB-2. see more Specific degradation of the spore’s peptidoglycan cortex is mediated by two enzymes, CwlJ and SleB, which require muramic-δ-lactam in peptidoglycan for their action [73, 74]. Homologous genes encoding CwlJ and SleB were identified in the genome of D. hafniense DCB-2 along with a gene coding for a membrane protein YpeB which is required for SleB insertion into the spore [74, 75]. Despite progress in the study of spore germination, little is known about the function of the receptors, signal transduction, and the mechanism of spore-coat breakdown [69, 70]. The germination system of D. hafniense DCB-2, which lacks some important gene homologs, may provide clues for understanding the missing links in other well-studied systems. selleck kinase inhibitor biofilm formation D. hafniense DCB-2 was showed to form biofilm in PCP-acclimated bioreactors [55, 76] and could also form biofilm on bead matrices under pyruvate fermentative conditions, and even more rapidly under Fe(III)-reducing conditions [25]. Under the identical Fe(III)-reducing conditions but with no added beads, cells expressed genes for type IV pilus biosynthesis (Dhaf_3547-3556) and genes

involved in the gluconeogenesis pathway including the fructose-1,6-bisphosphatase gene (Dhaf_4837). Development of microbial biofilm MX69 clinical trial encompasses attachment, microcolony formation, biofilm maturation and dispersion, a series of processes mediated by flagellae, type Decitabine IV pili, DNA, and exopolysaccharides [77, 78]. An increased production of type IV pili and exopolysaccharides would appear to contribute to faster establishment of biofilm under the Fe(III)-respiring conditions. Microcompartments A variety of bacteria utilize ethanolamine, a compound readily available from the degradation of cell membranes, as a source of carbon and/or nitrogen [79]. This process, which occurs within proteinaceous

organelles referred to as microcompartments or metabolosomes, involves cleaving ethanolamine into acetaldehyde and ammonia, and a subsequent conversion of acetaldehyde into acetyl-CoA [80]. In Salmonella typhimurium, 17 genes involved in the ethanolamine utilization constitute a eut operon [80]. All these genes were also identified in the genome of D. hafniense DCB-2 but were scattered among four operons (Dhaf_ 0363-0355, Dhaf_4859-4865, Dhaf_4890-4903, and Dhaf_4904-4908). Two genes (eutBC) encoding ethanolamine ammonia lyase which converts ethanolamine to acetaldehyde and ammonia were present in one operon (Dhaf_4859-4865), and the eutE gene encoding acetaldehyde dehydrogenase which forms acetyl-CoA was found as copies in the other three operons.

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