difficile (Levett, 1986) This study was supported in part by the

difficile (Levett, 1986). This study was supported in part by the Slovenian Research Agency Grants J4-2236 and P4-0092). We thank Dr John Pringle, SLU, for critical reading of the manuscript. “
“Flexirubins are specific polyene pigments produced by several genera of Bacteroidetes. Colonies and cell extracts of Flavobacterium johnsoniae and Flexibacter elegans have been

investigated by Raman spectroscopy to show that this fast and non-destructive technique can be used to differentiate PFT�� ic50 these pigments from carotenoids and to compare the flexirubin content of the two microorganisms. The presence or absence of certain distinguishing features in the CH combination band region at 2500–2750 cm−1 can assist in the discrimination between the two flexirubins investigated. Raman spectroscopy is thus a suitable CDK inhibitor tool not only to detect flexirubin pigments in bacterial cells, but also to further

characterize the pigments present in members of the Bacteroidetes genera that are rich in flexirubins. “
“Myxococcus xanthus has a large number of histidine kinase (HK) signal transduction proteins and many of these HKs are important for fruiting body development. Nla6S is an uncharacterized HK that lacks many of the conserved sequence motifs of typical HK proteins. In this study, we report that expression of the nla6S gene increases about sixfold during fruiting body development, that the Nla6S protein has the in vitro properties of HKs and that Nla6S is the prototype for a new family of HKs. To date, these Nla6-like HKs are found

only in fruiting members of the Cystobacterineae suborder of the myxobacteria. The myxobacterium Myxococcus xanthus has a highly social lifestyle. To obtain nutrients, gliding swarms of M. xanthus cells hunt prey bacteria and feed on them. When they are starving, M. xanthus cells initiate Lenvatinib purchase a development cycle that yields multicellular fruiting bodies containing thousands of stress-resistant spores. Because of this multicellular lifestyle, M. xanthus has developed intricate signal transduction networks that monitor cell–cell signals and signals from the environment, and respond accordingly. Myxococcus xanthus has an abundance of histidine kinase (HK) sensor proteins to monitor these signals (Goldman et al., 2006). HKs, together with response regulators (RR), form a signal relay system known as the two-component signal transduction system (TCS). In this system, the HK autophosphorylates when it detects a particular signal and transfers the phosphoryl group to the RR, which activates it (Laub & Goulian, 2007). Activated RRs then alter the appropriate cellular process, often by modulating changes in gene expression. HKs typically contain a sensor and a transmitter domain (Stewart, 2010). The amino acid sequences of sensor domains are highly variable owing to the vast diversity of signals that they detect.

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