diphtheriae KCTC3075 has been characterized (Kim et al, 2010), w

diphtheriae KCTC3075 has been characterized (Kim et al., 2010), which is the orthologue of DIP0543 C. diphtheriae NCTC check details 13129 (Fig. 4), confirming that this organism has both normal sialidase but also a reported trans-sialidase activity (Mattos-Guaraldi et al., 1998). Other data suggested that C. diphtheriae harbours sialic acid on its cell envelope (Mattos-Guaraldi

et al., 1999). This could originate from the trans-sialidase activity moving sialic acid directly from host sialoglycans onto the bacterium’s surface. Both the lack of association of the sialidase with production of the diphtheria toxin (Warren & Spearing, 1963; Moriyama & Barksdale, 1967) and the lack of a need for uptake for cell surface modification were perhaps the reason why no study has ever examined the capability of C. diphtheriae to use sialic acid as a nutrient in vivo, which this study would suggest it is capable of. While the identity of a sialidase click here in C. diphtheriae has been known for

nearly 50 years, the presence of a sialidase in C. glutamicum has not been suspected. This enzyme is not orthologous to the sialidases seen in C. diphtheriae, C. ulcerans and C. pseudotuberculosis, but rather is most similar to Arthrobacter sp. The essential nature of the ABC transporter in the same gene cluster as the sialidase (cg2935) suggests that Cg2935 is a sialidase; however, this will need experimental confirmation. This study presents the first evidence for an active transporter for Neu5Ac in an actinobacterium and increases the range of bacteria that appear to use an ABC transporter for this purpose. Other bacteria where sialic acid transporters have been characterized use tripartite ATP-independent periplasmic (TRAP) transporters (Severi et al.,

2005; Mulligan et al., 2009, 2012; Chowdhury et al., 2012), classical secondary transporters of the Morin Hydrate major facilitator superfamily (Martinez et al., 1995; Mulligan et al., 2012) or sodium solute symporter family (SSS) transporters (Severi et al., 2010), although perhaps significantly all these are Gram-negative bacteria. The only clear work on sialic acid transport in Gram-positives are from Streptococcus pneumoniae, which also uses an ABC transporter (Marion et al., 2011a, b). The reduced growth lag when cells are precultured in the presence of sialic acid suggests either the presence of a sialic acid-specific activator or the inactivation of a repressor. Given the presence of a GntR-family transcription factor in the cluster (cg2936), it is probable that the presence of Neu5Ac or one of its catabolic product acts as the ligand to cause depression of the cluster. The additional observation is that derepression by Neu5Ac is not seen in the presence of glucose, suggesting a catabolic repression-type mechanism is in operation. The mechanisms of catabolite repression are not well studied in C. glutamicum, and in many cases, different carbon sources are co-metabolized.

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