Whereas this finding suggests that mannosucrose might be a better

Whereas this finding suggests that mannosucrose might be a better compatible solute than trehalose, this would need experimental support. Despite trehalose

synthesis was osmoregulated in R. tropici CIAT 899, our data suggest that trehalose alone cannot account for the higher osmotolerance of this strain. Thus, osmoadaptation in R. tropici CIAT 899 (and most click here soil microorganisms) is probably a complex process involving many physiological and biochemical response mechanisms, not yet fully elucidated. Although trehalose, without doubt, participates in some way to alleviate osmotic stress, there is increasing evidence that trehalose is primarily a stress metabolite designed to ensure cell survival. In fact, trehalose synthesis in E. coli is under the selleck products control of the general stress factor σS, which is responsible for the expression of genes induced upon entry of stationary phase [38]. In S. meliloti, trehalose synthesis is under the control of the general stress factor RpoE2 [46], which is also necessary for desiccation resistance [47]. Thus, it may be possible that NaCl-induced synthesis of trehalose and mannosucrose in

the isolated soil strains are also involved in drought tolerance. This will be investigated in a future work. In this work, we showed the presence of otsA within the genome of the four studied Rhizobium strains, suggesting AZD5153 that trehalose synthesis in these strains occurs at least via OtsAB. In addition, by using [1/6-13C]mannitol as a carbon

source, we showed that in R. tropici CIAT 899 both trehalose moieties, as well as the β-glucan units, where (-)-p-Bromotetramisole Oxalate derived directly from mannitol. This finding, together with in silico analysis of rhizobial genomes, suggests that R. tropici takes up mannitol via a sorbitol/mannitol ABC transporter. Subsequently, mannitol is converted to fructose (by a mannitol 2-dehydrogenase) and the latter one into glucose, the trehalose precursor, by a xylose isomerase. In the case of mannose, the in silico analysis suggest that R. tropici incorporates it through a phosphotransferase system, yielding mannose-6-phosphate, but it cannot convert mannose-6-phosphate into fructose-6-phosphate, as it may lack the mannose-6-phosphate isomerase. This metabolic reconstruction would explain why R. tropici CIAT 899 cannot synthesize trehalose from mannose. Methods Bacterial strains and growth conditions Bacterial strains used in this study were R. gallicum bv. gallicum 8a3, R. leguminosarum bv. phaseoli 31c3, R. etli 12a3, Agrobacterium sp. 10c2 (in this work renamed as A. tumefaciens 10c2) [23, 24], and R. tropici CIAT 899T [15]. The reference strain R. tropici CIAT 899T belongs to the CIAT (International Center for Tropical Agriculture, Colombia) culture collection. It is able to form effective symbiosis with P. vulgaris and Leucaena trees [15] and to tolerate high temperature, low pH, and salinity [25, 26]. Rhizobial strains were routinely grown in complex TY medium [48] at 28°C.

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