, 2007) Similar advances are needed in the area of

Azosp

, 2007). Similar advances are needed in the area of

Azospirillum– and other PGPR–plant interactions (Pothier et al., 2007; Van Puyvelde et al., 2011). Investigating the traits that contribute to bacterial survival under adverse conditions during inoculant production, storage, inoculation, and colonization of seeds and plants is very important. For example, it is crucial to better understand the roles of cell storage materials like PHAs (Kadouri et al., 2005; Castro-Sowinski et al., 2010), glycogen (Lerner et al., 2009a), polyphosphates, and others, and cell surface components like EPS, LPS, and surface proteins in enhanced resistance of bacteria to diverse stress conditions (e.g. salinity, desiccation, osmotic pressure, suboptimal temperature,

and more). Further Fulvestrant mouse investigation using the available mutants as reported in this review could focus on the clarification of the complex interactions between different rhizosphere features, in contributing to a successful ecological performance of A. brasilense. This knowledge could contribute with new ideas as to which traits could be improved for more efficient plant growth promotion inoculants for the benefit of agriculture. This Minireview is dedicated to the memory of Robert H. Burris and Jesus Caballero-Mellado, for their extensive contribution to the research of diazotrophic PGPR.


“Kluyverlaboratorium voor Biotechnologie, find more Delft, The Netherlands 2-Butanol has been an issue of industries in many areas, for Carnitine palmitoyltransferase II example, biofuel production (as an advanced alternate fuel), fermented beverages, and food (as taste-altering component). Thus, its source of production, the biological pathway, and the enzymes involved are of high interest. In this study, 42 different isolates of lactic acid bacteria from nine different species were screened for their capability to consume meso-2,3-butanediol and produce 2-butanol. Lactobacillus brevis was the only species that showed any production of 2-butanol. Five of ten tested isolates of L. brevis were able to convert meso-2,3-butanediol to 2-butanol in a synthetic medium (SM2). However, none of them showed the same capability in a complex medium such as MRS indicating that the ability to produce 2-butanol is subject to some kind of repression mechanism. Furthermore, by evaluating the performance of the enzymes required to convert meso-2,3-butanediol to 2-butanol, that is, the secondary alcohol dehydrogenase and the diol dehydratase, it was shown that the latter needed the presence of a substrate to be expressed. “
“DOI: 10.1111/1574-6968.

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