Enantioselective lactic acid production by an Enterococcus faecium strain showing potential in agro-industrial waste bioconversion: physiological and proteomic studies.

The growing demand of biodegradable plastic polymers is increasing the industrial need of enantiospecific l-lactic acid (l-LA), the building block to produce polylactides. The most suitable industrial strategy to obtain high amounts of LA is the microbial fermentation of fruit and vegetable wastes by lactic acid bacteria (LAB). In this paper seven LAB strains from our laboratory collection, were screened for their ability to produce the highest amount of pure l-LA. A strain of Enterococcus faecium (LLAA-1) was selected and retained for further investigations. E. faecium LLAA-1 was grown in different culture media supplemented with the most abundant sugars present in agricultural wastes (i.e., glucose, fructose, cellobiose and xylose) and its ability to metabolize them to l-LA was evaluated. All tested sugars proved to be good carbon sources for the selected strain, except for xylose, which resulted in unsatisfactory biomass and LA production. Growth under aerobic conditions further stimulated l-LA production in fructose supplemented cultures with respect to anoxic-grown cultures. Proteomic profiles of E. faecium LLAA-1 grown in aerobiosis and anoxia were compared by means of two-dimensional electrophoresis followed by MALDI-TOF mass spectrometry. Seventeen proteins belonging to three main functional groups were differentially expressed: the biosynthesis of 6 proteins was up-regulated in aerobic-grown cultures while 11 proteins were biosynthesized in higher amounts in anoxia. The de novo biosynthesis of the f-subunit of alkyl hydroperoxide reductase involved in the re-oxidation of NADH seems the key element of the global re-arrangement of E. faecium LLAA-1 metabolism under aerobic conditions. An improved oxidative catabolism of proteinaceous substrates (i.e., protein hydrolisates) seems the main phenomenon allowing both higher biomass growth and improved LA production under these conditions.

High isoelectric point sub-proteome analysis of Acinetobacter radioresistens S13 reveals envelope stress responses induced by aromatic compounds.

In the present study, the high isoelectric point sub-proteome of Acinetobacter radioresistens S13 grown on aromatic compounds (benzoate or phenol) was analyzed and compared to the protein pattern, in the same pI range, of acetate-grown bacteria (control condition). Analyses concerned both soluble and membrane enriched proteomes and led to the identification of 25 proteins that were differentially expressed among the growth conditions considered: most of them were up-regulated in cells grown on aromatic compounds. Up to 17 identified proteins can be, more or less directly, related to the so called "envelope stress responses": these signal transduction pathways are activated when bacterial cells are exposed to stressing environments (e.g., heat, pH stress, organic solvents, osmotic stress) causing accumulation of misfolded/unfolded cell wall proteins into the periplasmic space. For, at least, five of these proteins (a DegP-like serine protease, a peptidyl-prolyl cis-trans isomerase, a phosphatidylserine decarboxylase, a pseudouridine synthase, and a TolB-like protein) a direct induction via either the σ(E) or the Cpx alternative signalling systems mediating envelope stress responses was previously demonstrated in Gram-negative bacteria. The proteins identified in this study include periplasmic proteases, chaperones, enzymes catalyzing peptydoglycan biogenesis, proteins involved in outer membrane integrity, cell surface properties and cellular redox homeostasis. The present study brings additional information to previous works on the acidic proteome of A. radioresistens S13, thus complementing and refining the metabolic picture of this bacterial strain during growth on aromatic compounds.