Prikladnaia biokhimiia i mikrobiologiia最新文献

Closely related penta- and octaheme nitrite reductases catalyze the reduction of nitrite, nitric oxide, and hydroxylamine to ammonium and of sulfite to sulfide. NrfA pentaheme nitrite reductase plays the key role in anaerobic nitrate respiration and the protection of bacterial cells from stresses caused by nitrogen oxides and hydrogen peroxide. Octaheme nitrite reductases from bacteria of the Thioalkalivibrio genus are less studied, and their function in the cell is unknown. In order to estimate the possible role of octaheme nitrite reductases in the cell resistance to oxidative stress, the peroxidase activity of the enzyme from T. nitratireducens (TvNiR) has been studied in detail. Comparative analysis of the active site structure of TvNiR and cytochrome c peroxidases has shown some common features, such as a five-coordinated catalytic heme and identical catalytic residues in active sites. A model of the possible productive binding of peroxide at the active site of TvNiR has been proposed. The peroxidase activity has been measured for TvNiR hexamers and trimers under different conditions (pH, buffers, the addition of CaCl2 and EDTA). The maximum peroxidase activity of TvNiR with ABTS as a substrate (k cat = 17 s–1; k cat/K m = 855 mM–1 s–1) has been 100–300 times lower than the activity of natural peroxidases. The different activities of TvNiR trimers and hexamers indicate that the rate-limiting stage of the reaction is not the catalytic event at the active site but the electron transfer along the heme c electron-transport chain.

The kinetics of oxidation reactions of flavonoids, quercetin, dihydroquercetin, and epicatechin has been studied in the presence of biocatalysts of different natures: horseradish peroxidase, mushroom tyrosinase, and hemoglobin from bull blood. Comparison of the kinetic parameters of the oxidation reaction showed that peroxidase appeared to be the most effective biocatalyst in these processes. The specificity of the enzyme for quercetin increased with increasing the polarity of the solvent in a series of ethanol–acetonitrile–dimethyl sulfoxide.

A knockout mutant of Methylobacterium dichloromethanicum DM4 with an inactivated gene of a putative transcription regulator METDI5511 (ΔMETDI5511) has been obtained. The expression of this gene increases many times when the strain is grown on dichloromethane compared to methanol. The mutant had a low growth rate on dichloromethane as compared with the original strain and was found to be more sensitive to influences of various types of stress (oxidative, osmotic stress, heat, and drying). The cells were stained with Fluorescent Brightener 28 (Calcofluor white), and the intensity of their fluorescence showed that the ΔMETDI5511 mutant had significantly increased numbers of surface polysaccharides with β-1,3 and β-1,4-glycoside bonds. The results indicate that the METDI5511 gene is involved in the regulation of surface polysaccharides that play an important role in adaptation of cells to growth on dichloromethane.

The article concerns converting waste from vegetable processing facilities into methane in anaerobic reactors with a small amount of inoculum (8.4%). Anaerobic digestion of vegetable waste with a high content of organic acids and carbohydrates makes it possible to achieve a methanogenesis productivity of 273–436 L CH4/kg of volatile solidis, which is comparable to or higher than the productivity of such reactors in the world (according to the literature). The contents of ammonia nitrogen and soluble phosphorus in the form of on undiluted substrate basis in the digested vegetable wastes ranged from 3.39 to 5.06 and from 0.78 to 1.03 g/L respectively. Thus, mineralized vegetable waste can be used as an organic fertilizer with a high nutrient content. The results show the feasibility of the technology of conversion of organic waste from vegetable processing facilities into methane and organic fertilizer in anaerobic fermenters (digesters).

The bacterial strain IB-1, which exhibits antagonism towards phytopathogens and stimulates the growth of agricultural plants, was isolated from the soil. Analysis of the cultural, morphological, physiological, and biochemical features and nucleotide sequences of the genes 16S rRNA and gyrB, as well as the fatty acid composition, made it possible to attribute the strain IB-1 to the genus Paenibacillus; however, the results did not provide an unambiguous conclusion on its species. The strain Paenibacillus sp. IB-1 possesses nitrogenase activity, the ability to synthesize indoleacetic acid and cytokinin-like compounds, and antagonistic activity towards phytopathogenic fungi, which indicates prospects for its use as a biological product for agricultural purposes. A high-viscous exopolysaccharide was isolated from the cultural fluid of Paenibacillus sp. IB-1. Based on the data from IR and NMR spectroscopy, it was shown to be a heteropolymer comprised of one to four linked α-L-guluronic acid and β-D-mannuronic acid residues. The exopolysaccharide was successfully tested as an adhesive for presowing treatment of barley and wheat seeds with biofungicides.

Recent studies of the immune system of leguminous plants infected with nodular bacteria (rhizobia) are summarized. The possibility of blocking the invasion of rhizobia into plant organs not affected by the primary infection is discussed. The concept of local and systemic resistance of the leguminous plant to rhizobial infection is introduced. The Nod factors of rhizobia are considered, as well as the plant receptors that interact with these factors upon the formation of symbiosis of the plant and bacteria. The role of bacterial surface exopolysaccharides in the suppression of the protective system of the plants is discussed. The innate immunity of leguminous plant cells is assumed to affect the formation and functioning of the symbiosis of the plant and the bacteria.

The maximal rates and effective constants of 2,6-dichlorphenolindophenol and oxygen reduction by bacterim Gluconobacter oxydans in bacterial fuel cells under different conditions were evaluated. In an open-circuit mode, the rate of 2,6-dichlorphenolindophenol reduction coupled with ethanol oxidation under oxygen and nirogen atmospheres were 1.0 and 1.1 μM s–1 g–1, respectively. In closed-circuit mode, these values were 0.4 and 0.44 μM s–1 g–1, respectively. The initial rate of mediator reduction with the use of membrane fractions of bacteria in oxygen and nitrogen atmospheres in open-circuit mode were 6.3 and 6.9 μM s–1 g–1, whereas these values in closed-circuit mode comprised 2.2 and 2.4 μM s–1 g–1, respectively. The oxygen reduction rates in the presence and absence of 2,6-dichlorphenolindophenol were 0.31 and 0.32 μM s–1 g–1, respectively. The data obtained in this work demonstrated independent electron transfer from bacterial redox centers to the mediator and the absence of competition between the redox mediator and oxygen. The results can make it possible to reduce costs of microbial fuel cells based on activity of acetic acid bacteria G. oxydans.

A method has been developed for the quantitative estimation of the binding force of a model microsphere with a eukaryocyte based on the optical trap in order to study the molecular mechanism of adhesion between an individual bacterium and a host cell. The substantial role of LPS O-side chains in the adhesiveness of Yersinia pseudotuberculosis 1b to J774 macrophages has been revealed with the use of a set of microspheres functionalized with lipopolysaccharide (LPS) preparations and antibodies with different specificities. The results indicate the significance of the O-antigen as a pathogenicity factor of Y. pseudotuberculosis in colonization of a macroorganism. The developed methodical approaches can be applied to the study of molecular mechanisms of the pathogenesis of pseudotuberculosis and other infectious diseases to improve antiepidemic service.

The biosynthesis of L-lactate oxidase in the Yarrowia lipolytica yeast during submerged cultivation in laboratory bioreactors ANKUM-2M has been studied. It has been shown under optimal conditions of yeast cultivation with L-lactate that 24.5 U/L enzyme accumulated in the medium and the yield was 2.0 U/(L h). An increase in the biosynthesis of L-lactate oxidase to 75 U/L and the yield to 3.2 U/(L h) was achieved in the medium with L-lactate (1%) and glucose (2%). The enzyme was purified 251 times to homogeneity by hydrophobic and ion exchange chromatography state with a yield of 45% and a specific activity of 55.3 U/mg. Techniques of gel filtration and denaturing electrophoresis showed that L-lactate oxidase from Y. lipolytica is a tetramer with a molecular mass of 200–230 kDa. The enzyme showed a strict specificity to L-lactate and did not oxidize fumarate, pyruvate, succinate, ascorbate, dihydroxyacetone, glycolate, D-lactate, D, L-2-hydroxybutyrate and D, L-alanine or D-serine.

A change in the contents of endogenous salicylic and jasmonic acids in the roots of the host plant at the preinfectious stage of interaction with symbiotic (Rhizobium leguminosarum) and pathogenic (Agrobacterium rizogenes) bacteria belonging for to the family Rhizobiaceae was studied. It was found that the jasmonic acid content increased 1.5–2 times 5 min after inoculation with these bacterial species. It was shown that dynamics of the change in the JA and SA contents depends on the type of infection. Thus, the JA content decreased in the case of pathogenesis, while the SA content increased. At the same time, an increased JA content was observed during symbiosis. The observed regularities could indicate the presence of different strategies of hormonal regulation for interaction with symbiotic and pathogenic bacteria belonging to the family Rhizobiaceae in peas plants.