[Advenella kashmirensis subsp. methylica PK1, a facultative methylotroph from carex rhizosphere].

A strain (PK1) of facultative methylobacteria growing on methanol as a carbon and energy source was isolated from carex rhizosphere (Pamukkale National Park, Turkey). The cells were nonmotile gram-negative rods propagating by binary fission. The organism was a strict anaerobe, oxidase- and catalase-positive. Optimal growth occurred at 29°C, pH 8.0-8.5, and 0.5% NaCl; no growth occurred at 2% NaCl. The organism used the ribulose bisphosphate pathway of C1 assimilation. Predominant fatty acids were 11-octodecenoic (18:1ω7) and cis-hexadecenoic (16:1ω7c). Phosphatidylethanolamine and diphosphatidylglycerol were the dominant phospholipids. Q8 was the main ubiquinone. DNA G+C content was 55.4 mol % (mp). Sequencing of the 16S rRNA gene revealed that strain PK1 belonged to the genus Advenella with 98.8 and 99.2% similarity to the type strains A. incenata CCUG 45225T and A. kashmirensis WT001T, respectively. DNA-DNA homology of strain PK1 and A. kashmirensis WT001T was 70%. While MALDI analysis confirmed their close clusterization, RAPD analysis revealed the differences between strain PKI and other Advenella strains. Based on its geno- and phenotypic properties, the isolate PK1 was classified as A. kashmirensis subsp. methylica PK1 (VKM-B 2850 = DSM 27514), the first known methylotroph of the genus Advenella.

[Phosphate-solubilizing activity of aerobic methylobacteria].

Phosphate-solubilizing activity was found in 14 strains of plant-associated aerobic methylobacteria belonging to the genera Methylophilus, Methylobacillus, Methylovorus, Methylopila, Methylobacterium, Delftia, and Ancyclobacter. The growth of methylobacteria on medium with methanol as the carbon and energy source and insoluble tricalcium phosphate as the phosphorus source was accompanied by a decrease in pH due to the accumulation of up to 7 mM formic acid as a methanol oxidation intermediate and by release of 120-280 µM phosphate ions, which can be used by both bacteria and plants. Phosphate-solubilizing activity is a newly revealed role of methylobacteria in phytosymbiosis.

[Genetic modification of Methylobacterium extorquens G10 producer strain of polyhydroxybutyrate].

The effect of the increased copy number of polyhydroxybutyrate (PHB) biosynthesis genes in pink-pigmented methylobacterium Methylobacterium extorquens G10 on properties of the biopolymer was studied. The activity of poly-3-hydroxybutyril-synthase (PHB-synthase) was shown to increase and the molecular weight of synthesized PHB decreases twofold (150 --> 79 kDa) after insertion of extra copies of phaC and phaCAB genes into cells of the producer strain, whereas the physicochemical properties of the plastic changed insignificantly. White mutant M. extorquens G10-W with disrupted synthesis of the carotenoid pigment (defect by the crtI gene, which codes for phytoene desaturase) was established to have the same rate of growth and level of PHB accumulation as the initial strain G10. The G10-W strain is a promising producer of PHB, with decreased expenses for purification and PHB biosynthesis.

[Comparative characteristics of biosynthesis of polyhydroxybutyrate from methanol by Methylobacteria extorquens G10 and Methyloligella halotolerans C2].

The biosynthesis of polyhydroxybutyrate by Methylobacteria extorquens G10 and Methyloligella halotolerans C2 via the serine pathway of C1 metabolism was comparatively studied. Nitrogen limitation stimulated synthesis of the biopolymer in both cultures. It was shown that, despite the similarity of the pathways of methanol metabolism and those of polyhydroxybutyrate biosynthesis, the methylobacteria synthesized polymers of different molecular weights. In the case of M. extorquens G10, an increase in the content of the residual nitrogen in the culture medium was found to result in a reduction of the molecular weight of the polymer from 250 to 85 kDa, whereas M. halotolerans C2 synthesized a polymer of high molecular weight (approximately 3000 kDa) regardless of the residual content of the nitrogen source. It was established that the examined methylobacteria can utilize not only pure methanol but also a crude one, a feature that made it possible to significantly reduce the cost of the resulting polyhydroxybutyrate.

[Biosynthesis of polyhydroxybutyrate/valerate with different molecular weights during the growth of Methylobacterium extorquens G-10 on a methanol-pentanol mixture].

The influence of the concentration and time of addition of cosubstrate (pentanol) on the molecular weight (MW) of the polyhydroxybutyrate/valerate (PHBV) copolymer synthesized by Methylobacterium extorquens G-10 during cultivation in a methanol-containing medium has been studied. It was shown that an increase in the pentanol concentration to 20% in a mixture with methanol stimulated the biosynthesis of PHBV with a MW of approximately 1500 kDa and increased the content of valerate up to 50%, especially when pentanol was added to the log phase culture. High pentanol concentrations are toxic for the producer and reduce the total yield of PHBV. An MW increase to 1500 kDa lowers the melting temperature (from 172 to 162 degrees C) and the crystallinity degree (from 63 to 8%) of the biopolymer but increases its elasticity. The revealed variability of PHBV properties extends considerably the potential application areas of synthetic bioplastics.

[Aerobic methylobacteria as the basis for a biosensor for dichloromethane detection].

Cells of dichloromethane (DChM) bacteria-destructors were immobilized by sorption on different types of membranes, which were fixed on the measuring surface of a pH-sensitive field transistor. The presence of DChM in the medium (0.6-8.8 mM) led to a change in the transistor's output signal, which was determined by the appearance of H+ ions in the medium due to DChM utilization by methylobateria. Among four strains of methylobacteria--Methylobacterium dichloromethanicum DM4, Methylobacterium extorquens DM 17, Methylopila helvetica DM6, and Ancylobacter dichloromethanicus DM 16--the highest and most stable activity toward DChM degradation was observed in the strain M. dichloromethanicum DM4. Among 11 types of membranes for cell immobilization, Millipore nitrocellulose membranes and chromatographic fiber paper GF/A, which allow one to obtain stable biosensor signals for 2 weeks without a bioreceptor change, were chosen as optimal carriers.

[Surface layers of methanotrophic bacteria].

Structural and functional characteristics of the regular glycoprotein layers in prokaryotes are analyzed with a special emphasis on aerobic methanotrophic bacteria. S-layers are present at the surfaces of Methylococcus, Methylothermus, and Methylomicrobium cells. Different Methylomicrobium species either synthesize S-layers with planar (p2, p4) symmetry or form cup-shaped or conicalstructures with hexagonal (p6) symmetry. A unique, copper-binding polypeptide 'CorA'/MopE (27/45 kDa), which is coexpressed with the diheme periplasmic cytochrome c peroxidase 'CorB'/Mca (80 kDa) was found in Methylomicrobium album BG8, Methylomicrobium alcaliphilum 20Z, and Methylococcus capsulatus Bath. This tandem of the surface proteins is functionally analogous to a new siderophore, methanobactin. Importantly, no 'CorA'/MopE homologue was found in methanotrophs not forming S-layers. The role of surface proteins in copper metabolism and initial methane oxidation is discussed.

[Properties of modified amperometric biosensors based on methanol dehydrogenase and Methylobacterium nodulans cells].

The properties of amperometric biosensors based on methanol dehydrogenase (MDH), Methylobacterium nodulans cells, and the ferrocene-modified carbon paste electrode were investigated. It was shown that the addition ofhydroxyapatite (HA) to a carbon paste increased the sensitivity and operating stability of MDH biosensors. The linear range of the electrode was 0.0135-0.5 and 0.032-1.5 mM for methanol and formaldehyde, respectively. The detection limit of methanol and formaldehyde was 4.5 and 11.0 microM, respectively. The loss of activity of the electrode within 10 days of storage in the presence of 2.0 mM KCN did not exceed 12%. Cyanide (10 mM) completely inhibited the sensor responses to formaldehyde (1.0 mM), which allowed for the selective determination of methanol in the presence of formaldehyde. The biosensor based on cells exhibited lower stability and sensitivity toward methanol and formaldehyde; the sensitivity coefficients were 980 and 21 nA/mM, respectively.

[Functional analysis of the genome fragment involved in aerobic dichloromethane degradation by methylobacterium dichloromethanicum DM4].

The hypothetical genes of Methylobacterium dichloromethanicum DM4, METDI 2671 (bioD2), and METDI 2680 located within the chromosomal fragment (126 kb) associated with dichloromethane (DCM) degradation have been studied. The reverse transcription polymerase chain reaction method (RT-PCR) showed the presence of transcripts of both genes in cells grown on DCM and methanol. The mobilized suicidal vector pK18mob was used to obtain knockout mutants in these genes. The BIO mutant (with an insertion in the bioD2 gene) after cultivation on methanol was characterized by a lower growth rate on DCM compared to the wild-type DM4 strain, while the MT mutant (with an insertion in the METDI 2680 gene) did not differ from the initial strain in respect of these characteristics. The results demonstrate the involvement of the bioD2 gene in biotin biosynthesis coupled with DCM degradation.

[EDTA degradation by cells of Chelativorans oligotrophicus immobilized on a biofilter].

A biofilter based on light expanded clay aggregate (LECA) and cells of the obligate ethylenediamine tetraacetate (EDTA) destructor Chelativorans oligotrophicus LPM-4 has been developed. The culture steadily maintained a high level of EDTA monooxygenase activity of 180-200 nmol/min/mg of protein during three months. EDTA was converted completely or by 80% at initial concentrations of 0.5-0.7 or 2.0 g/l, respectively, in a 2-dm2 biofilter at a flow rate of 20 ml/h.

[Purification and characteristics of methanol dehydrogenase of Methylobacterium nodulans rhizosphere phytosymbionts].

Methanol dehydrogenase (MDG) of the facultative methylotrophic phytosymbiont Methylobacterium nodulans has been purified for the first time to an electrophoretically homogeneous state and characterized. The native protein with a molecular mass of 70 kDa consists of large (60 kDa) and small (6 kDa) subunits. The purified protein displayed a specter identical to that of pyrochinolinchinon (PCC)-containing MDGs (pI 8.7, pH optimum in the range 9-10). The enzyme was inactive in the absence of ammonium or methylamine and exhibited a wide substrate specificity with regard to C1-C2 alcohols with the highest affinity to methanol (K(M) = 70 mM), but it did not oxidize benzyl and secondary alcohols. The apparent values of K(M) to primary alcohols increased with the length of the carbonic chain. The enzyme was characterized by a high stability level even in the absence of a substrate. An immobilized enzyme was used for amperometric methanol detection.

[Degradation of the EDTA and EDTA complexes with metals by immobilized cells of Chelativorans oligotrophicus LPM-4 bacteria].

Enzymatic oxidative degradation of EDTA and EDTA complexes with metals has been investigated using immobilized cells of Chelativorans oligotrophicus LPM-4. A polarographic method, which makes it possible to register oxygen consumption by cells, has been used. For the first time, it has been indicated that the Cd-EDTA and Ni-EDTA complexes undergo degradation by the bacteria under study.

[Aerobic degradation of ethylenediaminetetraacetate (review)].

Literature data on the influence of complexing compound ethylenediaminetetraacetate (EDTA) on environmental and ecological risks related with its application were analyzed and summarized. Methods of abiotic and biotic degradation of EDTA were systemized. Special attention was paid to microbiological degradation of EDTA was paid. Data on EDTA transport and metabolism pathways in aerobic bacteria are represented. The practical aspects of application of aerobic bacteria-destructors of EDTA in ecobiotechnology were discussed.