Effect of the membrane potential on the Mg2+,ATP-dependent transport of Ca2+ across smooth muscle sarcolemma

The effect of the membrane potential (K(+)-valinomycin system) on the Mg2+, ATP-dependent transport of Ca2+ in inside-out vesicles of myometrium sarcolemma has been studied. The membrane potential was identified by using a cyanine potential-sensitive probe, diS-C3-(5). In the presence of valinomycin (5.10(-8) M) the inside-out directed K+ gradient (delta psi = -86 mV, with a negative charge inside) stimulated the initial rate of the energy-dependent accumulation of Ca2+ transfer whereas the oppositely directed K+ gradient (delta psi = +72 mV, with a positive charge inside) had no effect on this process. The K+ gradient was formed by isotonic substitution of K+ in intra- or extravesicular space for choline +. At the same time, in the absence of K+ gradient the Mg2+, ATP-dependent accumulation of Ca2+ in membrane vesicles did not depend on the chemical nature of the cations (K+ or choline+) used for isotonicity. The decrease of delta psi from 0 to -86 mV affects the initial rate of Ca2+ accumulation but not the maximal content of the accumulated cation. Preliminary dissipation of the membrane potential (delta psi = -86 mV) in Mg2(+)-free isotonic (with respect of K+ and choline+) media containing ATP and Ca2+ resulted in the inhibition of Mg2+, ATP-dependent Ca2+ transport induced by subsequent addition of Mg2+. These results indicate that the negative (intravesicular) electrical potential activates the Ca-pump of smooth muscle sarcolemma. This activation is based on the increase in the turnover number of the Ca2+ transporting system but not on its affinity for the transfer substrate. The use of the absolute reaction rates theory made it possible to establish that the Ca-pump effectuates the transport of a single positive charge in inside-out vesicles of smooth muscle plasma membranes, i.e., the energy-dependent transport of Ca2+ occurs either as a symport (with an anion (Cl-) or an antiport with a monovalent cation (K+) or a proton. It is assumed that the potential dependence of the Ca-pump in the smooth muscle plasma membrane plays a role in the realization of effects of mediators and physiologically active substances that are manifested as stimulation of the contractile response and depolarization of the sarcolemma. In is quite probable that the delta psi-dependent Ca-pump is also responsible for the maintenance of intracellular homeostasis of monovalent cations (K+, H+, Cl-) in smooth muscle tissues.     

The Phylogenetic Diversity of Aerobic Organotrophic Bacteria from the Dagang High-Temperature Oil Field

The distribution and species diversity of aerobic organotrophic bacteria in the Dagang high-temperature oil field (China), which is exploited with water-flooding, have been studied. Twenty-two strains of the most characteristic thermophilic and mesophilic aerobic organotrophic bacteria have been isolated from the oil stratum. It has been found that, in a laboratory, the mesophilic and thermophilic isolates grow in the temperature, pH, and salinity ranges characteristic of the injection well near-bottom zones or of the oil stratum, respectively, and assimilate a wide range of hydrocarbons, fatty acids, lower alcohols, and crude oil, thus exhibiting adaptation to the environment. Using comparative phylogenetic 16S rRNA analysis, the taxonomic affiliation of the isolates has been established. The aerobic microbial community includes gram-positive bacteria with a high and low G+C content of DNA, and γ and β subclasses of Proteobacteria. The thermophilic bacteria belong to the genera Geobacillus and Thermoactinomyces, and the mesophilic strains belong to the genera Bacillus, Micrococcus, Cellulomonas, Pseudomonas, and Acinetobacter. The microbial community of the oil stratum is dominated by known species of the genus Geobacillus (G. subterraneus, G. stearothermophilus, and G. thermoglucosidasius) and a novel species “Geobacillus jurassicus.” A number of novel thermophilic oil-oxidizing bacilli have been isolated.__________Translated from Mikrobiologiya, Vol. 74, No. 3, 2005, pp. 401–409.Original Russian Text Copyright © 2005 by Nazina, Sokolova, Shestakova, Grigoryan, Mikhailova, Babich, Lysenko, Tourova, Poltaraus, Qingxian Feng, Fangtian Ni, Belyaev.     

Method of simplified kinetic equation for simulating the electron kinetics in dense gases in strong electric fields

A method for calculating the electron kinetics in dense gases in strong electric fields is developed. The method differs from the forward-backward approximation proposed by Ra?zer and Shne?der for “high-energy” electrons in that it introduces the effective cosines of the scattering angles with respect to the electric force, μ⁺(?, E) and μ^?(?, E), which are different from +1 and ?1, as in the forward-backward approximation. The method was implemented numerically for atmospheric-pressure helium and molecular nitrogen for fields in the ranges 10–200 and 50–800 kV/cm, respectively. The cosines μ⁺(?, E) and μ^?(?, E), the frequency of “fatal” collisions making high-energy electrons to pass from an acceleration regime to a deceleration one, and the rate at which the electrons leave the low-energy reservoir with energies of ≤15 eV for nitrogen and of ≤20 eV for helium are calculated.     

Microbiological and production characteristics of the high-temperature Kongdian bed revealed during field trial of biotechnology for the enhancement of oil recovery

Microbiological technology for the enhancement of oil recovery based on the activation of the stratal microflora was tested in the high-temperature horizons of the Kongdian bed (60 degrees C) of the Dagang oil field (China). This biotechnology consists in the pumping of a water-air mixture and nitrogen and phosphorus mineral salts into the oil stratum through injection wells in order to stimulate the activity of the stratal microflora which produce oil-releasing metabolites. Monitoring of the physicochemical, microbiological, and production characteristics of the test site has revealed large changes in the ecosystem as a result of the application of biotechnology. The cell numbers of thermophilic hydrocarbon-oxidizing, fermentative, sulfate-reducing, and methanogenic microorganisms increased 10-10 000-fold. The rates of methanogenesis and sulfate reduction increased in the near-bottom zone of the injection wells and of some production wells. The microbial oil transformation was accompanied by the accumulation of bicarbonate ions, volatile fatty acids, and biosurfactants in the formation waters, as well as of CH4 and CO2 both in the gas phase and in the oil. Microbial metabolites promoted the additional recovery of oil. As a result of the application of biotechnology, the water content in the production liquid from the test site decreased, and the oil content increased. This allowed the recovery of more than 14000 tons of additional oil over 3.5 years.     

Syntheses and structural characterization of rhenium-bis-hydrazinopyrimidine core complexes with thiolate and Schiff base coligands

The reaction of perrhenate with 2-hydrazinopyrimidine in MeOH–HCl yields [ReCl₃(η¹-NNC₄H₃N₂H)(η²-HNNC₄H₃N₂)] (1). The analogous reaction with Na₂MoO₄ yields [MoCl₃(η¹-NNC₄H₃N₂H)(η²-HNNHC₄H₃N₂)] (1a). The reaction of 1 with pyrimidine-2-thiol and triethylamine produces [Re(η¹-C₄H₃N₂S)(η²-C₄H₃N₂S)(η¹-NNC₄H₃N₂)(η²-HNNC₄H₃N₂)] (2), while reaction of 1 with the Schiff base HSC₆H₄N=C(H)C₆H₄OH provides [Re(η³-SC₆H₄N=C(H)C₆H₄O)(η¹-NNC₄H₃N₂)(η²-HNNC₄H₃N₂)]·0.6CH₂Cl₂ (3·0.6CH₂Cl₂). The analogous hydrazinopyridine complex of the Schiff base, [Re(η³-SC₆H₄N=C(H)C₆H₄O)(η¹-NNC₅H₄N)(η²-HNNC₅H₄N)] (4), was also synthesized by reacting [ReCl₃(η¹-NNC₅H₄NH)(η²-HNNC₅H₄N)] with HSC₆H₄N=C(H)C₆H₄OH. The crystal structures of 1–4 have been determined.     

Exogenous O6-methylguanine inhibits adduct removal and sensitizes human cells to killing by the chemical carcinogen N-methyl-N'-nitro-N-nitrosoguanidine

We partially depleted the O6-methylguanine-DNA methyltransferase activity in four O6-methylguanine (O6-mGua) repair-proficient (Mer+) human cell strains with exogenous O6-mGua (2 mM for 3 h, a non-toxic regimen) and then challenged them with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). MT-partially depleted HT29 cells removed O6-mGua from DNA at about half the rate of control cells, while removal of 3-methyladenine was unaffected. In spite of partial depletion of MT, however, cell killing by MNNG in a colony-forming assay with HT29, A549, A498 or KD cells was not greatly affected. (This is in contrast to the dramatic potentiation of CNU cytotoxicity observed previously.) In an attempt to sensitize Mer+ strains to killing by MNNG, we treated cells with O6-mGua following MNNG exposure (0.4 mM for 4 days), in addition to the pre-MNNG treatment of 2 mM O6-mGua for 3 h. This sensitized KD and HT29 cells 2-fold to killing by MNNG, based on the dose at 10% survival, but did not sensitive Mer- A1336. However, post-treatment alone was as effective as combined pre- and post-treatment in sensitizing KD cells to killing. Thus, when the O6-mGua post-treatment was begun, greater than 50% of O6-mGua was already removed from cell DNA. Our findings may be accounted for by at least two schemes, one in which nonlethal O6-mGua are removed from DNA rapidly, while potentially lethal O6-mGua are repaired later. The other scheme proposes that exogenous O6-mGua increases the lethality of a non-O6-mGua lesion by reducing its repair both in Mer+ and Mer- cells. Both schemes are consistent with the hypothesis that O6-mGua may be a lethal DNA lesion in human cells.