Operant reflex-related neuronal activity in the tectum of the <Emphasis Type="Italic">superior colliculus</Emphasis> and mesencephalic reticular formation of the cat

We tried to answer the question to what extent neurons in the tectum of the superior colliculus (SC) of the cat and in regions of the mesencephalic reticular formation (MRF) localized more ventrally are involved in the control of movements of the limbs. The impulse activity of neurons of the above-mentioned structures was recorded in animals performing targeted operated food-procuring movements by their forelimbs (pressing the pedal). As was found, neurons with impulse reactions correlating with forelimb movements are rather numerous in the SC and adjacent MRF, and there are several groups of neurons, whose impulse responses reached their maxima within different phases of the movements. These were neurons with peaks of the discharge frequency coinciding with the target-reaching movement, with the moment of touching the pedal, with pressing the pedal, and with the development of the muscle force counteracting the forced withdrawal of the limb toward the initial position. Such specific patterns of the responses of different neurons of the SC and neighboring MRF are indicative of a rather specific involvement of the above structures in the control of forelimb movements in cats. Neirofiziologiya/Neurophysiology, Vol. 39, No. 3, pp. 245–254, May–June, 2007.     

Vitamin B<Subscript>12</Subscript>-independent strains of <Emphasis Type="Italic">Methylophaga marina</Emphasis> isolated from Red Sea algae

Two strains (KM3 and KM5) of halophilic methylobacteria isolated from Red Sea algae do not require vitamin B₁₂ for growth and can use methanol, methylamine, dimethylamine, trimethylamine, dimethyl sulfide, and fructose as sources of carbon and energy. The cells of these strains are gram-negative motile monotrichous (strain KM3) or peritrichous (strain KM5) rods. The strains are strictly aerobic and require Na⁺ ions but not growth factors. They are oxidase-and catalase-positive and reduce nitrates to nitrites. Both strains can grow in a temperature range of 4 to 37°C (with optimal growth at 29–34°C), at pH between 5.5 and 8.5 (with optimal growth at pH 7.5–8.0), and in a range of salt concentrations between 0.5 and 15% NaCl (with optimal growth at 5–9% NaCl). The phospholipids of these strains are dominated by phosphatidylethanolamine and phosphatidylglycerol and also include phosphatidylcholine, phosphatidylserine, and cardiolipin. The dominant fatty acids are C_16:1ω7c and C_16:0. The major ubiquinone is Q₈. The cells accumulate ectoin, glutamate, and sucrose as intracellular osmoprotectants. The strains implement the 2-keto-3-deoxy-6-phosphogluconate-dependent variant of the ribulose monophosphate pathway. The G+C content of the DNA is 44.4–44.7 mol%. Analysis of the 16S rRNA genes showed that both strains belong to Gammaproteobacteria and have a high degree of homology (99.4%) to Methylophaga marina ATCC 35842^T. Based on the data of polyphasic taxonomy, isolates KM3 and KM5 are identified as new strains M. marina KM3 (VKM B-2386) and M. marina KM5 (VKM B-2387). The ability of these strains to produce auxins (indole-3-acetic acid) suggests their metabolic association with marine algae.     

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.     

The influence of myo-inositol on the ultrastructure of hippocampal CA1 area in kainate treated rats

The ultrastructure of neurons, synapses and astrocytes of hippocampal CA1 area in rats was investigated 14 days after: systemic injection of kainic acid and kainic acid and myo-Inositol. After injection of kainic acid numerous neurons with superficial and deep ultrastructural changes of cytoplasmic organelles were described. Among synapses numerous forms with osmiophilic active zone and single synaptic vesicles, also presynaptic terminals with core vesicles were often seen. After kainic acid + myo-Inositol injection the cells with superficial changes of organelles dominated and the synapsoarchitectonics of the area was close to normal. Thus, electrono-microscopic data indicate possible neuroprotective (antiepileptic?) features of myo-Inositol.     

Substrate phase state and time factor in variability of human fecal microbiota

Effects of substrate phase state and time factor on variability of human fecal microbiota were studied. It was shown that microecological system of native feces was characterized by marked time-dependent variability. It is unstable and begins to destruct after 24 hours of cultivation. The most sensitive elements of the system were bifidobacteria and Escherichia coli. Change of phase state of biotope eliminated the effect of factor limiting the microecosystem development, which allowed species of obligate and transitory microflora to freely colonize the growth substrate and interact with each other. The mentioned facts demonstrate that fecal microbiota exists in the environment of excess of growth substrate, which colonization is limited by cluster structure of biotope of native feces. It was concluded that phase state of growth substrate and duration of cultivation are important factors determining the population variability of fecal microbiota.     

Prospects for the Use of Metal Nanoparticles and Chitosan Nanomaterials with Metals to Combat Phytopathogens

Applied Biochemistry and Microbiology - The review considers the prospects for the use of chitosan nanoforms with metals to combat phytopathogens. Nanoparticles of metals and metal oxides exhibit...     

Methylophaga murata sp. nov.: a haloalkaliphilic aerobic methylotroph from deteriorating marble

The haloalkaliphilic methylotrophic bacterium (strain Kr3) isolated from material scraped off the deteriorating marble of the Moscow Kremlin masonry has been found to be able to utilize methanol, methylamine, trimethylamine, and fructose as carbon and energy sources. Its cells are gram-negative motile rods multiplying by binary fission. Spores are not produced. The isolate is strictly aerobic and requires vitamin B12 and Na+ ions for growth. It is oxidase- and catalase-positive and reduces nitrates to nitrites. Growth occurs at temperatures between 0 and 42 degrees C (with the optimum temperatures being 20-32 degrees C), pH values between 6 and 11 (with the optimum at 8-9), and NaCl concentrations between 0.05 and 3 M (with the optimum at 0.5-1.5 M). The dominant cellular phospholipids are phosphatidylethanolamine, phosphatidylglycerol, and cardiolipin. The major cellular fatty acids are palmitic (C16:0), palmitoleic (C16:1), and octadecenoic (C18:1) acids. The major ubiquinone is Q8. The isolate accumulates ectoine and glutamate, as well as a certain amount of sucrose, to function as osmoprotectants and synthesizes an exopolysaccharide composed of carbohydrate and protein components. It is resistant to heating at 70 degrees C, freezing, and drying; utilizes methanol, with the resulting production of formic acid, which is responsible for the marble-degrading activity of the isolate; and implements the 2-keto-3-deoxy-6-phosphogluconate variant of the ribulose monophosphate pathway. The G+C content of its DNA is 44.6 mol%. Based on 16S rRNA gene sequencing and DNA-DNA homology levels (23-41%) with neutrophilic and alkaliphilic methylobacteria from the genus Methylophaga, the isolate has been identified as a new species, Methylophaga murata (VKM B-2303T = NCIMB 13993T).     

Tissue Specificity of Alternative Splicing of Transcripts Encoding Hampin,a New Mouse Protein Homologous to the <Emphasis Type="Italic">Drosophila</Emphasis> MSL-1 Protein

A number of mammalian genomes have one gene copy encoding the protein that we named hampin. A search in a number of databases revealed a distant homologue, the well-known Drosophila protein MSL-1 (male-specific lethal 1). An alternative splicing of mRNA led to a significant diversity of structural hampin variants with different domain compositions. We analyzed the tissue-specific expression of five mouse hampin variants using RT-PCR. Two variants encoding hampin proteins with truncated N termini were shown to have a restricted tissue specificity: they are exclusively expressed in the testes. The mRNAs of other hampin variants were detected in all the tested tissues at comparable levels. We obtained polyclonal antibodies to the recombinant hampin and used them to demonstrate that at least one of the variants is predominantly localized in the nucleus. The specific features of the hampin primary structure and its possible functions as a member of the hampin/MSL-1 family of proteins are discussed.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 4, 2005, pp. 363–371.Original Russian Text Copyright © 2005 by Dmitriev, Pestov, Korneenko, Gerasimova, Zhao, Modyanov, Kostina, Shakhparonov.The article was translated by the authors.