[Modeling the Propagation of Microbial Cells and Phage Particles from the Sites of Permafrost Thawing.]

A method is proposed for integral assessment of the propagation of microbial cells and viral parti- cles during seasonal thawing of relic ice wedge layers. The results of on-site and laboratory investigation car- ried out in the upper part of permafrost exposure at Mamontova Gora (Yakutiya, Russia) are presented. To increase reliability of the results, suspensions of two microbial species and two coliphage species were intro- duced as biomarkers directly on the surface of thaing ice and in the meltwater flow. Each of the four different model biological objects was shown to possess unique parameters of movement in the meltwater flow and is able to move 132 m in 25-35 min with the water flow.

[Diversity of bacterial forms in ice wedge of the Mamontova Gora Glacial complex (central Yakutiya)].

Electron microscopic investigation of four samples of ancient ice wedge from the Pleistocene glacial complex of Mamontova Gora (Yakutiya, Russia) revealed high diversity of bacteriomorphic particles. Their structural features included the presence of electron-transparent zones, presumably inclusions containing storage compounds, and microenvironment (capsules or external sheaths). These features may be a result of adaptive strategies providing for microbial survival under permafrost conditions. Predominance of rod-shaped forms morphologically resembling coryneform actinobacteria was found. X-ray microanalysis revealed organic origin of bacteriomorphic particles. Some particles were characterized by incomplete spectra of the major biogenic elements, resulting probably from low-temperature damage to the cellular structures. Total numbers of aerobic heterotrophic bacteria determined by plating on nutrient media were comparable to the values obtained for permafrost soils and Arctic ice. Predominance of coryneform actinobacteria was observed. Abundance of these evolutionarily early groups of actinobacteria may indicate the ancient origin of the microflora of the relic frozen rocks.

[Effects of relic microorganism B. sp. on development, gaseous exchange, spontaneous motor activity, stress resistance and survival of Drosophila melanogaster].

The effect of relic microorganism B. sp., living in severe environment of Siberian permafrost during thousands and millions of years, on development and stress resistance of Drosophila melanogaster has been studied. In manipulating with such objects with practically "eternal life span", molecular carriers of the unprecedented longevity potential and possibilities of their transmission to other biological objects should primarily be addressed. Here we discuss for the first time the influence of B. sp. application on development, survival, stress resistance and the gross physiological predictors of aging rate in D. melanogaster. To establish optimal and toxic doses, wide range of B. sp. concentrations were tested (1-500 million cells of B. sp. per 1 ml of the flies feeding medium). Surprisingly, no toxic effects of B. sp. could be registered even on such a "sensitive" model as the developing larvae. In fact, the rate of development, survival and body mass gradually increased with elevation of B. sp. concentration. The gain of higher body mass within shorter periods of development could indicate enhanced anabolic and/ or declined catabolic effects of B. sp. Higher motor activity and gaseous exchange rates were observed in imagoes developed on the mediums with B. sp. application. Survival of these flies at the heat shock (30 min at 38 degrees C) and ultraviolet irradiation (60 min, 50W UV lamp) was increased, indicating elevated stress resistance, apparently due to stimulation of DNA-repair and chaperone-mediated protection of macromolecules. Further research is clearly warranted to identify more efficient anti-stress and antiaging preparations and schemes of B. sp. application on models of laboratory mammals and human cell cultures.

[Influence of permafrost microorganisms on the quality and duration of life of laboratory animals].

Microorganisms of genus Bacillus strain 3M (permafrost microorganisms--PM), allocated from the samples of permafrost soils from Mamontova Mountain (Yakutia) are influenced by the quality and duration of life of elderly mice. PMs were injected intraperitoneally to CBA mice at the age of 17 months. Motion activity, muscular force (lifting of cargo test), food instinct activity (dosed starvation test) and cellular immunity activity (reaction of delayed-type hypersensitivity in vivo) of animals have increased, and psychoemotional condition of animals has improved under influence of PM. Average duration of life has increased by 9.19%, minimal duration of life--by 41.93%, maximal duration of life--by 7.68%. Duration of survival (the remaining life after injection of microorganisms) has increased more significantly: minimal--by 141.9%, on the average--by 28.0%, maximal--by 20.4%. Mechanisms of PM influence on increase of laboratory mice duration of life up to the top specific limit through the positive influence on quality of their life are discussed.

[Relict microorganisms of cryolithozone as possible objects of gerontology].

Permafrost is widely distributed in the Northern Hemisphere, and its age reaches hundreds of thousands and millions of years. Permafrost contains alive microorganisms which are not frozen due to relatively high temperature of the environment (-2...-8 degrees C), but the microorganisms are immobilized and therefore aged probably similar to the age of permafrost. Longevity of the relict microbial cells is related obviously to their mechanism of protection against heat, radiation, free radicals and other damaging agents. A strain of Bacillus sp. was isolated from permafrost aged of about 3 million years, 16S rDNA sequence was identified and preliminary testing of bacterial culture on Drosophila melanogaster and mice was made. Immune stimulation and improvement of physical condition were observed, and that, together with the age of the microbial cells, presents the relict microorganisms as objects of gerontology.