[Membranes of subcellular organelles as the source of superoxide radicals in liver ischemia]. / Membrany subkletochnykh organell kak istochnik superoksidnykh radikalov pri ishemii pecheni.

O2-generation rate (Vo2-) in microsomal, mitochondrial and nuclei liver membranes was measured by ESR method, by accumulation of stable nitroxide radicals. These Vo2- values were compared with Cu, ZnSOD and MnSOD activities after 2 hours ischemia and 24 hours reoxygenation. O2- radicals generated by electron transfer chains are concluded to damage mainly during the ischemia, but not the reoxygenation.

[Isolation and characteristics of a new strain of diploid cells from human embryonic lung tissue]. / Poluchenie i kharakteristika novogo shtamma diploidnykh kletok iz émbrional'noi tkani legkogo cheloveka.

A new strain of the embryonic human fibroblasts L-68 was obtained and thoroughly characterized. It completely met all the requirements of the International Committee on the Cells Cultures. This strain can be recommended as a substrate for production of viral vaccines, diagnostic preparations and for research purposes.

[Alkaline phosphatase activity of normal and transformed cultured human cells]. / Aktivnost' shchelochnoi fosfatazy v kul'tiviruemykh normal'nykh i transformirovannykh kletkakh cheloveka.

A study was made of the relationship between the activity of alkaline phosphatase and the proliferation of cultured human cells with different replicative potentials. It is shown that alkaline phosphatase plays a role as one of endogenic stimulators of cellular proliferation. The ageing of diploid cells is accompanied by a decrease in the enzyme activity. Maximum activity was observed during a period of logarithmic cell growth. Addition of placental alkaline phosphatase to the synchronized diploid cells stimulated DNA synthesis in the S-phase of the cell cycle. Heteroploid cells with a high growth rate possessed a 30-100 times higher alkaline phosphatase activity than in the diploid cells. Under certain conditions alkaline phosphatase may presumably function as a proteinkinase.

[Selective accumulation of alkaline phosphatase in the microsomes of human cells cultured in the G0-phase of the cell cycle]. / Izbiratel'noe nakoplenie shchelochnoi fosfatazy v mikrosomakh kul'tiviruemykh kletok cheloveka v G0-faze kletochnogo tsikla.

The subcellular distribution of alkaline phosphatase in normal and transformed cultivated human cells was investigated. The total activity of alkaline phosphatase in the transformed cells exceeds that in normal cells 10- (or more) fold and is sharply increased with a rise in the cell population density. The proliferating cells have the same specific activity of alkaline phosphatase in the mitochondrial-lysosomal and microsomal fractions. The transition of normal cells to the G0-phase of the cell cycle is accompanied by an increase in the total enzyme activity and selective accumulation of alkaline phosphatase in the microsomes. An addition of exogenous alkaline phosphatase to intact cells leads to the stimulation of DNA synthesis and to changes in cell morphology. The data obtained suggest that alkaline phosphatase can participate in the destabilization of the cytoskeleton and stimulate cell proliferation. However, in normal cells the selective accumulation of the enzyme in the membranes may hamper its biosynthesis. the activity of alkaline phosphatase thus does not reach the level sufficient for unrestricted cell growth.

[Mechanism of post-synthetic changes in glucose-6-phosphate dehydrogenase in human cells cultured in vitro]. / Mekhanizm postsinteticheskoi modifikatsii gliukozo-6- fosfatdegidrogenazy v kletkakh cheloveka, kul'tiviruemykh in vitro.

The reasons for the decreased stability of glucose-6-phosphate dehydrogenase in transformed human cells were investigated. The enzyme stability was found to be dependent on its subunit composition; the dimeric form possessed a lower stability in comparison with the tetrameric one. An addition of NADP to cell extracts which had partly lost their glucose-6-phosphate dehydrogenase activity, resulted in reactivation and stabilization of the enzyme. The constants for a forward (k1) and back (k2) reactions during stabilization are equal to 2.87 X 10(-3) and 5.77 X 10(-1) s-1, respectively. The inactivation and reactivation kinetics suggest that the enzyme destabilization may also occur inside the cells. The cells contain more than 40% of glucose-6-phosphate dehydrogenase molecules in an inactive form. A mechanism of destabilization and inactivation of glucose-6-phosphate dehydrogenase is proposed, which consists in NADP hydrolysis and enzyme decomposition to inactive monomers which are less stable to proteolysis.

[Role of alkaline phosphatase in the regulation of the stability of glucose-6-phosphate dehydrogenase from human cells cultivated in vitro]. / Rol' shchelochnoi fosfatazy v reguliatsii stabil'nosti gliukozo-6- fosfatdegidrogenazy kletok cheloveka kul'tiviruemykh in vitro.

The causes for different stability of glucose-6-phosphate dehydrogenase in two heteroploid cell strains and in the diploid cell strain of human embryo lungs were investigated. The thermostability of glucose-6-phosphate dehydrogenase was shown to be dependent on the coenzyme (NADP) concentration and to be coupled with the activity of alkaline phosphatase. In diploid and heteroploid cell extracts possessing a low alkaline phosphatase activity glucose-6-phosphate dehydrogenase reveals a high stability. In heteroploid cell extracts having a high activity of alkaline phosphatase a fast hydrolysis of NADP and a decrease of glucose-6-phosphate dehydrogenase stability are observed. Inhibition of alkaline phosphatase by levamisole prior to cell disruption does not increase the stability of glucose-6-phosphate dehydrogenase. Presumably destabilization of glucose-6-phosphate dehydrogenase mediated by alkaline phosphatase occurs in intact cells and is an essential mechanism controlling the enzyme activity.

[Stability of glucose-6-phosphate dehydrogenase in human cells cultivated in vitro]. / Izuchenie stabil'nosti gliukozo-6-fosfatderidrogenazy v kletkakh cheloveka, kul'tiviruemykh in vitro.

It was shown that the thermal stability of glucose-6-phosphate dehydrogenase in human diploid cells is much higher than in human heteroploid cell lines HeLa and T-9. The purified enzymes from human diploid cells and from HeLa and T-9 cells possess similar thermal stabilities. Mixing of T-9 extracts with the purified enzyme preparations revealed that the non-stability factors of the dehydrogenase are present in the T-9 extracts. An addition of NADP- and NADPH-containing buffers and crystalline NADP to the heteroploid cell extracts stabilizes the enzyme. The thermal stability of the enzyme from "in vitro" cultivated human cells depends on the concentration of the coenzyme. It was also demonstrated that glucose-6-phosphate dehydrogenase stability in HeLa and T-9 extracts is the same at low concentrations of the coenzyme and after addition of crystalline NADP. However, at NADP concentration of 10(-3) M the enzyme stability in HeLa and T-9 extracts is different. It is assumed that the destabilizing factors are the enzymes possessing the nucleotidases activity, which is different in various cell lines.