[Ultrastructural and X-ray spectral analysis of cells U-937 during apoptosis process induced by hypertony].

The results of this work concerning ultrastructural changes of U-937 cells in a state of apoptosis are largely in consistent with the same information available in the literature. However, we have got the original data on the ultrastructural changes of cell organelles and immune localization and distribution of proteasomes. It has been demonstrated that Golgi apparatus is located close to the plasma membrane in the case of apoptosis induced by incubating the cells in a hypertonic suchrose solution (200-400 mM). The fact can be considered as an indirect indication of depolymerization of cytoskeletal elements, in particular, MTs maintaining Golgi apparatus in a cell centre. In the later stages of apoptosis, the distances between Golgi cisterna are significantly increased. It can be explained by hydrolysis of golgins binding cisterna between each other. Mitochondria are not significantly changed in these cells. They have regularly disposed crista and sufficiently dense matrix with a few vacuoles. Proteasomes as rod-shaped osmiophilic particles (12 x 30 nm) have been revealed during each apoptosis stage both in nuclei and cytopl;asm of cells studied. The particles form aggregates of different densitities and sizes unlimited by membrane. It has been proposed that the particle aggregates revealed in the work are analogous to "processing bodies" or aggresomes described in the literature. They can be detected in cells under conditions of suppressed nucleus transcriptional processes in the nucleus and participate in storing and degradation of various mRNAs, RNP and proteins. The changes of intracellular contents of Na and K in a single cell during apoptosis induced by osmotic shock have been revealed using method of X-ray microanalysis. It has been demonstrated the increase in the ratio of intracellular contents Na+/K+ in the most of apoptotic cells in comparing with control cells.

[Li/Na exchange and Li active transport in human lymphoid cells U937 cultured in lithium media].

Lithium transport across the cell membrane is interesting in the light of general cell physiology and becau- se of its alteration during numerous human diseases. The mechanism of Li4 transfer has been studied mainly in erythrocytes with a slow kinetics of ion exchange and therefore under the unbalanced ion distribution. Prolife- rating cultured cells with a rapid ion exchange have not been used practically in study of Li4 transport. In pre- sent paper, the kinetics of Li4 uptake and exit as well as its balanced distribution across the plasma membrane of U937 cells were studied at minimal external Li+ concentrations and after the whole replacement of external Na+ for Li+. It has been found that a steady state Li+ distribution is attained at a high rate similar to that for Na+ and Cl- and that Li+/Na+ discrimination under the balanced ion distribution at 1-10 mM external Li+ keeps on 3 and drops to 1 following blocking of the Na,K-ATPase pump by ouabain. About of 80% of the total Li+ flux across the plasma membrane under the balanced Li+ distribution at 5 mM external Li+ accounts for the equiva- lent Li+/Li+ exchange. The most part of the Li+ flux into the cell down the electrochemical gradient is a flux through channels and its small part may account for the NC and NKCC cotransport influxes. The downhill Li+ influxes are balanced by the uphill Li+ efflux involved in Li+/Na+ exchange. The Na+ flux involved in the countertransport with the Li+ accounts for about 0.5% of the total Na+ flux across the plasma membrane. The study of Li+ transport is an important approach to understand the mechanism of the equivalent Li+/Li+/Na+/Na+ exchange because no blockers of this mode of ion transfer are known and it cannot be revealed by electrophysiological methods. Cells treated with the medium where Na+ is replaced for Li+ are recommended as an object for studying cells without the Na,K-ATPase pump and with very low intracellular Na+ and K+ concentration.

Analysis of the monovalent ion fluxes in U937 cells under the balanced ion distribution: recognition of ion transporters responsible for changes in cell ion and water balance during apoptosis.

Unidirectional (22)Na, Li(+) and Rb(+) fluxes and net fluxes of Na(+) and K(+) were measured in U937 human leukemic cells before and after induction of apoptosis by staurosporine (1 microM, 4 h) to answer the question which ion transporter(s) are responsible for changes in cell ion and water balance at apoptosis. The original version of the mathematical model of cell ion and water balance was used for analysis of the unidirectional ion fluxes under the balanced distribution of major monovalent ions across the cell membrane. The values of all major components of the Na(+) and K(+) efflux and influx, i.e. fluxes via the Na(+),K(+)-ATPase pump, Na(+) channels, K(+) channels, Na/Na exchanger and Na-Cl symport were determined. It is concluded that apoptotic cell shrinkage and changes in Na(+) and K(+) fluxes typical of apoptosis in U937 cells induced by staurosporine are caused by a complex decrease in the pump activity, Na-Cl symport and integral Na(+) channel permeability.

[Cell shrinkage during apoptosis is not obligatory. Apoptosis of U937 cells induced by staurosporine and etoposide]. / Degidratsionnoe sokrashchenie ob"ema kletok pri apoptoze--fakul'tativnyi priznak. Apoptoz kletok U937, vyzvannyi staurosporinom i étopozidom.

A study was made of apoptotic cell shrinkage, which is generally believed to be a hallmark of apoptosis. The two conventional models of apoptosis were used for examination of changes in cell water balance--one is apoptosis caused in human lymphoma cell line U937 by staurosporine, and the other by etoposide. Intracellular water was determined by measuring buoyant density of cells in continuous Percoll gradient. Apoptosis was recognized by microscopy and flow cytometry. Apoptosis caused by staurosporine (1 microM, 4 h) was found to be associated with a decrease in cell water content by almost 24%. In contrast, no decrease in cell water content was observed in U937 cells incubated with etoposide (50 microM, 4 h), in spite of the number of features suggesting the presence of apoptosis, such as the appearance of apoptotic bodies, chromatin condensation and fragmentation and disappearance of S-phase cells in DNA histogram. It is concluded that definition of apoptosis as "shrinkage-necrosis" (Kerr, 1971) needs correcting: the distinction of apoptotic cells involves the absence of swelling, rather than cell shrinkage.

[Water and ion balance in rat thymocytes under apoptosis induced with dexamethasone or etoposide. Ion-osmotic model of cell volume decrease]. / Vodnyi i ionnyi balans timotsitov krysy pri apoptoze, vyzvannom deksametazonom i étopozidom. Iono-osmoticheskaia model' umen'sheniia ob'ema kletki.

Cell ion and water balance was studied with respect to analysis of the osmotic model of apoptotic volume decrease (AVD) in rat thymocytes under dexamethasone (1 microM, 4-6 h) or etoposide (50 microM, 5 h) treatment. Intracellular water content was determined by measurement of cell buoyant density in continuous Percoll gradient, while intracellular potassium and sodium contents were determined by flame emission analysis. Apoptosis was verified by an increase in cell buoyant density, fluorescence of cells stained with Acridine orange and Ethidium bromide (flow cytometry), by changes in the cell cycle and the appearance of sub-diploid peak in the DNA histogram (flow cytometry), and by a decrease in cell size examined with light microscope. A separate fraction of dense cells with reduced size was found to appear after dexamethasone or etoposide treatment. This fraction was considered as apoptotic. An increase in buoyant density of apoptotic cells corresponded to a decrease in cell water content. In apoptotic cells vs. cells with normal buoyant density, the intracellular potassium content was lower, but sodium content was higher. The sum of potassium and sodium contents was lower in apoptotic cells. Taken into account the loss of anions, associated with the loss of cations, the bulk decrease in ions content has been sufficient to be accounted for cell volume decrease on the basis of the ion-osmotic model.

[Changes in sodium pump transport activity and Na+, K+-ATPase expression level following lymphocytes activation in humans]. / Izmenenie transportnoi aktivnosti natrievogo nasosa i urovnia ékspressii Na+, K+-ATFazy pri aktivatsii limfotsitov cheloveka.

Ouabain-inhibitable rubidium influxes, intracellular sodium content (Nai), and alpha 1-subunit abundance have been studied in human blood lymphocytes, stimulated by phytohemagglutinin (PHA) or by the phorbol 12,13-dibutyrate (PDBu), and calcium ionophore--ionomycin. It is shown that at early stages of PHA-induced activation, the Na/K pump expression (as determined by Wesrn blots of alpha 1 protein in membrane fractions of total cell lysates) does not change, and the increase in Rb influx is due to the increase in Nai and results from the enhanced transport activity of Na/K pumps present in plasma membrane. During the late stages of G0-->G1-->S transit (16-48 h), the increase in Rb influx occurs without changes in Nai, and monensin increases both Nai, and the Rb influx via the Na/K pump. To the end of the first day of mitogen activation, the alpha 1 protein content was found to increase by 5-7 times. A correlation was revealed between changes in ouabain-inhibitable Rb influxes, alpha 1 protein abundance, and the proliferation rate. It is concluded that blasttransformathion of normal human lymphocytes is accompanied by the increase in membrane-associated pool of alpha 1-subunit of Na+,K(+)-ATPase, and the enhanced activity of sodium pump during the G0-->G1-->S progression is provided by increased number of Na+,K(+)-ATPase pumps in plasma membrane.