Vereninov Aa

Ion channels in cell proliferation and apoptotic cell death.

Cell proliferation and apoptosis are paralleled by altered regulation of ion channels that play an active part in the signaling of those fundamental cellular mechanisms. Cell proliferation must - at some time point - increase cell volume and apoptosis is typically paralleled by cell shrinkage. Cell volume changes require the participation of ion transport across the cell membrane, including appropriate activity of Cl− and K+ channels. Besides regulating cytosolic Cl− activity, osmolyte flux and, thus, cell volume, most Cl− channels allow HCO3− exit and cytosolic acidification, which inhibits cell proliferation and favors apoptosis. K+ exit through K+ channels may decrease intracellular K+ concentration, which in turn favors apoptotic cell death. K+ channel activity further maintains the cell membrane potential, a critical determinant of Ca2+ entry through Ca2+ channels. Cytosolic Ca2+ may trigger mechanisms required for cell proliferation and stimulate enzymes executing apoptosis. The switch between cell proliferation and apoptosis apparently depends on the magnitude and temporal organization of Ca2+ entry and on the functional state of the cell. Due to complex interaction with other signaling pathways, a given ion channel may play a dual role in both cell proliferation and apoptosis. Thus, specific ion channel blockers may abrogate both fundamental cellular mechanisms, depending on cell type, regulatory environment and condition of the cell. Clearly, considerable further experimental effort is required to fully understand the complex interplay between ion channels, cell proliferation and apoptosis.

Cell Volume Regulatory Ion Channels in Cell Proliferation and Cell Death

Alterations of cell volume are key events during both cell proliferation and apoptotic cell death. Cell proliferation eventually requires an increase of cell volume, and apoptosis is typically paralleled by cell shrinkage. Alterations of cell volume require the participation of ion transport across the cell membrane, including appropriate activity of Cl(-) and K(+) channels. Cl(-) channels modify cytosolic Cl(-) activity and mediate osmolyte flux, and thus influence cell volume. Most Cl(-) channels allow exit of HCO(3)(-), leading to cytosolic acidification, which in turn inhibits cell proliferation and favors apoptosis. K(+) exit through K(+) channels decreases cytosolic K(+) concentration, which may sensitize the cell for apoptotic cell death. K(+) channel activity further maintains the cell membrane potential, a critical determinant of Ca(2+) entry through Ca(2+) channels. Ca(2+) may, in addition, enter through Ca(2+)-permeable cation channels, which, in some cells, are activated by hyperosmotic shock. Increases of cytosolic Ca(2+) activity may trigger both mechanisms required for cell proliferation and mechanisms, leading to apoptosis. Thereby cell proliferation and apoptosis depend on magnitude and temporal organization of Ca(2+) entry, as well as activity of other signaling pathways. Accordingly, the same ion channels may participate in the stimulation of both cell proliferation and apoptosis. Specific ion channel blockers may thus abrogate both cellular mechanisms, depending on cell type and condition.

Ion channels and cell volume in regulation of cell proliferation and apoptotic cell death.

Cell proliferation must be accompanied by increase of cell volume and apoptosis is typically paralleled by cell shrinkage. Moreover, profound osmotic cell shrinkage may trigger apoptosis. In isotonic environment cell volume changes require the respective alterations of transport across the cell membrane. Cell proliferation is typically paralleled by activation of K(+) channels, which is required for the maintenance of the cell membrane potential, a critical determinant of Ca(2+) entry through Ca(2+) channels. The Ca(2+) entry leads to oscillations of cytosolic Ca(2+) activity which is followed by activation of Ca(2+) dependent transcription factors and by depolymerization of the actin filament network. The latter disinhibits the Na(+) H(+) exchanger and Na(+) , K(+) , 2Cl(-)cotransport thus leading to cell swelling. At some point transient activation of Cl(-) channels is required leading to transient decrease of cell volume. Apoptosis is typically paralleled by sustained activation of Cl(-) channels leading to Cl(-) , HCO-(3) and osmolyte exit. The subsequent cell shrinkage and cytosolic acidification are not counter-regulated by activation of the Na(+) /H(+) exchanger, which is inhibited and eventually degraded during apoptosis. At a later stage K(+) exit through K(+) channels decreases intracellular K(+) concentration and facilitates cell shrinkage. Sustained or excessive increase of Ca(+) triggers apoptotic cell death, typically paralleled by cell shrinkage due to activation of Ca(2+) sensitive K(+) channels. Cellular K(+) loss and cell shrinkage are supportive but not required for the induction of apoptosis. On the other hand, several studies point to a critical role of K(+) -channel inhibition in the initiation of apoptosis. Thus, alterations of K(+) channel and Ca(2+) channel activities may participate in the triggering of both, cell proliferation and apoptosis. The impact of those channels depends on magnitude and temporal organization of channel activation and on the activity of further signaling mechanisms. Accordingly, the same ion channel blockers may interfere with both, cell proliferation and apoptosis depending on cell type, regulatory environment and condition of the cell.

Potassium and Sodium Balance in U937 Cells During Apoptosis With and Without Cell Shrinkage

Staurosporine (STS) and etoposide (Eto) induced apoptosis of the human histiocytic lymphoma cells U937 were studied to determine the role of monovalent ions in apoptotic cell shrinkage. Cell shrinkage, defined as cell dehydration, was assayed by measurement of buoyant density of cells in continuous Percoll gradient. The K+ and Na+ content in cells of different density fractions was estimated by flame emission analysis. Apoptosis was evaluated by confocal microscopy and flow cytometry of acridine orange stained cells, by flow DNA cytometry and by effector caspase activity. Apoptosis of U937 cells induced by 1 µM STS for 4 h was found to be paralleled by an increase in buoyant density indicating cell shrinkage. An increase in density was accompanied by a decrease in K+ content (from 1.1 to 0.78 mmol/g protein), which exceeded the increase in Na+ content (from 0.30 to 0.34 mmol/g) and resulted in a significant decrease of the total K+ and Na+ content (from 1.4 to 1.1 mmol/g). In contrast to STS, 50 µM Eto for 4 h or 0.8-8 µM Eto for 18-24 h induced apoptosis without triggering cell shrinkage. During apoptosis of U937 cells induced by Eto the intracellular K+/Na+ ratio decreased like in the cells treated with STS, but the total K+ and Na+ content remained virtually the same due to a decrease in K+ content being nearly the same as an increase in Na+ content. Apoptotic cell dehydration correlated with the shift of the total cellular K+ and Na+ content. There was no statistically significant decrease in K+ concentration per cell water during apoptosis induced by either Eto (by 13.5%) or STS (by 8%), whereas increase in Na+ concentration per cell water was statistically significant (by 27% and 47%, respectively). The data show that apoptosis can occur without cell shrinkage-dehydration, that apoptosis with shrinkage is mostly due to a decrease in cellular K+ content, and that this decrease is not accompanied by a significant decrease of K+ concentration in cell water.

Thymocyte K + , Na + and Water Balance During Dexamethasone- and Etoposide-Induced Apoptosis

The mechanism of apoptotic cell volume decrease was studied in rat thymocytes treated with dexamethasone (Dex) or etoposide (Eto). Cell shrinkage, i.e. dehydration, was quantified by using buoyant density of the thymocytes in a continuous Percoll gradient. The K+ and Na+ content of cells from different density fractions were assayed by flame emission analysis. Apoptosis was tested by microscopy and flow cytometry of acridine orange stained cells as well as by flow DNA cytometry. Treatment of the thymocytes with 1 µM Dex for 4-5.5 h or 50 µM Eto for 5 h resulted in the appearance of a new distinct high-density cell subpopulation. The cells from this heavy subpopulation but not those with normal buoyant density had typical features of apoptosis. Apoptotic increase of cell density was accompanied by a decrease in cellular K+ content, which exceeded the simultaneous increase in cellular Na+ content. Cellular loss of K+ contributed to most of the estimated loss of cellular osmolytes, but owing to the parallel loss of cell water, the decrease in cytosolic K+ concentration was less than one third. Due to gain of Na+ and loss of cell water the cytosolic Na+ concentration in thymocytes rose following treatment with Dex (5.5 h) or Eto (5 h) by a factor of about 3.6 and 3.1, respectively.

Differential Transcription of Ion Transporters, NHE1, ATP1B1, NKCC1 in Human Peripheral Blood Lymphocytes Activated to Proliferation

This work, using RT PCR, studied expression of mRNAs encoding ion transporters, the Na/H antiporter (NHE1), the β subunit of the Na,K-ATPase pump (ATP1B1), the NaK2Cl symporter (NKCC1), and some proteins unrelated to ion transport: the serum and glucocorticoid dependent kinase (hSGK), β-actin, a glycolytic enzyme (GAPDH), and regulators of proliferation and apoptosis (p53, Bcl-2) during activation of human lymphocytes with phytohemagglutinin for 4-24 h. Within 24 hours the mRNA levels of NHE1, β-actin, Bcl-2, and p53 increased by more than 100%, the mRNA levels of ATP1B1, GAPDH, and hSGK, by about 50%, while the mRNA levels of NKCC1 decreased transiently. These results indicate a differential transcriptional control of NHE1, ATP1B1, and NKCC1 following a proliferative stimulus of human lymphocytes.

Na, K-ATPase pump in activated human lymphocytes: on the mechanisms of rapid and long-term increase in K influxes during the initiation of phytohemagglutinin-induced proliferation.

Functional expression of Na, K-ATPase pump as determined by ouabain-sensitive Rb influxes has been investigated in human peripheral blood lymphocytes, activated by phytohemagglutinin (PHA) from resting state to proliferation. It is found that a rapid twofold elevation of ouabain-sensitive Rb influx in response to PHA is followed by a long-term increase in pump activity, which precedes the DNA synthesis and is temporally related to the growth phase of mitogenic response. Unlike the early pump activation, the late enhanced pump activity is not the result of elevated cell Na content, it is inhibited by cycloheximide and requires new protein synthesis. Actinomycin D and alpha-amanitin, in doses, which suppress the PHA-induced increase in the RNA synthesis, do not abolish the elevated Rb influx until 20-24h of mitogenic activation and inhibit the late, growth-associated increase in Rb influx. It is concluded that (1) in mitogen-activated cells both short- and long-term control is involved in the enhanced pump activity, and (2) translational and transcriptional mechanisms may contribute to the long-term up-regulation of Na, K-ATPase pump during blast transformation of human lymphocytes.

Balance of unidirectional monovalent ion fluxes in cells undergoing apoptosis: why does Na+/K+ pump suppression not cause cell swelling?

Non‐technical summary  Apoptosis is a crucial mechanism for tissue maintenance and deregulation of apoptosis may lead to catastrophic consequences in humans (e.g. cancer). The present work is a first attempt to quantitatively characterize rearrangement of the monovalent ion fluxes in cells during apoptosis. An established model of apoptosis induced by staurosporine in lymphoid U937 cells is used to experimentally measure cellular Cl− content and fluxes, K+, Na+ and water content as well as ouabain‐sensitive and ‐resistant Rb+ fluxes. A mathematical model is developed to account for the unidirectional ion fluxes and water balance in a cell as a whole. A decrease in the channel permeability of the plasma membrane for Na+ proved to be crucial for preventing cell swelling due to the decrease in Na+/K+ pump activity in cells undergoing apoptosis whereas opening of the K+ and Cl− channels is not required. Supplemental Table S1 is given for easy calculating flux balance under specified conditions.

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 22Na, 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 μM, 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.

Dual Response of Human Leukemia U937 Cells to Hypertonic Shrinkage: Initial Regulatory Volume Increase (RVI) and Delayed Apoptotic Volume Decrease (AVD)

Background/Aims: Osmotic cell shrinkage is a powerful trigger of suicidal cell death or apoptosis, which is paralleled and enforced by apoptotic volume decrease (AVD). Cells counteract cell shrinkage by volume regulatory increase (RVI). The present study explored the response of human U937 cells to hypertonic solution thus elucidating the relationship between RVI and AVD. Methods: Cell water, concentration of monovalent ions and the appearance of apoptotic markers were followed for 0.5-4 h after the cells were transferred to a hypertonic medium. Intracellular water, K+, Na+, and Cl– content, ouabain-sensitive and -resistant Rb+ influxes were determined by measurement of the cell buoyant density in Percoll density gradient, flame emission analysis and 36Cl– assay, respectively. Fluorescent microscopy of live cells stained by acridine orange and ethidium bromide was used to verify apoptosis. Results: After 2-4 h incubation in hypertonic media the cell population was split into light (L) and heavy (H) fractions. According to microscopy and analysis of monovalent ions the majority of cells in the L population were healthy, while the H fractions were enriched with apoptotic cells. The density of L cells was decreasing with time, while the density of H cells was increasing, thus reflecting the opposite effects of RVI and AVD. At the same time, some of the cells were shifting from L to H fractions, indicating that apoptosis was gradually extending to cells that were previously displaying normal RVI. Conclusion: The findings suggest that apoptosis can develop in cells capable of RVI.