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Cell cycle‐dependent activity of the volume‐ and Ca<sup>2+</sup>‐activated anion currents in Ehrlich lettre ascites cells

Thomas Kjær KlausenDepartment of Biochemistry, Institute for Molecular Biology and Physiology, University of Copenhagen, Copenhagen, DenmarkAndreas BergdahlDepartment of Biochemistry, Institute for Molecular Biology and Physiology, University of Copenhagen, Copenhagen, DenmarkCharlotte HougaardNeuroSearch A/S Pederstrupvej 93B, Ballerup, DenmarkPalle ChristophersenNeuroSearch A/S Pederstrupvej 93B, Ballerup, DenmarkStine F. PedersenDepartment of Biochemistry, Institute for Molecular Biology and Physiology, University of Copenhagen, Copenhagen, DenmarkElse K. HoffmannDepartment of Biochemistry, Institute for Molecular Biology and Physiology, University of Copenhagen, Copenhagen, Denmark
2006en
ABI

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Recent evidence implicates the volume-regulated anion current (VRAC) and other anion currents in control or modulation of cell cycle progression; however, the precise involvement of anion channels in this process is unclear. Here, Cl- currents in Ehrlich Lettre Ascites (ELA) cells were monitored during cell cycle progression, under three conditions: (i) after osmotic swelling (i.e., VRAC), (ii) after an increase in the free intracellular Ca2+ concentration (i.e., the Ca2+-activated Cl- current, CaCC), and (iii) under steady-state isotonic conditions. The maximal swelling-activated VRAC current decreased in G1 and increased in early S phase, compared to that in G0. The isotonic steady-state current, which seems to be predominantly VRAC, also decreased in G1, and increased again in early S phase, to a level similar to that in G0. In contrast, the maximal CaCC current (500 nM free Ca2+ in the pipette), was unaltered from G0 to G1, but decreased in early S phase. A novel high-affinity anion channel inhibitor, the acidic di-aryl-urea NS3728, which inhibited both VRAC and CaCC, attenuated ELA cell growth, suggesting a possible mechanistic link between cell cycle progression and cell cycle-dependent changes in the capacity for conductive Cl- transport. It is suggested that in ELA cells, entrance into the S phase requires an increase in VRAC activity and/or an increased potential for regulatory volume decrease (RVD), and at the same time a decrease in CaCC magnitude.

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