Early-phase occurrence of K+ and Cl- efflux in addition to Ca 2+ mobilization is a prerequisite to apoptosis in HeLa cells.

Sustained rise in cytosolic Ca(2+) and cell shrinkage mainly caused by K(+) and Cl(-) efflux are known to be prerequisites to apoptotic cell death. Here, we investigated how the efflux of K(+) and Cl(-) as well as the rise in cytosolic Ca(2+) occur prior to caspase activation and are coupled to each other in apoptotic human epithelial HeLa cells. Caspase-3 activation and DNA laddering induced by staurosporine were abolished by blockers of K(+) and Cl(-) channels or cytosolic Ca(2+) chelation. Staurosporine induced decreases in the intracellular free K(+) and Cl(-) concentrations ([K(+)](i) and [Cl(-)](i)) in an early stage prior to caspase-3 activation. Staurosporine also induced a long-lasting rise in the cytosolic free Ca(2+) concentration. The early-phase decreases in [K(+)](i) and [Cl(-)](i) were completely prevented by a blocker of K(+) or Cl(-) channel, but were not affected by cytosolic Ca(2+) chelation. By contrast, the Ca(2+) response was abolished by a blocker of K(+) or Cl(-) channel. Strong hypertonic stress promptly induced a cytosolic Ca(2+) increase lasting >50 min together with sustained shrinkage and thereafter caspase-3 activation after 4 h. The hypertonic stress induced slight increases in [K(+)](i) and [Cl(-)](i) in the first 50 min, but these increases were much less than the effect of shrinkage-induced condensation, indicating that K(+) and Cl(-) efflux took place. Hypertonicity induced caspase-3 activation that was prevented not only by cytosolic Ca(2+) chelation but also by K(+) and Cl(-) channel blockers. Thus, it is concluded that not only Ca(2+) mobilization but early-phase efflux of K(+) and Cl(-) are required for caspase activation, and Ca(2+) mobilization is a downstream and resultant event of cell shrinkage in both staurosporine- and hypertonicity-induced apoptosis.

Apoptotic Volume Decrease (AVD) Is Independent of Mitochondrial Dysfunction and Initiator Caspase Activation.

Persistent cell shrinkage is a major hallmark of apoptotic cell death. The early-phase shrinkage, which starts within 30-120 min after apoptotic stimulation and is called apoptotic volume decrease (AVD), is known to be accomplished by activation of K+ channels and volume-sensitive outwardly rectifying (VSOR) Cl- channels in a manner independent of caspase-3 activation. However, it is controversial whether AVD depends on apoptotic dysfunction of mitochondria and activation of initiator caspases. Here, we observed that AVD is induced not only by a mitochondrial apoptosis inducer, staurosporine (STS), in mouse B lymphoma WEHI-231 cells, but also by ligation of the death receptor Fas in human B lymphoblastoid SKW6.4 cells, which undergo Fas-mediated apoptosis without involving mitochondria. Overexpression of Bcl-2 failed to inhibit the STS-induced AVD in WEHI-231 cells. These results indicate that AVD does not require the mitochondrial pathway of apoptosis. In human epithelial HeLa cells stimulated with anti-Fas antibody or STS, the AVD induction was found to precede activation of caspase-8 and caspase-9 and to be resistant to pan-caspase blockers. Thus, it is concluded that the AVD induction is an early event independent of the mitochondrial apoptotic signaling pathway and initiator caspase activation.

MiR-107 and MiR-185 can induce cell cycle arrest in human non small cell lung cancer cell lines.

BACKGROUND: MicroRNAs (miRNAs) are short single stranded noncoding RNAs that suppress gene expression through either translational repression or degradation of target mRNAs. The annealing between messenger RNAs and 5' seed region of miRNAs is believed to be essential for the specific suppression of target gene expression. One miRNA can have several hundred different targets in a cell. Rapidly accumulating evidence suggests that many miRNAs are involved in cell cycle regulation and consequentially play critical roles in carcinogenesis. METHODOLOGY/PRINCIPAL FINDINGS: Introduction of synthetic miR-107 or miR-185 suppressed growth of the human non-small cell lung cancer cell lines. Flow cytometry analysis revealed these miRNAs induce a G1 cell cycle arrest in H1299 cells and the suppression of cell cycle progression is stronger than that by Let-7 miRNA. By the gene expression analyses with oligonucleotide microarrays, we find hundreds of genes are affected by transfection of these miRNAs. Using miRNA-target prediction analyses and the array data, we listed up a set of likely targets of miR-107 and miR-185 for G1 cell cycle arrest and validate a subset of them using real-time RT-PCR and immunoblotting for CDK6. CONCLUSIONS/SIGNIFICANCE: We identified new cell cycle regulating miRNAs, miR-107 and miR-185, localized in frequently altered chromosomal regions in human lung cancers. Especially for miR-107, a large number of down-regulated genes are annotated with the gene ontology term 'cell cycle'. Our results suggest that these miRNAs may contribute to regulate cell cycle in human malignant tumors.

Prerequisite role of persistent cell shrinkage in apoptosis of human epithelial cells.

Persistent cell volume reduction is a major hallmark of apoptosis. Recent studies have demonstrated that cell volume reduction is not a passive, secondary event of the apoptotic cell death process. Whole-cell shrinkage, termed apoptotic volume decrease (AVD), takes place soon after stimulation with apoptogen and precedes caspase activation, DNA and cell fragmentation in a variety of cell types including human epithelial cells. The AVD induction is the result of KCl efflux attained by activation of K(+) and Cl(-) channels. Inhibition of AVD induction leads to rescue of the cells from apoptosis. Since the AVD process is coupled to dysfunction of the regulatory volume increase (RVI), apoptotic cells undergo persistent cell shrinkage in human epithelial HeLa cells. When the RVI mechanism was impaired, hypertonic stress itself induced not only persistent cell shrinkage but also apoptotic cell death in HeLa cells. Even under normotonic apoptogen-free conditions, exposure of HeLa cells to Na(+)- or Cl(-)-deficient solution alone can bring about persistent cell shrinkage and thereafter apoptotic cell death. Thus, it is concluded that persistent cell shrinkage, which comprises AVD induction and RVI dysfunction, is a prerequisite to apoptosis induction in human epithelial cells.

Dysfunction of regulatory volume increase is a key component of apoptosis.

Sustained cell shrinkage is a major hallmark of apoptotic cell death. In apoptotic cells, whole cell volume reduction, called apoptotic volume decrease (AVD), proceeds until fragmentation of cells. Under non-apoptotic conditions, human epithelial HeLa cells exhibited a slow regulatory volume increase (RVI) after osmotic shrinkage induced by exposure to hypertonic solution. When AVD was induced by treatment with a Fas ligand, TNF-alpha or staurosporine, however, it was found that HeLa cells failed to undergo RVI. When RVI was inhibited by combined application of Na+/H+ exchanger (NHE) and anion exchanger blockers, hypertonic stress induced prolonged shrinkage followed by caspase-3 activation in HeLa cells. Hypertonicity also induced apoptosis in NHE1-deficient PS120 fibroblasts, which lack the RVI response. When RVI was restored by transfection of these cells with NHE1, hypertonicity-induced apoptosis was completely prevented. Thus, it is concluded that RVI dysfunction is indispensable for the persistence of AVD and induction of apoptosis.

Dual roles of plasmalemmal chloride channels in induction of cell death.

Even under anisotonic conditions, most cells can regulate their volume by mechanisms called regulatory volume decrease (RVD) and increase (RVI) after osmotic swelling or shrinkage, respectively. In contrast, the initial processes of necrosis and apoptosis are associated with persistent swelling and shrinkage. Necrotic volume increase (NVI) is initiated by uptake of osmolytes, such as Na+, Cl- and lactate, under conditions of injury, hypoxia, ischaemia, acidosis or lactacidosis. Persistence of NVI is caused by dysfunction of RVD due to impairment of volume-sensitive Cl- channels under conditions of ATP deficiency or lactacidosis. Both lactacidosis-induced RVD dysfunction and necrotic cell death are prevented by pretreatment of cells with the vacuolating cytotoxin-A (VacA) toxin protein purified from Helicobacter pylori, which forms a lactacidosis-resistant anion channel. Apoptotic volume decrease (AVD) is triggered by activation of K+ and Cl- conductances following stimulation with a mitochondrion-mediated or death receptor-mediated apoptosis inducer. Apoptotic cell death can be prevented by blocking the Cl- channels but not the K+-Cl- cotransporters. Thus, the volume regulatory anion channel plays, unless impaired, a cell-rescuing role in the necrotic process by ensuring RVD after swelling induced by necrotic insults, whereas normotonic activation of the anion channel plays a cell-killing role in the apoptotic process by triggering AVD following stimulation with apoptosis inducers.

Cell culture in a closed nano-space.

The minimum size of a closed nano-space in which cells can survive was determined using 4-nl nanowells. One or two cells could divide in the nanowell. Our results suggest that the cell division activity in the nano-space is determined by the conflict between intercellular effects and consumption of substrates.

LTRPC2 Ca2+-permeable channel activated by changes in redox status confers susceptibility to cell death.

Redox status changes exert critical impacts on necrotic/apoptotic and normal cellular processes. We report here a widely expressed Ca2+-permeable cation channel, LTRPC2, activated by micromolar levels of H2O2 and agents that produce reactive oxygen/nitrogen species. This sensitivity of LTRPC2 to redox state modifiers was attributable to an agonistic binding of nicotinamide adenine dinucleotide (beta-NAD+) to the MutT motif. Arachidonic acid and Ca2+ were important positive regulators for LTRPC2. Heterologous LTRPC2 expression conferred susceptibility to death on HEK cells. Antisense oligonucleotide experiments revealed physiological involvement of "native" LTRPC2 in H2O2- and TNFalpha-induced Ca2+ influx and cell death. Thus, LTRPC2 represents an important intrinsic mechanism that mediates Ca2+ and Na+ overload in response to disturbance of redox state in cell death.