SUMMARY1. Individual cells were isolated from the sino-atrial node area of the rabbit heart using an enzyme medium containing collagenase and elastase. After enzymatic treatment the cells were placed in normal Tyrode solution, where beating resumed in a fraction of them.2. Isolated cells were studied in the whole cell configuration. Action potentials as well as membrane currents under voltage-clamp conditions were similar to those in multicellular preparations.3. Pulses to voltages more negative than about -50 mV caused activation of the hyperpolarizing-activated current, if. Investigation of the properties of this current was carried out under conditions that limited the influence of other current systems during voltage clamp.4. The if current activation range usually extended approximately from -50 to -100 mV, but varied from cell to cell. In several cases, pulsing to the region of -40 mV elicited a sizeable if. Both current activation and deactivation during voltage steps had S-shaped time courses. A high variability was however observed in the sigmoidal behaviour of if kinetics. 5. Plots of the fully-activated current-voltage (I-V) relation in different extracellular Na and K concentrations showed that both ions carry the current if. While changes in the external Na concentration caused the current I-V relation to undergo simple shifts along the voltage axis, changes in extracellular K concentration were also associated with changes in its slope. Again, a large variability was observed in the increase of I-V slope on raising the external K concentration.6. The current if was strongly depressed by Cs, and the block induced by 5 mM-Cs was markedly voltage dependent.
Most proteins adopt a well defined three-dimensional structure; however, it is increasingly recognized that some proteins can exist with at least two stable conformations. Recently, a class of intracellular chloride ion channel proteins (CLICs) has been shown to exist in both soluble and integral membrane forms. The structure of the soluble form of CLIC1 is typical of a soluble glutathione S-transferase superfamily protein but contains a glutaredoxin-like active site. In this study we show that on oxidation CLIC1 undergoes a reversible transition from a monomeric to a non-covalent dimeric state due to the formation of an intramolecular disulfide bond (Cys-24 -Cys-59). We have determined the crystal structure of this oxidized state and show that a major structural transition has occurred, exposing a large hydrophobic surface, which forms the dimer interface. The oxidized CLIC1 dimer maintains its ability to form chloride ion channels in artificial bilayers and vesicles, whereas a reducing environment prevents the formation of ion channels by CLIC1. Mutational studies show that both Cys-24 and Cys-59 are required for channel activity.Chloride ion channels control a variety of cellular processes that are central to normal function and disease states (1). The CLIC 1 family is a recently identified class of Cl Ϫ channel proteins that consists of seven members (p64, parchorin, CLIC1-5) (2, 3). A conserved C-terminal CLIC module of ϳ240 amino acids is present in each member of the family with several members containing additional, unrelated Nterminal domains. Most CLICs are localized to intracellular membranes and have been linked to functions including apoptosis, pH, and cell cycle regulation (4 -6). The CLIC ion channels are unusual in that they possess both soluble and integral membrane forms (2). In this regard they are similar to some bacterial toxins and several classes of intracellular proteins including Bcl-x L and the annexins (7). Our understanding of how such dual natured proteins enter the membrane is limited by the dearth of high resolution structures for key states in this process.We have recently determined the crystal structure of a soluble monomeric form of CLIC1 (8) and found that it is a structural homologue of the GST superfamily of proteins (9). This soluble form of CLIC1 consists of two domains, the N-domain possessing a thioredoxin fold closely resembling glutaredoxin and an all ␣-helical C-domain, which is typical of the GST superfamily. CLIC1 contains an intact glutathione-binding site that was shown to covalently bind glutathione via a conserved CLIC cysteine residue, Cys-24. This led to the suggestion that CLIC1 function may be under redox control, possibly via reactive oxygen or nitrogen species.The structure and stoichiometry of the integral membrane form of the CLIC proteins is still unclear. Electrophysiology of purified, soluble (Escherichia coli-expressed) recombinant CLIC1 in reconstituted artificial bilayers shows that CLIC1 alone is sufficient for chloride ion channel formation (8, 1...
CLIC1 (NCC27) is a member of the highly conserved class of chloride ion channels that exists in both soluble and integral membrane forms. Purified CLIC1 can integrate into synthetic lipid bilayers forming a chloride channel with similar properties to those observed in vivo. The structure of the soluble form of CLIC1 has been determined at 1.4-Å resolution. The protein is monomeric and structurally homologous to the glutathione S-transferase superfamily, and it has a redox-active site resembling glutaredoxin. The structure of the complex of CLIC1 with glutathione shows that glutathione occupies the redox-active site, which is adjacent to an open, elongated slot lined by basic residues. Integration of CLIC1 into the membrane is likely to require a major structural rearrangement, probably of the N-domain (residues 1-90), with the putative transmembrane helix arising from residues in the vicinity of the redox-active site. The structure indicates that CLIC1 is likely to be controlled by redox-dependent processes.Chloride ion channels, located both within the plasma membrane and other internal cell membranes (1, 2), are involved in diverse physiological processes. They are known to participate in the control of secretion and absorption of salt, regulation of membrane potentials, organellar acidification, and cell volume homeostasis (3). Malfunction in these channels can lead to severe disease states (4).Chloride channels fall into several classes based on their sequence relationships. The three best characterized classes are the ligand-gated receptor channels (␥-aminobutyric acid and glycine receptors), the cystic fibrosis transmembrane conductance regulator family, and the ClC chloride ion channels (1, 2). A new class of chloride ion channel, the "chloride intracellular channels" (CLICs), 1 has recently been characterized at a molecular level. To date, there are seven members of the CLIC family: CLIC1 (NCC27) (5), CLIC2 (6), CLIC3 (7), CLIC4 (8), CLIC5 (9), p64 (10), and parchorin (11). All of these proteins exist as soluble globular proteins that can form ion channels in organellar and plasma membranes (5,7,8,(12)(13)(14)(15). Five of the CLIC proteins are each composed of ϳ240 residues, while the longer p64 and parchorin consist of distinct amino-terminal domains followed by the 240-residue CLIC module. This module has recently been shown to share weak sequence homology with the glutathione S-transferase (GST) superfamily (16).The CLIC proteins are expressed in a wide variety of tissues and appear to have diverse physiological functions. p64 is associated with kidney function (17), while CLIC1 and CLIC4 appear to have a broad tissue distribution (5,8,18,19). Several CLICs interact with protein kinases (7,11,20). CLICs are associated with a variety of intracellular membranes including the nuclear membrane (5), the endoplasmic reticular membrane (8), large dense-core vesicles (19), mitochondria (21), trans-Golgi vesicles (22), and secretory vesicles (23). Parchorin forms the chloride channel in water-secreting cells,...
SummaryATR controls chromosome integrity and chromatin dynamics. We have previously shown that yeast Mec1/ATR promotes chromatin detachment from the nuclear envelope to counteract aberrant topological transitions during DNA replication. Here, we provide evidence that ATR activity at the nuclear envelope responds to mechanical stress. Human ATR associates with the nuclear envelope during S phase and prophase, and both osmotic stress and mechanical stretching relocalize ATR to nuclear membranes throughout the cell cycle. The ATR-mediated mechanical response occurs within the range of physiological forces, is reversible, and is independent of DNA damage signaling. ATR-defective cells exhibit aberrant chromatin condensation and nuclear envelope breakdown. We propose that mechanical forces derived from chromosome dynamics and torsional stress on nuclear membranes activate ATR to modulate nuclear envelope plasticity and chromatin association to the nuclear envelope, thus enabling cells to cope with the mechanical strain imposed by these molecular processes.
Epidemiological and preclinical studies propose that metformin, a first-line drug for type-2 diabetes, exerts direct antitumor activity. Although several clinical trials are ongoing, the molecular mechanisms of this effect are unknown.Here we show that chloride intracellular channel-1 (CLIC1) is a direct target of metformin in human glioblastoma cells. Metformin exposure induces antiproliferative effects in cancer stem cell-enriched cultures, isolated from three individual WHO grade IV human glioblastomas. These effects phenocopy metformin-mediated inhibition of a chloride current specifically dependent on CLIC1 functional activity. CLIC1 ion channel is preferentially active during the G1-S transition via transient membrane insertion. Metformin inhibition of CLIC1 activity induces G1 arrest of glioblastoma stem cells. This effect was time-dependent, and prolonged treatments caused antiproliferative effects also for low, clinically significant, metformin concentrations. Furthermore, substitution of Arg29 in the putative CLIC1 pore region impairs metformin modulation of channel activity.The lack of drugs affecting cancer stem cell viability is the main cause of therapy failure and tumor relapse. We identified CLIC1 not only as a modulator of cell cycle progression in human glioblastoma stem cells but also as the main target of metformin's antiproliferative activity, paving the way for novel and needed pharmacological approaches to glioblastoma treatment.
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