Hepatocyte Growth Factor/Scatter Factor Stimulates Ca ²⁺-Activated Membrane K⁺ Current and Migration of MDCK II Cells

Jin, M., Defoe, D. M., Wondergem, R.

01 January 2003

Hepatocyte growth factor/scatter factor (HGF/SF) stimulates migration of various cells and has been linked via Met tyrosine kinase-signaling to transformation and the metastatic phenotype. Migration of transformed MDCK-F cells depends on activation of a charybdotoxin-sensitive, volume-activated membrane K+ current. Thus, we used patchclamp electrophysiology and transwell migration assays to determine whether HGF/SF stimulation of MDCK II cell migration depends on the activation of membrane K+ currents. HGF/SF activated a membrane K+ current that increased over 24 hr, and which could be modulated by increasing intracellular calcium concentration, [Ca2+]i. Charybdotoxin (ChTX, 50 nM), iberiotoxin (IbTX, 100 nM), stichodactyla toxin (Stk, 100 nM) and clotrimazole (CLT, 1 μM) all inhibited this current. HGF/SF (100 scatter units/ml) significantly increased MDCK II cell migration over 8 hr compared to control cells. Addition of ChTX (50 nM), IbTX (100 nm), Stk (100 nM) or CLT (1 μM) inhibited the HGF/SF-stimulated MDCK II cell migration. We conclude that the activation of membrane Ca2+-activated K+ current is necessary for HGF/ SF stimulation of MDCK II cell.

Ca -activated K channel 2+ +

charybdotoxin

iberiotoxin

migration assay

Biomedical Sciences

Effects of Cccp-Induced Mitochondrial Uncoupling and Cyclosporin a on Cell Volume, Cell Injury and Preconditioning Protection of Isolated Rabbit Cardiomyocytes

Ganote, Charles E., Armstrong, Stephen C.

01 July 2003

Cell swelling may contribute to acute cell injury subsequent to ischemia/reperfusion. The potential role of mitochondrial uncoupling and the resultant mitochondrial swelling, due to opening of the mitochondrial permeability transition pore (MPTP), were examined in an in vitro ischemically pelleted isolated rabbit cardiomyocyte model using the protonophore, carbonyl cyanide m-chlorophenylhydrazone (CCCP) to uncouple mitochondria. Cyclosporin A (CsA) was employed to inhibit MPTP opening. Cell volume was determined by a cell-flotation, density-gradient assay, using bromododecane. Cell viability, subsequent to an osmotic stress, was determined by trypan blue permeability. Ischemic preconditioning (IPC) facilitated volume regulation following an osmotic stress. Ischemic-cell swelling was reduced by IPC. IPC protected ischemically pelleted cells, but CsA had no significant effects on injury or IPC protection. CCCP ischemia accelerated rates of ischemic contracture and injury, and abolished IPC protection. IPC protection was restored by CsA. In CCCP-ischemic-uncoupled cells, subjected to a reduced (170 mOsm) osmotic stress, CsA and IPC afforded independent and additive protection. Chelerythrine and 5-hydroxydecanoate (5-HD) blocked IPC, but did not reduce CsA protection. Electron microscopy confirmed that CCCP ischemia induced mitochondrial matrix swelling that was reduced by CsA. Cardioprotection by IPC and CsA was accompanied by proportional reductions in cell swelling. Morphometric analysis of the electron photomicrographs demonstrated that the mitochondrial volume fractions were significantly reduced in the CsA/CCCP (29.8 ± 2.3%, P < 0.004) and IPC/CsA/CCCP (31.5 ± 1.7%, P < 0.0008) groups as compared to the CCCP-ischemic group (40.5 ± 1.7%) The IPC/CCCP group (39.5 ± 4.2%) was not significantly different from the CCCP-ischemic group. NIM 811, a CsA analogue MPTP blocker with no calcineurin inhibitory activity, afforded protection similar to CsA. The results suggest that CsA protection may, in part, be mediated by reduction of mitochondrial swelling.

ischemia

ischemic preconditioning

isolated cardiomyocytes

mitochondria

mitochondrial K channel ATP

mitochondrial permeability

Transition pore

Activation of Ca²⁺-activated K⁺ Channels and Cell Migration by Hepatocyte Growth Factor/Scatter Factor in Madin-Darby Canine Kidney Cells.

Jin, Min

14 December 2002

Hepatocyte Growth Factor/Scatter Factor (HGF/SF) stimulates migration of various cells and has been linked via Met tyrosine kinase signaling to transformation and the metastatic phenotype. HGF/SF-Met signaling also plays a role in malignancy. Migration of transformed MDCK-F cells depends on activation of a charybdotoxin (ChTX)-sensitive, volume-activated membrane K+ current. Patch-clamp electrophysiology and transwell migration assays were used to study the effects of HGF/SF on membrane K+ currents and cell migration in MDCK II cells. HGF/SF activated membrane K+ currents that increased over 24 hr, and these could be modulated by altering intracellular free calcium concentration [Ca2+]i. HGF/SF also significantly increased MDCK II cell migration. Specific Ca2+-activated K+ channel blockers, ChTX, iberiotoxin (IbTX), stichodactyla toxin (Stk) and clotrimazole (CLT) inhibited HGF/SF stimulation of membrane K+ currents and cell migration. This suggests that the activation of Ca2+-activated K+ channels is necessary for HGF/SF stimulation of MDCK II cell migration. Furthermore, HGF/SF induced ERK phosphorylation, and addition of the MEK inhibitor PD98059 inhibited ERK phosphorylation, as well as HGF/SF stimulation of Ca2+-activated K+ currents and cell migration in MDCK II cells. Taken together, HGF/SF induces phosphorylation of ERK, which plays a role in HGF/SF activation of Ca2+-activated K+ channels and enhancing cell migration in MDCK II cells.

HGF/SF

Ca2+-activated K+ channel

MEK

ERK

Medical Sciences

Medicine and Health Sciences

A key role for peroxynitrite-mediated inhibition of cardiac ERG (Kv11.1) K+ channels in carbon monoxide–induced proarrhythmic early afterdepolarizations

Al-Owais, M.M., Hettiarachchi, N.T., Kirton, H.M., Hardy, Matthew E., Boyle, J.P., Scragg, J.L., Steele, D.S., Peers, C.

25 July 2017

Yes / Exposure to CO causes early afterdepolarization arrhythmias. Previous studies in rats have indicated that arrhythmias arose as a result of augmentation of the late Na+ current. The purpose of the present study was to examine the basis for CO-induced arrhythmias in guinea pig myocytes in which action potentials (APs) more closely resemble those of human myocytes. Whole-cell current- and voltage-clamp recordings were made from isolated guinea pig myocytes as well as from human embryonic kidney 293 (HEK293) cells that express wild-type or a C723S mutant form of ether-a-go-go–related gene (ERG; Kv11.1). We also monitored the formation of peroxynitrite (ONOO−) in HEK293 cells fluorimetrically. CO—applied as the CO-releasing molecule, CORM-2—prolonged the APs and induced early afterdepolarizations in guinea pig myocytes. In HEK293 cells, CO inhibited wild-type, but not C723S mutant, Kv11.1 K+ currents. Inhibition was prevented by an antioxidant, mitochondrial inhibitors, or inhibition of NO formation. CO also raised ONOO− levels, an effect that was reversed by the ONOO− scavenger, FeTPPS [5,10,15,20-tetrakis-(4-sulfonatophenyl)-porphyrinato-iron(III)], which also prevented the CO inhibition of Kv11.1 currents and abolished the effects of CO on Kv11.1 tail currents and APs in guinea pig myocytes. Our data suggest that CO induces arrhythmias in guinea pig cardiac myocytes via the ONOO−-mediated inhibition of Kv11.1 K+ channels. / British Heart Foundation

Nitric oxide

Potassium channel

Myocytes

Biophysical Studies On The Plastic And Cooperative Properties Of Single Voltage Gated Na+ And Leak K+ Ion Channels

Nayak, Tapan Kumar

11 1900

Ion channels are fundamental molecules in the nervous system that catalyze the flux of ions across the cell membrane. There are mounting evidences suggesting that the kinetic properties of ion channels undergo activity-dependent changes in various pathophysiological conditions. Here such activity-dependent changes were studied in case of two different ion channels; the rat brain derived voltage-gated Na+ channel, rNav1.2 and the human background leak K+ channel, hTREK1 using the single channel patch-clamp technique. Our results on the voltage-gated Na+ channel (Chapter III) illustrated that sustained membrane depolarization, as seen in pathophysiological conditions like epilepsy, induced a defined non-linear variation in the unitary conductance, activation, inactivation and recovery kinetic properties of the channel. Signal processing tools attributed a pseudo-oscillatory nature to the non-linearity observed in the channel properties. Prolonged membrane depolarization also induced a “molecular memory” phenomenon, characterized by clustering of dwell time events and strong autocorrelation in the dwell time series. The persistence of such molecular memory was found to be dependent on the duration of depolarization. Similar plastic changes were observed in case of the hTREK1 channel in presence of saturating concentrations of agonist, trichloroethanol (TCE) (Chapter IV). TREK1 channel behaves similar to single enzyme molecules with a single binding site for the substrate K+ ion whereas TCE acts as an allosteric activator of the channel. We observed that with increasing concentration of TCE (10 M to 10 mM) the catalytic turnover rate exhibited progressive departure from monoexponential to multi-exponential distribution suggesting the presence of ‘dynamic disorder’ analogous to single enzyme molecules. In addition, we observed the induction of strong correlation in successive waiting times and flux intensities, exemplified by distinct mode switching between high and low flux activity, which implied the induction of memory in single ion channel. Our observation of such molecular memory in two different ion channels in different experimental conditions highlights the importance and generality of the phenomenon which is normally hidden under the ensemble behaviour of ion channels. In the final part of the work (chapter V) we observed strong negative cooperativity and half-of-sites saturation kinetics in the interaction of local anesthetic, lidocaine with hTREK1 channel. We also mapped the specific anesthetic binding site in the c-terminal domain of the channel. Further, single channel analysis and the heterodimer studies enabled us to propose a model for this interaction and provide a plausible paradigm for the inhibitory action of lidocaine on hTREK1.

Biophysics

Electricity

Sodium Ions

Potassiium Ions

Ion Channels

Ion Channels - Biophysical Properties

Ion Channel Gating

Ion Selectivity

Ion Channels - Molecular Memory

Intrinsic Plasticity

Ligand-Gated Ion Channels

Ion Channels - Cooperativity

Sodium Channel

K+ Channel

Na+ Channel

Biophysics