Closure Of Ca2 Research Articles

Slow excitatory metabotropic signal transmission in the enteric nervous system

Metabotropic mechanisms of excitatory signalling in enteric neurones underlie both slow synaptic transmission and paracrine transmission from enteric non-neuronal cells. The type of neurone in which signalling occurs determines the characteristics of synaptic- and paracrine-mediated slow excitatory responses. Slow excitatory responses in neurones with AH-type electrophysiological behaviour and multipolar Dogiel type II morphology are characterized by membrane depolarization associated with closure of Ca2+ -gated K+ channels that is reflected by increased neuronal input resistance. Slow excitatory responses in neurones with S-type electrophysiological behaviour and uniaxonal morphology are characterized by membrane depolarization associated with opening of cationic channels and decreased neuronal input resistance. Postreceptor signalling that involves activation of adenylate cyclase, stimulation of cAMP formation and activation protein kinase A generates excitatory responses characterized by increased neuronal input resistance in AH neurones. Postreceptor signalling that involves activation of phospholipase C, release of IP3 and diacylglycerol and activation of protein kinase C and calmodulin kinases generates excitatory responses characterized by decreased neuronal input resistance in S neurones. Slow excitatory responses that are characterized by increased neuronal input resistance are a property of AH-type neurones that function as interneurones in the neural networks of the ENS. Slow excitatory responses that are characterized by decreased neuronal input resistance are a property of S-type neurones that function either as interneurones or as musculomotor and secretomotor neurones in the neural networks of the ENS.

P2Ys go neuronal: modulation of Ca2+ and K+ channels by recombinant receptors

British Journal of Pharmacology (2003) 138, 716. doi:10.1038/sj.bjp.0705201

P2Ys go neuronal: modulation of Ca2+ and K+ channels by recombinant receptors.

British Journal of Pharmacology (2003) 138, 1–3. doi:10.1038/sj.bjp.0705044

Members of the Kv1 and Kv2 voltage-dependent K(+) channel families regulate insulin secretion.

In pancreatic beta-cells, voltage-dependent K(+) (Kv) channels are potential mediators of repolarization, closure of Ca(2+) channels, and limitation of insulin secretion. The specific Kv channels expressed in beta-cells and their contribution to the delayed rectifier current and regulation of insulin secretion in these cells are unclear. High-level protein expression and mRNA transcripts for Kv1.4, 1.6, and 2.1 were detected in rat islets and insulinoma cells. Inhibition of these channels with tetraethylammonium decreased I(DR) by approximately 85% and enhanced glucose-stimulated insulin secretion by 2- to 4-fold. Adenovirus-mediated expression of a C-terminal truncated Kv2.1 subunit, specifically eliminating Kv2 family currents, reduced delayed rectifier currents in these cells by 60-70% and enhanced glucose-stimulated insulin secretion from rat islets by 60%. Expression of a C-terminal truncated Kv1.4 subunit, abolishing Kv1 channel family currents, reduced delayed rectifier currents by approximately 25% and enhanced glucose-stimulated insulin secretion from rat islets by 40%. This study establishes that Kv2 and 1 channel homologs mediate the majority of repolarizing delayed rectifier current in rat beta-cells and that antagonism of Kv2.1 may prove to be a novel glucose-dependent therapeutic treatment for type 2 diabetes.

Members of the Kv1 and Kv2 Voltage-Dependent K+ Channel Families Regulate Insulin Secretion

In pancreatic β-cells, voltage-dependent K+ (Kv) channels are potential mediators of repolarization, closure of Ca2+ channels, and limitation of insulin secretion. The specific Kv channels expressed in β-cells and their contribution to the delayed rectifier current and regulation of insulin secretion in these cells are unclear. High-level protein expression and mRNA transcripts for Kv1.4, 1.6, and 2.1 were detected in rat islets and insulinoma cells. Inhibition of these channels with tetraethylammonium decreased IDR by approximately 85% and enhanced glucose-stimulated insulin secretion by 2- to 4-fold. Adenovirus-mediated expression of a C-terminal truncated Kv2.1 subunit, specifically eliminating Kv2 family currents, reduced delayed rectifier currents in these cells by 60–70% and enhanced glucose-stimulated insulin secretion from rat islets by 60%. Expression of a C-terminal truncated Kv1.4 subunit, abolishing Kv1 channel family currents, reduced delayed rectifier currents by approximately 25% and enhanced glucose-stimulated insulin secretion from rat islets by 40%. This study establishes that Kv2 and 1 channel homologs mediate the majority of repolarizing delayed rectifier current in rat β-cells and that antagonism of Kv2.1 may prove to be a novel glucose-dependent therapeutic treatment for type 2 diabetes.

The kinetics of exocytosis and endocytosis in the synaptic terminal of goldfish retinal bipolar cells.

1. The kinetics of exocytosis and endocytosis were studied in the giant synaptic terminal of depolarizing bipolar cells from the goldfish retina. Two techniques were applied: capacitance measurements of changes in membrane surface area, and fluorescence measurements of exocytosis using the membrane dye FM1-43. 2. Three phases of exocytosis occurred during maintained depolarization to 0 mV. The first component was complete within about 10 ms and involved a pool of 1200-1800 vesicles (with a total membrane area equivalent to about 1.6 % of the surface of the terminal). The second component of exocytosis involved the release of about 4400 vesicles over 1 s. The third component of exocytosis was stimulated continuously at a rate of about 1000 vesicles s-1. 3. After short depolarizations (< 200 ms), neither the FM1-43 signal nor the capacitance signal continued to rise, indicating that exocytosis stopped rapidly after closure of Ca2+ channels. The fall in capacitance could therefore be used to monitor endocytosis independently of exocytosis. The capacitance measured after brief stimuli began to fall immediately, recovering to the pre-stimulus baseline with a rate constant of 0.8 s-1. 4. The amount of exocytosis measured using the capacitance and FM1-43 techniques was similar during the first 200 ms of depolarization, suggesting that the most rapidly released vesicles could be detected by either method. 5. After a few seconds of continuous stimulation, the net increase in membrane surface area reached a plateau at about 5 %, even though continuous exocytosis occurred at a rate of 0.9 % s-1. Under these conditions of balanced exocytosis and endocytosis, the rate constant of endocytosis was about 0.2 s-1. The average rate of endocytosis during maintained depolarization was therefore considerably slower than the rate observed after a brief stimulus. 6. After longer depolarizations (> 500 ms), both the capacitance and FM1-43 signals continued to rise for periods of seconds after closure of Ca2+ channels. The continuation of exocytosis was correlated with a persistent increase in [Ca2+]i in the synaptic terminal, as indicated by the activation of a Ca2+-dependent conductance and measurements of [Ca2+]i using the fluorescent indicator furaptra. 7. The delayed fall in membrane capacitance after longer depolarizations occurred along a double exponential time course indicating the existence of two endocytic processes: fast endocytosis, with a rate constant of 0.8 s-1, and slow endocytosis, with a rate constant of 0.1 s-1. 8. Increasing the duration of depolarization caused an increase in the fraction of membrane recovered by slow endocytosis. After a 100 ms stimulus, all the membrane was recycled by fast endocytosis, but after a 5 s depolarization, about 50 % of the membrane was recycled by slow endocytosis. 9. These results demonstrate the existence of fast and slow endocytic mechanisms at a synapse and support the idea that prolonged stimulation leads to an increase in the amount of membrane retrieved by the slower route. The rise in cytoplasmic Ca2+ that occurred during longer depolarizations was correlated with stimulation of continuous exocytosis and inhibition of fast endocytosis. The results also confirm that transient and continuous components of exocytosis coexist in the synaptic terminal of depolarizing bipolar cells.

Galanin receptors: involvement in feeding, pain, depression and Alzheimer's disease.

Galanin, a neuroendocrine peptide with a multitude of functions, binds to and acts on specific G-protein coupled receptors. Only one galanin receptor subtype, GalRI, has been cloned so far, although pharmacological evidence suggests the presence of more than one galanin receptor subtype. These receptors mediate via different Gi/Go-proteins the inhibition of adenylyl cyclase, opening of K+-channels and closure of Ca2+-channels. Galanin inhibits secretion of insulin, acetylcholine, serotonin and noradrenaline, while it stimulates prolactin and growth hormone release. Determination of structural components of galanin receptors required for binding of the peptide ligand as carried out recently will facilitate the screening and design of molecules specifically acting on galaninergic systems with therapeutic potential in Alzheimer's disease, feeding disorders, pain and depression.

Variations in cyclic adenosine 3',5'-monophosphate and cyclic guanosine 3',5'-monophosphate content and efflux from the photosensitive pineal organ of the pike in culture.

The photoreceptor cells of the pike pineal organ transduce 24-h light/dark (LD) information to synchronize the clocks driving the melatonin (MEL) rhythm. In fish, the nocturnal rise in MEL synthesis is associated with an increase in cyclic adenosine 3', 5'-monophosphate (cAMP) production and with Ca2+ entry, through voltage-gated channels. Light induces inhibition of MEL synthesis and a depression of cAMP content, as well as closure of Ca2+ channels. Cyclic guanosine 3',5'-monophosphate (GMP) levels also are reduced upon acute illumination but this second messenger of phototransduction does not appear to be directly involved in the control of MEL metabolism. It is not known whether cAMP and/or cGMP are components of the clock machinery. In this study we measured cAMP and cGMP contents (static culture) and release (perifusion culture) using pike pineal organs maintained under LD or DD (constant darkness). Under LD, cAMP levels were low at noon and midnight, and high at dawn and dusk, in organs as well as in perfusates. This pattern was maintained under DD, with a major peak occurring at the beginning of subjective light, and a minor peak at the beginning of subjective darkness; only one peak during the subjective light was seen in the perfusates. Under DD, the MEL rhythm displays only one peak during the subjective night. It is suggested that increases in cAMP might not always be correlated with increases in MEL secretion. Under LD, variations in cGMP content were not statistically significant; however, in the perfusates, the levels were higher during the night than during the day. This suggests that: (1) extrusion participates in the regulation of intracellular levels of cGMP, (2) nocturnal synthesis of cGMP is higher than its catabolism, and (3) synthesis is increased during the day to compensate for the light-induced activation of catabolism. Under DD, the cGMP content and release were higher during the subjective night than during the subjective day, revealing a circadian component in the regulation of cGMP metabolism. This may provide the basis for the generation of membrane-related circadian events including variations in membrane potential, in the opening/closure of voltage-gated channels (e.g. Ca2+ channels), or in enzyme activities (adenylyl cyclase, cGMP-dependent phosphodiesterase).

Long Ca2+ channel opening induced by large depolarization and Bay K 8644 in smooth muscle cells isolated from guinea-pig detrusor.

1. In smooth muscle cells enzymatically isolated from guinea-pig urinary bladder, Ca2+ channel currents were recorded by conventional cell-attached patch clamp techniques. In most recordings Bay K 8644 (2 microM) was contained in the patch pipette. 2. Closure of Ca2+ channels observed during the repolarizing steps was significantly slowed by preconditioning with large depolarizations (+80 and 100 mV), with or without Bay K 8644 in the pipette. 3. The sum of the unitary Ca2+ channel current traces obtained after large conditioning depolarizations (in the presence of Bay K 8644) showed a slowly deactivating tail current. 4. By use of this slow deactivating feature, the current-voltage relationship of the unitary Ca2+ channel current was continuously measured with a ramp pulse after large depolarization. The slope conductance ranged from 22 to 30 pS, compatible with that of L-type Ca2+ channels. 5. It is concluded that L-type Ca2+ channels in guinea-pig detrusor cells are open for much longer after large depolarizations consistent with their being two channel open states, and that Bay K 8644 prolongs the lifetime of both open states. The underlying mechanisms are discussed.

Membrane physiological reactions of human arteriosclerotic coronary arteries to hypoxia.

Human coronary arteries were taken from heart transplant patients. Arteriosclerotic arteries were more depolarized and constricted over the whole PO2 range between 535 and 0 mm Hg. During oxygen deficiency, control preparations showed a maximal hyperpolarization of delta V = 10.9 mV and a maximal relaxation of delta T = 0.466 g. Arteriosclerotic arteries, however, became hyperpolarized by merely delta V = 7.1 mV and relaxed by delta T = 0.258 g. In normal coronary arteries, indomethacin reduced the hypoxic hyperpolarization and dilation at 30 mm Hg PO2 by about 51%. The reduction was 26% in arteriosclerotic vessels. The complete removal of the endothelium caused a 49% (74%) restriction of dilatory vascular reactivity. The relationship was quite similar for a carbogen Krebs solution. The hyperpolarizing and dilatory contribution by prostacyclin was 32% in normal and 12% in arteriosclerotic coronary arteries. The remainder could be attributed to the basal release of the endothelial dilator endothelium-derived hyperpolarizing factor (EDHF). Thus, it may be concluded that in arteriosclerotic blood vessels, prostacyclin (PGI2) synthesis and release are predominantly diminished. Finally, we found that the ratio PGI2/EDHF in the voltage and tension changes strongly shifted to the PGI2 side with a declining oxygen concentration. This is true for normal and arteriosclerotic vessels. In accordance with the activation curve for vascular smooth muscle, the hyperpolarization leads to relaxation via a closure of Ca2+ channels. Hyperpolarization of 2.5 mV reduces the tension developed by one-half.