Developmental regulation of calcium channel-mediated currents in retinal glial (Muller) cells.
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Whole cell voltage-clamp recordings of freshly isolated cells were used to study changes in the currents through voltage-gated Ca(2+) channels during the postnatal development of immature radial glial cells into Muller cells of the rabbit retina. Using Ba(2+) or Ca(2+) ions as charge carriers, currents through transient low-voltage-activated (LVA) Ca(2+) channels were recorded in cells from early postnatal stages, with an activation threshold at -60 mV and a peak current at -25 mV. To increase the amplitude of currents through Ca(2+) channels, Na(+) ions were used as the main charge carriers, and currents were recorded in divalent cation-free bath solutions. Currents through transient LVA Ca(2+) channels were found in all radial glial cells from retinae between postnatal days 2 and 37. The currents activated at potentials positive to -80 mV and displayed a maximum at -40 mV. The amplitude of LVA currents increased during the first postnatal week; after postnatal day 6, the amplitude remained virtually constant. The density of LVA currents was highest at early postnatal days (days 2-5: 13 pA/pF) and decreased to a stable, moderate level within the first three postnatal weeks (3 pA/pF). A significant expression of currents through sustained, high-voltage-activated Ca(2+) channels was found after the third postnatal week in approximately 25% of the investigated cells. The early and sole expression of transient currents at high-density may suggest that LVA Ca(2+) channels are involved in early developmental processes of rabbit Muller cells. (+info)
The amino side of the C-terminus determines fast inactivation of the T-type calcium channel alpha1G.
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We analysed the kinetic properties of the fast inactivating T-type calcium channel alpha1G in HEK 293 cells transfected with different alpha1G chimeras, containing the N-terminus, III-IV linker or various C-terminal regions of the slowly inactivating L-type alpha1C. A highly negatively charged region of 23 amino acids at the amino side of the intracellular carboxy terminus of alpha1G was found to be critical for fast inactivation. The N-terminus of alpha1G does not seem to be necessary for inactivation of the T-type calcium channel because replacement of the a1G N-terminus with the alpha1C N-terminus did not influence channel kinetics at all. Replacing the III-IV linker of alpha1G with that of a1C decreased the rate of inactivation at -20 mV from 15.8 +/- 1.8 to 8.5 +/- 1.1 ms, and shifted the potential for half-maximal inactivation from -69.6 +/- 0.8 to -54.0 +/- 1.7 mV. However, these parameters were not significantly different at other potentials. We suggest a putative 'ball-and-chain'-like mechanism for inactivation in which the negative charges function as an acceptor domain for a ball, hypothetically located at a different intracellular part of the channel. In addition, transferring the IQ motif and EF hand of alpha1C to alpha1G does not confer Ca2+-dependent inactivation on alpha1G, suggesting that other sequences besides the C-terminus are needed for Ca2+-dependent inactivation of alpha1C. (+info)
Conducted vasoconstriction in rat mesenteric arterioles: role for dihydropyridine-insensitive Ca(2+) channels.
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The aim of this study was to evaluate the role of voltage-operated Ca(2+) channels in the initiation and conduction of vasoconstrictor responses to local micropipette electrical stimulation of rat mesenteric arterioles (28 +/- 1 microm, n = 79) in vivo. Local and conducted (600 microm upstream from the pipette) vasoconstriction was not blocked by TTX (1 micromol/l, n = 5), nifedipine, or nimodipine (10 micromol/l, n = 9). Increasing the K(+) concentration of the superfusate to 75 mmol/l did not evoke vasoconstriction, but this depolarizing stimulus reversibly abolished vasoconstrictor responses to current stimulation (n = 7). Addition of the T-type Ca(2+) antagonist mibefradil (10 micromol/l, n = 6) to the superfusate reversibly blocked local and conducted vasoconstriction to current stimulation. With the use of RT-PCR techniques, it was demonstrated that rat mesenteric arterioles <40 microm do not express mRNA for L-type Ca(2+) channels (alpha(1C)-subunit), whereas mRNA coding for T-type subunits was found (alpha(1G)- and alpha(1H)-subunits). The data indicate that L-type Ca(2+) channels are absent from rat mesenteric arterioles (<40 microm). Rather, the vasoconstrictor responses appear to rely on other types of voltage-gated, dihydropyridine-insensitive Ca(2+) channels, possibly of the T-type. (+info)
alpha1H T-type Ca2+ channel is the predominant subtype expressed in bovine and rat zona glomerulosa.
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The low voltage-activated (T-type) Ca2+ channel has been implicated in the regulation of aldosterone secretion from the adrenal zona glomerulosa by extracellular K+ levels, angiotensin II, and ACTH. However, the identity of the specific subtype mediating this regulation has not been determined. We utilized in situ hybridization to examine the distribution of three newly cloned members of the T-type Ca2+ channel family, alpha1G, alpha1H, and alpha1I, in the rat and bovine adrenal gland. Substantial expression of only the mRNA transcript for the alpha1H-subunit was detected in the zona glomerulosa of both rat and bovine. A much weaker expression signal was detected for the alpha1H transcript in the zona fasciculata of bovine. Whole cell recordings of isolated bovine adrenal zona glomerulosa cells showed the native low voltage-activated current to be inhibited by NiCl2 with an IC50 of 6.4 +/- 0.2 microM. Because the alpha1H subtype exhibits similar NiCl2 sensitivity, we propose that the alpha1H subtype is the predominant T-type Ca2+ channel present in the adrenal zona glomerulosa. (+info)
At least three genes encode T-type calcium channel alpha(1) subunits, and identification of cDNA transcripts provided evidence that molecular diversity of these channels can be further enhanced by alternative splicing mechanisms, especially for the alpha(1G) subunit (Ca(V)3.1). Using whole-cell patch-clamp procedures, we have investigated the electrophysiological properties of five isoforms of the human alpha(1G) subunit that display a distinct III-IV linker, namely, alpha(1G-a), alpha(1G-b), and alpha(1G-bc), as well as a distinct II-III linker, namely, alpha(1G-ae), alpha(1G-be), as expressed in HEK-293 cells. We report that insertion e within the II-III linker specifically modulates inactivation, steady-state kinetics, and modestly recovery from inactivation, whereas alternative splicing within the III-IV linker affects preferentially kinetics and voltage dependence of activation, as well as deactivation and inactivation. By using voltage-clamp protocols mimicking neuronal activities, such as cerebellar train of action potentials and thalamic low-threshold spike, we describe that inactivation properties of alpha(1G-a) and alpha(1G-ae) isoforms can support channel behaviors reminiscent to those described in native neurons. Altogether, these data demonstrate that expression of distinct variants for the T-type alpha(1G) subunit can account for specific low-voltage-activated currents observed in neuronal tissues. (+info)
Identification of the t-type calcium channel (Ca(v)3.1d) in developing mouse heart.
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During cardiac development, there is a reciprocal relationship between cardiac morphogenesis and force production (contractility). In the early embryonic myocardium, the sarcoplasmic reticulum is poorly developed, and plasma membrane calcium (Ca(2+)) channels are critical for maintaining both contractility and excitability. In the present study, we identified the Ca(V)3.1d mRNA expressed in embryonic day 14 (E14) mouse heart. Ca(V)3.1d is a splice variant of the alpha1G, T-type Ca(2+) channel. Immunohistochemical localization showed expression of alpha1G Ca(2+) channels in E14 myocardium, and staining of isolated ventricular myocytes revealed membrane localization of the alpha1G channels. Dihydropyridine-resistant inward Ba(2+) or Ca(2+) currents were present in all fetal ventricular myocytes tested. Regardless of charge carrier, inward current inactivated with sustained depolarization and mirrored steady-state inactivation voltage dependence of the alpha1G channel expressed in human embryonic kidney-293 cells. Ni(2+) blockade discriminates among T-type Ca(2+) channel isoforms and is a relatively selective blocker of T-type channels over other cardiac plasma membrane Ca(2+) handling proteins. We demonstrate that 100 micromol/L Ni(2+) partially blocked alpha1G currents under physiological external Ca(2+). We conclude that alpha1G T-type Ca(2+) channels are functional in midgestational fetal myocardium. (+info)
Differential efficacy of L- and T-type calcium channel blockers in preventing tachycardia-induced atrial remodeling in dogs.
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BACKGROUND: Tachycardia-induced remodeling likely plays an important role in atrial fibrillation (AF) maintenance and recurrence after cardioversion, and Ca(2+) overload may be an important mediator. This study was designed to evaluate the relative efficacies of selective T-type (mibefradil) and L-type (diltiazem) Ca(2+)-channel blockers in preventing tachycardia-induced atrial remodeling. METHODS: Dogs were given daily doses of mibefradil (100 mg), diltiazem (240 mg) or placebo in a blinded fashion, beginning 4 days before and continuing through a 7-day period of atrial pacing at 400 bpm. An electrophysiological study was then performed to assess changes in refractoriness, refractoriness heterogeneity and AF duration. RESULTS: Mean duration of burst-pacing induced AF was similar in placebo (567+/-203 s) and diltiazem-treated (963+/-280 s, P=NS) animals, but was much less in mibefradil-treated dogs (3.6+/-0.9 s, P<0.002) and non-paced controls (6.6+/-2.7 s). In contrast to mibefradil, diltiazem did not alter tachycardia-induced refractoriness abbreviation or heterogeneity. To exclude inadequate dosing as an explanation for diltiazem's inefficacy, we studied an additional group of dogs treated with 720 mg/day of diltiazem, and again noted no protective effect. Acute intravenous administration of diltiazem to control dogs failed to alter atrial refractoriness or AF duration, excluding a masking of remodeling suppression by offsetting profibrillatory effects of the drug. CONCLUSIONS: Whereas the selective T-type Ca(2+)-channel blocker mibefradil protects against atrial remodeling caused by 7-day atrial tachycardia, the selective L-type blocker diltiazem is without effect. These findings are potentially important for understanding the mechanisms and prevention of clinically-relevant atrial-tachycardia-induced remodeling. (+info)
Recovery from inactivation of t-type ca2+ channels in rat thalamic neurons.
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We studied the gating kinetics, especially the kinetics of recovery from inactivation, of T-type Ca(2+) channels (T-channels) in thalamic neurons. The recovery course is associated with no discernible Ca(2+) current and is characterized by an initial delay, as well as a subsequent exponential phase. These findings are qualitatively similar to previous observations on neuronal Na(+) channels and suggest that T-channels also must deactivate to recover from inactivation. In contrast to Na(+) channels in which both the delay and the time constant of the exponential phase are shortened with increasing hyperpolarization, in T-channels the time constant of the exponential recovery phase remains unchanged between -100 and -200 mV, although the initial delay is still shortened e-fold per 43 mV hyperpolarization over the same voltage range. The deactivating kinetics of tail T-currents also show a similar voltage dependence between -90 and -170 mV. According to the hinged-lid model of fast inactivation, these findings suggest that the affinity difference between inactivating peptide binding to the activated channel and binding to the fully deactivated channel is much smaller in T-channels than in Na(+) channels. Moreover, the inactivating peptide in T-channels seems to have much slower binding and unbinding kinetics, and the unbinding rates probably remain unchanged once the inactivated T-channel has gone through the initial steps of deactivation and "closes" the pore (with the activation gate). T-channels thus might have a more rigid hinge and a more abrupt conformational change in the inactivation machinery associated with opening and closing of the pore. (+info)