CaV 3.1 and CaV 3.3 account for T-type Ca2+ current in GH3 cells

T-type Ca2+ channels are important for cell signaling by a variety of cells. We report here the electrophysiological and molecular characteristics of the whole-cell Ca2+ current in GH3 clonal pituitary cells. The current inactivation at 0 mV was described by a single exponential function with a time constant of 18.32 ñ 1.87 ms (N = 16). The I-V relationship measured with Ca2+ as a charge carrier was shifted to the left when we applied a conditioning pre-pulse of up to -120 mV, indicating that a low voltage-activated current may be present in GH3 cells. Transient currents were first activated at -50 mV and peaked around -20 mV. The half-maximal voltage activation and the slope factors for the two conditions are -35.02 ñ 2.4 and 6.7 ñ 0.3 mV (pre-pulse of -120 mV, N = 15), and -27.0 ñ 0.97 and 7.5 ñ 0.7 mV (pre-pulse of -40 mV, N = 9). The 8-mV shift in the activation mid-point was statistically significant (P < 0.05). The tail currents decayed bi-exponentially suggesting two different T-type Ca2+ channel populations. RT-PCR revealed the presence of a1G (CaV3.1) and a1I (CaV3.3) T-type Ca2+ channel mRNA transcripts.

Electrophysiological evidence for glial-subtype glutamate transporter functional expression in rat cerebellar granule neurons

A glutamate-sensitive inward current (Iglu) is described in rat cerebellar granule neurons and related to a glutamate transport mechanism. We examined the features of Iglu using the patch-clamp technique. In steady-state conditions the Iglu measured 8.14 ± 1.9 pA. Iglu was identified as a voltage-dependent inward current showing a strong rectification at positive potentials. L-Glutamate activated the inward current in a dose-dependent manner, with a half-maximal effect at about 18 æM and a maximum increase of 51.2 ± 4.4 percent. The inward current was blocked by the presence of dihydrokainate (0.5 mM), shown by others to readily block the GLT1 isoform. We thus speculate that Iglu could be attributed to the presence of a native glutamate transporter in cerebellar granule neurons

Partial purification and pharmacological characterization of a neurotoxic fraction isolet from the venom of the spider Lycosa erythrognatha

The effect of the venom of the spider Lycosa erythrognatha on the frog sciatic nerve was investigated with the single sucrose-gap method. Solutions containing the crude venom (40 µg protein/ml) markedly increased the duration of compound action potentials and caused the appearance of long-lasting depolarizing post-potentials. These effects were only partially (20 percent) reversded by extensive washsing with control solution. The active material was sensitive to proteolytic treatments with pronase or trypsin and was separated with 20 percent acetonitrile and 0.1 percent trifluoroacetic acid by reverse phase chromatography. The effect of this fraction (LycIV) on the post-potential amplitude was concentration-dependent, and was fitted with a quadratic hyperbola having a half maximal effect of 0.9 µg protein/ml. SDS-polyacrylamide gel electrophoresis of LycIV showed an enriched polypeptide band with apparent molecular weight of ~8 kDa. The observed effects were similar to those of toxins that inhibit sodium channel inactivation and different from the effects of potassium channel blockers. Pore formation or membrane disruption could be ruled out. It was concluded that the venom contains a neurotoxic polypeptide that alters the repolarization of action potentials, probably by inhibiting sodium channel inactivation

Effects of crotoxin on the action potential kinetics of frog skeletal muscle

1. The effect of crotoxin on the action potential kinetics of frog (Rana catesbeiana; 60-80 g) skeletal muscle was studied using a modified Ringer solution containing 1.6 mM KCl. 2. Crotoxin affected the kinetics of the action potential in a dose-dependent manner (90 to 460 nM). At 230 nM, crotoxin prolonged the duration of the action potential (from 1.1 +/- 0.1 to 1.6 +/- 0.1 ms) and slowed the rates of depolarization (from 282.0 +/- 7.3 to 196.0 +/- 13.2 V/s) and repolarization (from -81.4 +/- 6.9 to -55.6 +/- 3.8 V/s), in a dose-dependent manner. Its phospholipase subunit (component B) was five times less effective. 3. No effect of crotoxin was observed in the presence of 2.5 mM KCl or when SrCl2 was substituted for CaCl2. Lowering the muscle temperature to 12 degrees C did not reduce the effect of crotoxin. 4. No effect on the passive membrane response to hyperpolarizing current pulses was observed, which implies no major effect on the membrane resistance and capacitance. 5. It is concluded that crotoxin reduces the Na+ current and slows down the repolarization mechanism. This effect is probably not dependent on the phospholipase A2 activity of crotoxin and is inhibited by the substitution of Sr2+ for Ca2+

The effect of crotoxin on the release of acetylcholine and lactate dehydrogenase from rat brain cortical slices

We have studied the effects of crotoxin, the neurotoxin of the South American rattlesnake Crotalus durissus terrificus, ,on the release of acetylcholine and lactate dehydrogenase from rat brain cortical slices. Crotoxin enhances the release of [3H]-acetylcholine from cortical slices (control values 92.8 ñ 5.9 and 150.3 ñ 11.7 DPM/mg and crotoxin valuesw 199.1 ñ 7.0 and 336.0 ñ 26.0 DPM/mg at 60 and 120 min incubation, respectively) in parallel with the release of lactate dehydrogenase (control values 50.4 ñ 16.8 and 80.3 ñ 19.5 U/mg and crotoxin values 162.5 ñ 39.1 and 355.7 ñ 38.2 U/mg, at 120 min incubation, respectively). Both effects are markedly reduced when substituting Sr2+ for Ca2+ in the incubation medium. It is concluded that the phospholipase activity of crotoxin is responsible for the observed effects