Modulation of N-type Ca2+ channel current kinetics by PMA in rat sympathetic neurons.

The protein kinase C activator phorbol 12-myristate 13-acetate (PMA) has been used extensively in studies of G protein modulation of Ca2+ channels. PMA has been shown to be a powerful tool for inducing phosphorylation and interrupting G-protein-mediated signaling pathways. Here we re-examine the effects of PMA on whole-cell N-type Ca2+-channel currents in rat sympathetic neurons. We found that, along with an increase in the current amplitude previously reported by others, PMA pretreatment leads to alterations in current activation and inactivation kinetics. These alterations in current kinetics are voltage-dependent and are not reproduced by internal dialysis with the G protein inhibitor GDPbetaS. Alterations in current kinetics by PMA may therefore indicate the existence of a modulated state, presumably phosphorylated, of N-type Ca2+ channels. We propose that the increase in current amplitude is due primarily to alterations in current kinetics rather than to removal of tonic inhibition.

Potentiation of prolactin secretion following lactotrope escape from dopamine action. I. Dopamine withdrawal augments l-type calcium current.

Hypothalamic dopamine (DA) tonically inhibits prolactin (PRL) release from the anterior pituitary gland. Transient escapes from this DA tone elicit a pronounced potentiation of the PRL-releasing action of secretagogues such as thyrotropin-releasing hormone (TRH). Previous evidence has suggested that modulation of Ca(2+) channels can be involved in this potentiation. With a lactotropic cell line (GH(4)C(1)) expressing human D(2)-DA receptors, we tested the hypothesis that a brief escape from the tonic inhibitory action of DA triggers a facilitation of Ca(2+) influx through Ca(2+) channels. We initially found that in these cells, DA effectively and reversibly inhibited PRL secretion, and reversibly enhanced an inwardly rectifying K(+) current. The effects of DA administration and withdrawal on Ca(2+) currents were examined using the patch-clamp technique in the whole-cell configuration and Ba(2+) as a divalent charge carrier through Ca(2+) channels. Macroscopic Ba(2+) currents were significantly decreased by short term (1-10 min) applications of DA (500 nM), which further declined following 24 h of constant exposure to DA. After DA removal, a biphasic facilitation of the density of Ba(2+) currents was observed. An initial 2-fold enhancement of conductance was detected between 10 and 40 min, followed by a second facilitation of the same magnitude observed 24 h after DA withdrawal. The present results directly demonstrate that dissociation of DA from D(2)-receptors expressed in GH(4)C(1) lactotrope cells causes an increase of high-voltage-activated Ca(2+) channel function, which may play an important role in the cross-talking amplification of endocrine cascades such as that involved in the TRH-induced PRL-release potentiating action of DA withdrawal.

G-protein beta-subunit specificity in the fast membrane-delimited inhibition of Ca2+ channels.

We investigated which subtypes of G-protein beta subunits participate in voltage-dependent modulation of N-type calcium channels. Calcium currents were recorded from cultured rat superior cervical ganglion neurons injected intranuclearly with DNA encoding five different G-protein beta subunits. Gbeta1 and Gbeta2 strongly mimicked the fast voltage-dependent inhibition of calcium channels produced by many G-protein-coupled receptors. The Gbeta5 subunit produced much weaker effects than Gbeta1 and Gbeta2, whereas Gbeta3 and Gbeta4 were nearly inactive in these electrophysiological studies. The specificity implied by these results was confirmed and extended using the yeast two-hybrid system to test for protein-protein interactions. Here, Gbeta1 or Gbeta2 coupled to the GAL4-activation domain interacted strongly with a channel sequence corresponding to the intracellular loop connecting domains I and II of a alpha1 subunit of the class B calcium channel fused to the GAL4 DNA-binding domain. In this assay, the Gbeta5 subunit interacted weakly, and Gbeta3 and Gbeta4 failed to interact. Together, these results suggest that Gbeta1 and/or Gbeta2 subunits account for most of the voltage-dependent inhibition of N-type calcium channels and that the linker between domains I and II of the calcium channel alpha1 subunit is a principal receptor for this inhibition.

Repeated REM sleep deprivation after chronic haloperidol administration in the rat.

Repeated haloperidol administration produces up-regulation of dopamine (DA) receptors. REM sleep deprivation (REMSD) does also, but in addition, has been shown to produce REM sleep rebound. Should DA receptor up-regulation play a role in REM sleep rebound, haloperidol could conceivably have effects similar to those observed following REMSD. This is the central question investigated in this study. Male Wistar rats were prepared for sleep recordings. They were randomly assigned to the following groups: group 1, REMSD by small platforms (40 h REMSD + 8 h recording); group 2, was the large platform control group (40 h in large platforms + 8 h of recording); group 3, received 2-week daily administration of haloperidol (3 mg/kg, i.p.) plus REMSD (40 h REMSD + 8 h of recording); group 4, 2-week administration of haloperidol (3 mg/kg) without sleep manipulation and at the end 40 h were allowed to elapse, following which 8 h of sleep recordings was carried out. In each group the sleep manipulation and/or sleep recordings were repeated five consecutive times. Repeated REMSD produced increases of REM sleep time after each recovery in group 1. Large platforms did not produce increases of REM sleep during the recovery trials. The 2-week administration of haloperidol plus REMSD prevented REM sleep rebound (group 3). The 2-week administration of haloperidol without sleep manipulation (group 4) produced a REM sleep reduction. Dopamine modulation seems not to be important for REM sleep rebound. Hypersensitivity of DA receptors developed after REMSD may be an epiphenomenon associated with this sleep manipulation, but seems not to participate in REM sleep enhancement after REMSD.

Differences in sleep variables, blood adenosine, and body temperature between hypothyroid and euthyroid rats before and after REM sleep deprivation.

Sleep deprivation causes an increase in energy expenditure in animals. Thyroid gland function has been related to metabolic function, and this may be compromised in sleep manipulations. The objectives of the present study were the following: 1) to develop a model of hypothyroid rats by surgical removal of thyroid glands without extirpation of the parathyroid; 2) to observe the sleep architecture in euthyroid (Etx) and hypothyroid (Htx) rats, both before and after rapid eye movement (REM) sleep deprivation (96 hours); 3) to challenge both groups (i.e. Etx and Htx) with REM sleep deprivation (96 hours) and then evaluate the effects on temperature; and 4) to measure the levels of adenosine and thyroid hormones in blood. One-month-old Wistar male rats (weight 90-100 g) were studied. The thyroid gland was removed, and the parathyroid glands were reimplanted within the neck muscle (Htx) under halothane anesthesia. A sham-operated group was also included (Etx). Four months later, the animals were studied according to the following protocols. Protocol 1: Animals of both groups (i.e. Etx and Htx) were implanted for sleep recordings. After a baseline polysomnography, these animals were REM sleep deprived by the platform method (96 hours). Protocol 2. An intraperitoneal temperature transducer was placed into animals of both groups under deep halothane anesthesia. They were studied at baseline, during 96 hours of REM sleep deprivation, and on the rebound period. Protocol 3: Plasma thyroid hormones [T3, T4, and thyroid-stimulating hormone (TSH)] and plasma adenosine were determined in both groups. Results of protocol 1 indicated that the main difference observed in Htx rats during the baseline sleep was an increase in delta sleep (slow-wave sleep 2) and a reduction in waking time compared with Etx animals. REM sleep rebound after 96 hours of REM sleep deprivation was similar in both groups. In protocol 2, the main finding was that Htx animals had reduced body temperature. A significant difference in body temperature between Etx and Htx animals was found mainly during lights-on period. REM sleep deprivation in the Etx group produced an increase in body temperature. Htx animals showed the opposite effect, with a reduction in body temperature during and after REM sleep deprivation. In protocol 3, the main findings were that Htx animals exhibited a significant reduction in blood thyroid hormones (T3, T4), and that they also had high levels of plasma adenosine. REM sleep deprivation produces changes in temperature regulation. The increase in body temperature during REM sleep deprivation may require thyroid integrity. Absence of the thyroid gland does not seem to influence REM sleep recovery after its deprivation. The high plasma adenosine levels found in the Htx group may explain the increase in delta sleep in this group.