CB₁ receptor activation inhibits neuronal and astrocytic intermediary metabolism in the rat hippocampus

Cannabinoid CB₁ receptor (CB₁R) activation decreases synaptic GABAergic and glutamatergic transmission and it also controls peripheral metabolism. Here we aimed at testing with ¹³C NMR isotopomer analysis whether CB₁Rs could have a local metabolic role in brain areas having high CB₁R density, such as the hippocampus. We labelled hippocampal slices with the tracers [2-¹³C]acetate, which is oxidized in glial cells, and [U-¹³C]glucose, which is metabolized both in glia and neurons, to evaluate metabolic compartmentation between glia and neurons. The synthetic CB₁R agonist WIN55212-2 (1 μM) significantly decreased the metabolism of both [2-¹³C]acetate (−11.6 ± 2.0%) and [U-¹³C]glucose (−11.2 ± 3.4%) in the tricarboxylic acid cycle that contributes to the glutamate pool. WIN55212-2 also significantly decreased the metabolism of [U-¹³C]glucose (−11.7 ± 4.0%) but not that of [2-¹³C]acetate contributing to the pool of GABA. These effects of WIN55212-2 were prevented by the CB₁R antagonist AM251 (500 nM). These results thus suggest that CB₁Rs might be present also in hippocampal astrocytes besides their well-known neuronal localization. Indeed, confocal microscopy analysis revealed the presence of specific CB₁R immunoreactivity in astrocytes and pericytes throughout the hippocampus.In conclusion, CB₁Rs are able to control hippocampal intermediary metabolism in both neuronal and glial compartments, which suggests new alternative mechanisms by which CB₁Rs control cell physiology and afford neuroprotection.     

Effects of staurosporine on the capacitative regulation of the state of the Ca reserves in activated Jurkat T lymphocytes

Staurosporine (Stp) is an inhibitor of protein kinase C (PKC) that has been used to address the role of this enzyme in a variety of cells. However, Stp can also inhibit protein tyrosine kinases (PTK). We have investigated the effects of Stp on the InsP₃- (using mAb C305 directed against the β chain of the T cell receptor (TcR)/CD3 complex) and the thapsigargin (Tg)-dependent release and influx of Ca²⁺ in human (Jurkat) T cells. The addition of Stp (200 nM) during the sustained phase of the TcR-dependent Ca²⁺ response resulted in a rapid inhibition of the influx of Ca²⁺ that was not seen when Ca²⁺ mobilization was triggered by Tg (1 μM). When the cells were preincubated with Stp (200 nM), there was an inhibition of the mAb C305- but not the Tg-dependent Ca²⁺ response. The effect of Stp was not the result of the inhibition of PKC as shown by down-regulation of PKC and with the use of the specific PKC inhibitor bis-indolyl maleimide GF 109203X. The effect of Stp on the entry of Ca²⁺ in activated (mAb C305) Jurkat lymphocytes was dose-related and was not the result of a direct inhibition of plasma membrane Ca²⁺ channels based on an absence of effect on the Tg-dependent entry of Ca²⁺ and the use of Ca²⁺ channel blockers (econazole and Ni²⁺). These blockers terminated the influx of Ca²⁺ but the Tg-sensitive Ca²⁺ reserves were not refilled in marked contrast to the effect of Stp. Quantification of InsP₃ revealed that the addition of Stp resulted in an approximate 40% reduction in mAb C305-activated Jurkat cells. The effects of Stp can be explained as follows. Stp decreases the mAb C305-induced production of InsP₃ by inhibiting the TcR/CD3-dependent activation of PTK associated with the stimulation of phospholipase C-γ₁. A decrease in [InsP₃] without a return to baseline is sufficient to close the InsP₃ Ca²⁺ channel, endoplasmic Ca²⁺ ATPases use the incoming Ca²⁺ to refill the Ca²⁺ pools and that terminates the capacitative entry of Ca²⁺. A simple kinetic model reproduced the experimental data.     

One-step dilution of open-pulled-straw (OPS)-vitrified mouse blastocysts in sucrose-free medium

Embryos vitrified by the open-pulled-straw (OPS) method are only briefly exposed to cryoprotectants and not fully equilibrated with the cryoprotectant. That being the case, conceivably the post-thawing de- and rehydration processes may be omitted. This would render thawing and dilution in a single step and direct transfer to recipients possible without the need for a microscope and other laboratory equipment. Morphologically intact mouse blastocysts from superovulated 5- to 8-week-old virgin female NMRI mice were vitrified according to a protocol [6] slightly modified from the classical OPS-procedure of Vajta et al. [29] consisting of exposure to 10% dimethyl-sulfoxide (Me₂SO) + 10% ethylene glycol (EG) for 1 min, followed by 20% Me₂SO + 20% EG for 20 s before loading into straws that are plunged into liquid nitrogen. In Group 1, 75 blastocysts were exposed to the standard thawing and dilution regimen involving exposure to three solutions of decreasing sucrose content (Control). In Groups 2, 3 and 4, 75 blastocysts each were transferred, in a single step, to medium at 37 °C containing 0.66, 0.33 or 0 M sucrose, respectively. After 48 h of in vitro culture the proportion of hatched blastocysts was determined. In Group 1, this proportion amounted to 82.7%, in Groups 2, 3 and 4 to 76.0%, 73.3% and 78.7%, respectively (P > 0.05). To examine their potential to continue development in vivo, OPS-vitrified blastocysts thawed according to the regimens of Groups 1 and 4 were transferred to recipients (10 embryos/recipient). In Group 1, 9/10 recipients got pregnant with 4.7 ± 0.6 (mean ± SEM) fetuses, in Group 4, 8/10 recipients with 5.0 ± 0.5 fetuses. The overall embryo survival rate per group was 42% for Group 1 and 40% for Group 4. All fetuses were normally developed and viable and there were no significant differences between groups (P > 0.05). It may be concluded that warming and transfer of OPS-vitrified mouse embryos in a single step in medium devoid of sucrose is feasible, which is tantamount to a substantial simplification of embryo transfer operations.     

Metabolic Basis of Detoxication: Metabolism of Functional Groups : Edited by W.B. Jakoby,J.R. Bend and J. Caldwell Academic Press: New York, 1982 357 + 18 pages. $42.00

By inhibiting the α-like DNA polymerase, and therefore nuclear DNA synthesis, aphidicolin induces accumulation of suspension cultured carrot cells at the G₁/S boundary of the cell cycle. After a 24-h treatment with the drug the accumulation is complete, affecting all the cycling cells (95% of the population). Upon removal of the inhibitor, all cycling cells immediately resume nuclear DNA synthesis and move synchronously throughout the S-phase.