3'-5' cyclic-guanosine monophosphate increase in rat brain hippocampus after gamma-hydroxybutyrate administration. Prevention by valproate and naloxone

An increase (123%) of cyclic GMP (cGMP) was observed in the hippocampus of the rat killed by microwave irradiation 45 min after administration of 500 mg/kg gamma-hydroxybutyrate (GHB) IP. This increase is time and dose dependent. No modification in cyclic nucleotide content was observed in striatum and in cerebellum. As the role of GHB has been implicated in neurotransmission, the fact that this compound increases cyclic GMP accumulation in hippocampus in vivo may represent a mechanism by which the actions of GHB are mediated at the cellular level. Valproate (400 mg/kg) or naloxone (10 mg/kg) pretreatment completely abolish the cGMP increase due to GHB. A GABAergic and/or opiate phenomenon may be involved in the mechanism of GHB induced increase of cGMP.     

Evidence for a role of high Km aldehyde reductase in the degradation of endogenous gamma-hydroxybutyrate from rat brain

gamma-Hydroxybutyrate (GHB) is a putative neurotransmitter in brain. We have already demonstrated that it is transformed into gamma-aminobutyrate (GABA) by rat brain slices incubated under physiological conditions. This conversion occurs via a GABA-transaminase reaction. Therefore, succinic semialdehyde, the oxidative derivative of GHB, appears to be the primary catabolite of GHB degradation. Apparently, the kinetic characteristics and pH optimum of GHB dehydrogenase (high Km aldehyde reductase) in vitro do not favor a role for this enzyme in endogenous brain GHB oxidation. However, in the presence of glucuronate, glutamate, NADP and pyridoxal phosphate, pure GHB dehydrogenase, coupled to purified GABA-transaminase does produce GABA from GHB at an optimum pH close to the physiological value and with a low Km for GHB.     

Conversion of γ-Hydroxybutyrate to γ-Aminobutyrate In Vitro

[3H]gamma-Hydroxybutyric acid [( 3H]GHB) at physiological concentration incubated with brain slices in Krebs-Ringer medium produced [3H]gamma-aminobutyric acid [( 3H]GABA). This compound was identified by its Rf values on thin-layer chromatograms and by analysis of the dansyl derivatives of the free amino acid fraction. No labelled glutamate could be detected. Brain slices incubated with labelled glutamate and nonradioactive GHB generated labelled 2-oxoglutarate, suggesting that gamma-aminobutyrate-2-oxoglutarate transaminase (GABA-T) is involved in catalyzing this reaction. Furthermore, specific inhibitors of GABA-T blocked the production of labelled GABA from labelled GHB and of labelled 2-oxoglutarate from labelled glutamate. Transformation of [3H]GHB into [3H]GABA was not inhibited by malonate, demonstrating that the succinate-linked pathway is not involved in the generation of GABA. The kinetic characteristics of the multienzyme system involved in GHB degradation studied in vitro are compatible with the production of GABA in vivo.     

Effect of Anticonvulsant Drugs on 7-Hydroxybutyrate Release from Hippocampal Slices: Inhibition by Valproate and Ethosuximide

The effects of some anticonvulsant drugs have been investigated on gamma-hydroxybutyrate release from rat hippocampal and striatal slices. Sodium valproate and ethosuximide inhibited the depolarization-evoked release of gamma-hydroxybutyrate induced by 40 mM K+. The IC50 values for these two drugs are in the concentration range of valproate and ethosuximide that exists in rat brain after administration of anticonvulsant doses to the animals. Trimethadione and pentobarbital are without significant effects. It can be concluded that the inhibition of gamma-hydroxybutyrate release, particularly that observed for hippocampus, might explain the protective effect of valproate and ethosuximide on gamma-hydroxybutyrate-induced seizures and perhaps on other kinds of epileptoid phenomenon.     

Diverse University Students Across the United States Reveal Promising Pathways to Hunter Recruitment and Retention

Declining participation in hunting, especially among young adult hunters, affects the ability of state and federal agencies to achieve goals for wildlife management and decreases revenue for conservation. For wildlife agencies hoping to engage diverse audiences in hunter recruitment, retention, and reactivation (R3) efforts, university settings provide unique advantages: they contain millions of young adults who are developmentally primed to explore new activities, and they cultivate a social atmosphere where new identities can flourish. From 2018 to 2020, we surveyed 17,203 undergraduate students at public universities across 22 states in the United States to explore R3 potential on college campuses and assess key demographic, social, and cognitive correlates of past and intended future hunting behavior. After weighting to account for demographic differences between our sample and the larger student population, 29% of students across all states had hunted in the past. Students with previous hunting experience were likely to be white, male, from rural areas or hunting families, and pursuing degrees related to natural resources. When we grouped students into 1 of 4 categories with respect to hunting (i.e., non-hunters [50%], potential hunters [22%], active hunters [26%], and lapsed hunters [3%]), comparisons revealed differences based on demographic attributes, beliefs, attitudes, and behaviors. Compared to active hunters, potential hunters were more likely to be females or racial and ethnic minorities, and less likely to experience social support for hunting. Potential hunters valued game meat and altruistic reasons for hunting, but they faced unique constraints due to lack of hunting knowledge and skills. Findings provide insights for marketing and programming designed to achieve R3 objectives with a focus on university students. © 2021 The Wildlife Society.     

γ-Hydroxybutyrate Stimulation of the Formation of Cyclic GMP and Inositol Phosphates in Rat Hippocampal Slices

The presence of gamma-hydroxybutyrate (GHB) (300-600 microM) in the incubation medium of rat hippocampal slices led to an increase of intracellular cyclic GMP and inositol phosphates. This phenomenon is dependent on the time and the dose of GHB used and might be the result of the stimulation of GHB receptor sites which are abundant in rat hippocampus. The increase of cyclic GMP and inositol phosphates is blocked by some anticonvulsants and opiate antagonists. These results seems to indicate that, like many substances inducing epileptic phenomena, GHB provokes neuronal depolarization in hippocampus which is accompanied by formation of cyclic GMP and inositol phosphates. The effect of opiate antagonists can be explained by the possible implication of an opiate synapse which mediates GHB effects in rat hippocampus.