Alcohol consumption induces global gene expression changes in VTA dopaminergic neurons.

Alcoholism is associated with dysregulation in the neural circuitry that mediates motivated and goal-directed behaviors. The dopaminergic (DA) connection between the ventral tegmental area (VTA) and the nucleus accumbens is viewed as a critical component of the neurocircuitry mediating alcohol's rewarding and behavioral effects. We sought to determine the effects of binge alcohol drinking on global gene expression in VTA DA neurons. Alcohol-preferring C57BL/6J × FVB/NJ F1 hybrid female mice were exposed to a modified drinking in the dark (DID) procedure for 3 weeks, while control animals had access to water only. Global gene expression of laser-captured tyrosine hydroxylase (TH)-positive VTA DA neurons was measured using microarrays. A total of 644 transcripts were differentially expressed between the drinking and nondrinking mice, and 930 transcripts correlated with alcohol intake during the last 2 days of drinking in the alcohol group. Bioinformatics analysis of alcohol-responsive genes identified molecular pathways and networks perturbed in DA neurons by alcohol consumption, which included neuroimmune and epigenetic functions, alcohol metabolism and brain disorders. The majority of genes with high and specific expression in DA neurons were downregulated by or negatively correlated with alcohol consumption, suggesting a decreased activity of DA neurons in high drinking animals. These changes in the DA transcriptome provide a foundation for alcohol-induced neuroadaptations that may play a crucial role in the transition to addiction.

In situ coexpression of glucose and monocarboxylate transporter mRNAs in metabolic-sensitive caudal dorsal vagal complex catecholaminergic neurons: transcriptional reactivity to insulin-induced hypoglycemia and caudal hindbrain glucose or lactate repletion during insulin-induced hypoglycemia.

The neurochemical phenotype(s) of metabolic sensing neurons in the dorsal vagal complex (DVC) remains unclear. These studies utilized single-cell quantitative real-time RT-PCR, in conjunction with laser-catapult microdissection, to address the hypothesis that DVC A2 neurons express genes that encode the characterized metabolic transducers, e.g. glucokinase (GCK) and the energy-dependent potassium channel, K(ATP). Studies show that either glucose or lactate alters synaptic firing of DVC chemosensory neurons, and that delivery of the latter fuel into the caudal hindbrain amplifies insulin-induced hypoglycemia (IIH) and elevates neuronal glucose and monocarboxylate transporter, GCK, and sulfonylurea-1 mRNA in the DVC. We thus examined the additional premise that IIH modifies A2 substrate transporter and metabolic transducer gene profiles, and that such transcriptional responses may be reversed by exogenous lactate and/or glucose. Individual tyrosine hydroxylase (TH)-immunoreactive (-ir) A2 neurons were microdissected from the caudal DVC 2 h after injection of insulin or saline, and continuous caudal fourth ventricular (CV4) infusion of lactate, glucose, or artificial cerebrospinal fluid. The data show that IIH decreased MCT2, but elevated GLUT3, GLUT4, GCK, and SUR-1 transcripts in A2 neurons. Blood glucose levels in insulin-injected rats were further reduced by CV4 infusion of either lactate or glucose. Lactate plus insulin reversed hypoglycemic reductions in MCT2 mRNA and further augmented GLUT3 transcripts in A2 neurons, whereas glucose infusion in insulin-injected rats further increased GLUT3 and GCK gene profiles. The present results demonstrate that caudal DVC A2 neurons express molecular markers for metabolic sensing, and genes that encode glucose and monocarboxylate transporters. Evidence that IIH reduces A2 MCT2, but elevates GLUT3 and GLUT4 gene profiles suggests that glucose may be a primary energy source to these cells during hypoglycemia, while decreased lactate uptake, alone or relative to glucose uptake, may be a critical manifestation of systemic glucose deficiency at the cellular level. Findings that singular fuel repletion does not normalize hypoglycemic patterns of glucose transporter, GCK, or SUR-1 mRNA expression in A2 neurons imply that sufficient supply of both energy substrates is required for metabolic balance, and that cellular adaptation to the prevalence of either fuel may increase cellular dependence on glucose-specific metabolites or other products.