Regulation of RGS proteins by chronic morphine in rat locus coeruleus.

The present study explored a possible role for RGS (regulators of G protein signalling) proteins in the long term actions of morphine in the locus coeruleus (LC), a brainstem region implicated in opiate physical dependence and withdrawal. Morphine influences LC neurons through activation of micro -opioid receptors, which, being Gi/o-linked, would be expected to be modulated by RGS proteins. We focused on several RGS subtypes that are known to be expressed in this brain region. Levels of mRNAs encoding RGS2, -3, -4, -5, -7, -8 and -11 are unchanged following chronic morphine, but RGS2 and -4 mRNA levels are increased 2-3-fold 6 h following precipitation of opiate withdrawal. The increases in RGS2 and -4 mRNA peak after 6 h of withdrawal and return to control levels by 24 h. Immunoblot analysis of RGS4 revealed a striking divergence between mRNA and protein responses in LC: protein levels are elevated twofold following chronic morphine and decrease to control values by 6 h of withdrawal. In contrast, levels of RGS7 and -11 proteins, the only other subtypes for which antibodies are available, were not altered by these treatments. Intracellular application of wild-type RGS4, but not a GTPase accelerating-deficient mutant of RGS4, into LC neurons diminished electrophysiological responses to morphine. The observed subtype- and time-specific regulation of RGS4 protein and mRNA, and the diminished morphine-induced currents in the presence of elevated RGS4 protein levels, indicate that morphine induction of RGS4 could contribute to aspects of opiate tolerance and dependence displayed by LC neurons.

Maternal behavior and developmental psychopathology.

This paper reviews recent developments in the phenomenology, neurobiology, and genetics of maternal behavior in animal model systems from an evolutionary perspective on psychopathology. Following a review of the phenomenology and neurobiology of maternal behavior, recent studies addressing the role of genetic factors in the maternal behavior of rodents were identified in a search of literature in peer-reviewed journals. Gene knockout studies were evaluated with regard to mouse strain background, method of behavioral phenotyping, and quantification of the behavioral deficits. Gene knockout data were then analyzed using a cluster analysis technique. At least nine genes have been identified that are necessary for the expression of one or more aspects of maternal behavior. These genes encode for three transcription factors: three enzymes, including dopamine beta hydroxylase and neuronal nitric oxide synthase; two receptors, including the prolactin and the estrogen alpha receptor; and one neuropeptide, oxytocin. Cluster analysis suggested possible relationships between specific genes. Gene knockout technology has provided new insights into the molecular basis of maternal behavior that are congruent with the existing neurobiological literature. Future studies of genetic and environmental influences on maternal behavior have the potential to inform models of disease pathogenesis.