Altered gene expression in mice selected for high maternal aggression.

We previously applied selective breeding on outbred mice to increase maternal aggression (maternal defense). In this study, we compared gene expression within a continuous region of the central nervous system (CNS) involved in maternal aggression (hypothalamus and preoptic regions) between lactating selected (S) and nonselected control (C) mice (n= 6 per group). Using microarrays representing over 40,000 genes or expressed sequence tags, two statistical algorithms were used to identify significant differences in gene expression: robust multiarray and the probe logarithmic intensity error method. Approximately 200 genes were identified as significant using an intersection from both techniques. A subset of genes was examined for confirmation by real-time polymerase chain reaction (PCR). Significant decreases were found in S mice for neurotensin and neuropeptide Y receptor Y2 (both confirmed by PCR). Significant increases were found in S mice for neuronal nitric oxide synthase (confirmed by PCR), the K+ channel subunit, Kcna1 (confirmed by PCR), corticotrophin releasing factor binding protein (just above significance using PCR; P= 0.051) and GABA A receptor subunit 1A (not confirmed by PCR, but similar direction). S mice also exhibited significantly higher levels of the neurotransmitter receptor, adenosine A1 receptor and the transcription factors, c-Fos, and Egr-1. Interestingly, for 24 genes related to metabolism, all were significantly elevated in S mice, suggesting altered metabolism in these mice. Together, this study provides a list of candidate genes (some previously implicated in maternal aggression and some novel) that may play an important role in the production of this behavior.

Progesterone treatment of adult male rats suppresses arginine vasopressin expression in the bed nucleus of the stria terminalis and the centromedial amygdala.

The steroid sensitive vasopressin cells of the bed nucleus of the stria terminalis (BST) and centromedial amygdala (CMA) are involved in numerous behavioural and physiological functions. These cells are known to be greatly influenced by gonadal steroids. Castration reduces and testosterone replacement restores arginine vasopressin (AVP)-immunoreactive (-ir) labelling and AVP mRNA expression in the BST and CMA. Gonadal steroids appear to act directly in AVP-expressing cells within the BST and CMA, because the majority of AVP-ir cells in these areas contain oestrogen and androgen receptor immunoreactivity. Recently, we have localised progestin receptor immunoreactivity in virtually all of the AVP-ir cells in the BST and CMA. To understand the role played by progestin receptors in AVP cells within the BST and CMA, we treated male rats with 1 mg of progesterone or oil for 5 days, and then examined AVP immunoreactivity within the brain. We found that progesterone decreased AVP-ir labelling within the BST and CMA, as well as in two of the projection sites of these cells, the lateral septum and lateral habenula. Progesterone treatment did not alter testosterone secretion from the testes, nor did it alter adult male sexual behaviour. These data illustrate an additional mechanism by which the AVP cells in the BST and CMA can be regulated. These data also suggest that progesterone may act in the male brain to influence behaviours that are AVP-dependent.