Both Notch and NFkappaB signaling pathways are well-known for regulating proliferation, differentiation and apoptosis. Recent studies have presented several lines of evidence supporting an integration of the Notch and NFkappaB signaling pathways in differentiation/maturation of a diverse range of cell types. It is notable that Notch and NFkappaB signaling pathways share many common features: (i) both are activated by common stimuli such as TNF-alpha and hypoxia, (ii) activated Notch (NICD) and NFkappaB mediate transcription by regulating corepressors such as SMRT/N-COR, and (iii) both regulate similar target genes such as Hes-1 and IkappaBalpha. This review expands on how the collaboration between these pathways may play an important role in the CNS. We will speculate on the mechanisms by which Notch and NFkappaB signaling may collaborate to regulate stem cell renewal and differentiation during brain development and function.
We are using transgenic mice to study the regulation of the bovine vasopressin (VP) and oxytocin (OT) genes. Prompted by the observation that mice bearing a bovine OT transgene express bovine OT RNA in their testes, we investigated the expression of the VP-OT locus in normal mice and cattle. Normal wild-type mice do not have detectable levels of either VP or OT RNA in their testes. Normal cattle are also devoid of detectable VP transcripts, but have relatively high levels of testicular OT RNA. Additionally, OT, but not VP, peptide is detectable by HPLC. In situ hybridization to RNA in bovine testicular tissue sections localized OT transcripts to seminiferous tubules, with a distribution similar to that of alpha-inhibin, suggesting expression in Sertoli cells. Interestingly, the bovine OT RNAs in the transgenic mouse testes were also shown by in situ hybridization to have the same distribution. These data suggest that the cis-acting regulatory sequences responsible for expression of the OT gene in bovine Sertoli testis reside within the limits of the transgene used in this study. Further, the trans-acting factors present in murine testicular cells are able to recognize these elements, although they do not express the endogenous mouse OT gene in this tissue.
We have used transgenic mice to analyse the regulation of the bovine vasopressin (BVP) gene. We find that the restriction of BVP gene expression to anatomically and functionally distinct hypothalamic neuronal groups is achieved, in part, by selective repression. The expression of a 1.25 kb BVP proximal promoter, which on its own confers general expression of a reporter to most peripheral and brain tissues, was limited by sequences in the BVP structural gene to neural cells in the adrenal medulla and brain. Transgene expression in the hypothalamus was shown to be regulated by the physiological stimulus of dehydration in parallel with the endogenous gene. The expression of a larger 13.4 kb BVP transgene, containing 9 kb of 5′ upstream sequence, the VP structural gene and 1.5 kb 3′ of the transcription unit, was even more restricted and resembles that of the endogenous mouse gene. Hypothalamic expression of the 13.4 kb BVP transgene was regulated appropriately in response to an osmotic challenge.
The bovine oxytocin gene has been expressed in the testes of two independent transgenic mouse lines. Hybridization and RNase protection analysis showed that the oxytocin transgene was transcribed from the normal functional promoter in the Sertoli cells of the seminiferous tubules in a developmentally regulated manner. Immunohistochemistry indicated that both oxytocin and neurophysin epitopes were expressed together in the Sertoli cells at stages I\p=n-\Vand X\p=n-\XIIof the cycle of the seminiferous epithelium. Furthermore, analysis with high-performance liquid chromatography showed that there was a tenfold increase in the amount of amidated oxytocin present in testicular extracts from the transgenic mice. However, there appeared to be no detectable effect of this overproduction of hormone on testicular morphology or fertility parameters. A significant decrease by 50% was detected only in the levels of intratesticular testosterone and dihydrotestosterone. The results point to a local paracrine role for oxytocin in the modulation of Leydig cell function.
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