Deficiency of somatostatin (SST) receptor type 5 (SSTR5) is associated with sexually dimorphic changes in the expression of SST and SST receptors in brain and pancreas.

The actions of somatostatin (SST) are mediated through five somatostatin receptor subtypes, termed SSTR1-5. Although SSTRs commonly display an overlapping pattern of tissue distribution, subtype-selective responses have been shown to occur in the same tissue. In the present study, we have investigated the changes in SSTR subtypes at the cellular and molecular level in both the brain and the pancreatic islets of mice deficient in SSTR5 (SSTR5KO). Expression levels of insulin and glucagon were also determined in the pancreas of these mice. Semi-quantitative RT-PCR and Western blot analysis showed significant increases in the expression of SSTR2 and 3 with a corresponding reduction in SSTR4 in the brains of female SSTR5KOs, while no changes were observed in male KOs. Strikingly, SST mRNA and SST-like immunoreactivity (SST-LI) were reduced in the brain of male KO animals but not in their female counterparts. In male SSTR5KO islets, there was an increase in the number of cells immunoreactive for SSTR1-3, whereas in female islets only SSTR3 expression was increased. Pancreatic SST-LI and SST mRNA, as well as immunoreactivity for insulin were reduced in male but not in female KO mice. These data indicate that deficiency of SSTR5 leads to subtype-selective sexually dimorphic changes in the expression of both brain and pancreatic SSTRs.

Reproductive functions of the progesterone receptor isoforms: lessons from knock-out mice.

Progesterone plays a central coordinate role in diverse reproductive events associated with establishment and maintenance of pregnancy. In humans and other vertebrates, the biological activities of progesterone are mediated by two proteins, A (PR-A) and B (PR-B) that arise from the same gene and function as progesterone activated transcription factors that exhibit different transcription regulatory activities in vitro. Mice lacking both PR isoforms (PRKO mice) exhibit pleiotropic reproductive abnormalities. To address the physiological role of the individual isoforms, we have selectively ablated PR-A expression in mice (PRAKO). We have demonstrated that PR-B mediates a subset of the reproductive functions of P. Ablation of PR-A does not affect responses of the mammary gland or thymus to P but results in severe abnormalities in ovarian and uterine function. Analysis of urine function of PRAKP mice reveals an unexpected P-dependent proliferative activity of PR-B in the epithelium and provides evidence that the tissue-specific reproductive effects of this isoform are due to specificity of target gene transactivation rather than differences in tissue-specific expression relative to PR-A. Taken together, our data indicate that PR-A and PR-B act in vivo as two functionally distinct transcription factors.

Reproductive functions of the progesterone receptor.

Progesterone plays a central coordinate role in regulating reproductive events associated with the establishment and maintenance of pregnancy including ovulation, uterine and mammary gland development and tumorigenesis, and neurobehavioral expression associated with sexual responsiveness. The effects of progesterone are mediated by two receptor proteins (PR), termed A and B, that arise from a single gene and act as ligand-activated transcription factors to regulate the expression of reproductive target genes. Null mutation of both proteins in mice leads to pleiotropic reproductive abnormalities. This review summarizes the structure and functional properties of the PR isoforms and how functional differences between these proteins are likely to impact on the overall physiologic role of the receptor in reproductive systems.

Nurr1 is essential for the induction of the dopaminergic phenotype and the survival of ventral mesencephalic late dopaminergic precursor neurons.

Nurr1 is a member of the nuclear receptor superfamily of transcription factors that is expressed predominantly in the central nervous system, including developing and mature dopaminergic neurons. Recent studies have demonstrated that Nurr1 is essential for the induction of phenotypic markers of ventral mid-brain dopaminergic neurons whose generation is specified by the floor plate-derived morphogenic signal sonic hedgehog (SHH), but the precise role of Nurr1 in this differentiative pathway has not been established. To provide further insights into the role of Nurr1 in the final differentiation pathway, we have examined the fate of dopamine cell precursors in Nurr1 null mutant mice. Here we demonstrate that Nurr1 functions at the later stages of dopamine cell development to drive differentiation of ventral mesencephalic late dopaminergic precursor neurons. In the absence of Nurr1, neuroepithelial cells that give rise to dopaminergic neurons adopt a normal ventral localization and neuronal phenotype characterized by expression of the homeodomain transcription factor and mesencephalic marker, Ptx-3, at embryonic day 11.5. However, these late precursors fail to induce a dopaminergic phenotype, indicating that Nurr1 is essential for specifying commitment of mesencephalic precursors to the full dopaminergic phenotype. Further, as development progresses, these mid-brain dopamine precursor cells degenerate in the absence of Nurr1, resulting in loss of Ptx-3 expression and a concomitant increase in apoptosis of ventral midbrain neurons in newborn null mutant mice. Taken together, these data indicate that Nurr1 is essential for both survival and final differentiation of ventral mesencephalic late dopaminergic precursor neurons into a complete dopaminergic phenotype.