Analysis of spatiotemporal regulation of aromatase in the brain using transgenic mice

Brain aromatase is widely distributed in the vertebrates, from fish to mammals, and plays important roles in functional reproductive behavior through production of estrogen as a neurosteroid. It is expressed only in the nerve cells of specific brain regions with a transient peak in the neonatal period when sexual behavior becomes organized, and therefore provides a good model system to study regulatory mechanism of cell-specific, brain region-specific, and developmental stage-specific expression.

To elucidate spatiotemporal regulation of brain aromatase, we prepared transgenic mice carrying a reporter gene under the promoter of brain-specific exon 1f of the mouse aromatase gene. The reporter transgene carrying a 6.5 kb upstream region of the brain-specific promoter accurately reproduced the spatiotemporal expression patterns of aromatase in mouse brain, whereas transgenes carrying smaller fragments of the promoter showed ambiguous or inconsistent expression patterns.

The binding sites of Aro-AI, Aro-AII, and Aro-B for nuclear factors were also identified in the proximal region of the exon 1f brain-specific promoter. Introduction of a mutation into the Aro-AII site in the reporter transgene carrying −6.5 kb promoter region of exon 1f caused complete alteration of the spatiotemporal expression pattern of the reporter gene in the transgenic mice.

These results indicate that the −6.5 kb promoter region of exon 1f is the minimal essential element for brain-specific regulation, with both proximal and distal promoter regions required for accurate spatiotemporal expression of aromatase in the mouse brain.     

SnoN co-repressor binds and represses smad7 gene promoter

SnoN and Ski oncoproteins are co-repressors for Smad proteins and repress TGF-beta-responsive gene expression. The smad7 gene is a TGF-beta target induced by Smad signaling, and its promoter contains the Smad-binding element (SBE) required for a positive regulation by the TGF-beta/Smad pathway. SnoN and Ski co-repressors also bind SBE but regulate negatively smad7 gene. Ski along with Smad4 binds and represses the smad7 promoter, whereas the repression mechanism by SnoN is not clear. Ski and SnoN overexpression inhibits smad7 reporter expression induced through TGF-beta signaling. Using chromatin immunoprecipitation assays, we found that SnoN binds smad7 promoter at the basal condition, whereas after a short TGF-beta treatment for 15-30 min SnoN is downregulated and no longer bound smad7 promoter. Interestingly, after a prolonged TGF-beta treatment SnoN is upregulated and returns to its position on the smad7 promoter, functioning probably as a negative feedback control. Thus, SnoN also seems to regulate negatively the TGF-beta-responsive smad7 gene by binding and repressing its promoter in a similar way to Ski.     

Characterization and purification of a protein binding to the cis-acting element for brain-specific exon 1 of the mouse aromatase gene

The functional differences between male and female brains commit to the existence of androgen that the testis secretes during the perinatal period. Androgen exerts its action on the brain after conversion to estrogen by brain aromatase. The aromatase appears in some neural nuclei such as in the hypothalamus and amygdala, and has been indicated to be involved in the expression of sexuality by the results of neurobehavioral analyses involving aromatase-knockout mice. We analyzed the brain-specific promoter in order to clarify the control mechanism for the expression of brain aromatase, which is deeply concerned in the sexual differentiation of the brain. The 202 bp upstream region of brain-specific exon 1 contains at least three kinds of cis-acting elements, Arom-A, -Aβ and -B. In particular, the binding activities as to the Aβ sequence show a tissue-specific pattern. Gel shift analysis revealed that the Aβ binding factor recognizes the TTGGCCCCT sequence. Aβ binding activity is detectable at the perinatal stage, but is undetectable at the adult stage in the brain. Furthermore, a protein which binds to the Aβ sequence was purified from the fetal mouse brain. The molecular mass of the Aβ binding protein was estimated to be 49 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Characterization and purification of a protein binding to the cis-acting element for brain-specific exon 1 of the mouse aromatase gene

The functional differences between male and female brains commit to the existence of androgen that the testis secretes during the perinatal period. Androgen exerts its action on the brain after conversion to estrogen by brain aromatase. The aromatase appears in some neural nuclei such as in the hypothalamus and amygdala, and has been indicated to be involved in the expression of sexuality by the results of neurobehavioral analyses involving aromatase-knockout mice. We analyzed the brain-specific promoter in order to clarify the control mechanism for the expression of brain aromatase, which is deeply concerned in the sexual differentiation of the brain. The 202 bp upstream region of brain-specific exon 1 contains at least three kinds of cis-acting elements, Arom-Aα, -Aβ and -B. In particular, the binding activities as to the Aβ sequence show a tissue-specific pattern. Gel shift analysis revealed that the Aβ binding factor recognizes the TTGGCCCCT sequence. Aβ binding activity is detectable at the perinatal stage, but is undetectable at the adult stage in the brain. Furthermore, a protein which binds to the Aβ sequence was purified from the fetal mouse brain. The molecular mass of the Aβ binding protein was estimated to be 49 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

The effects of mouse ovarian granulosa cell function and related gene expression by suppressing BMP/Smad signaling pathway

BMP I type receptor inhibitor can selectively inhibit BMP/Smad signaling pathways, mainly by inhibiting the BMP I type receptor activity to prevent phosphorylation of Smad1, Smad5 and Smad9. The aim of the present study was to explore the effects of mouse ovarian granulosa cell function and related gene expression by suppressing BMP/Smad signaling pathway with LDN-193189(A type of BMP I type receptor inhibitor). In this study, we cultivate the original generation of mouse ovarian granular cells then collect cells and cell culture medium after treatment. Cellular localization and expression of Smad9 and P-smad9 proteins was studied by immunofluorescence (IF) in the ovarian granulosa cells of mouse; Related genes mRNA and proteins expression was checked by QRT-PCR and Western blot; Detected the concentration of related hormones by using ELISA kit; finally, the growth of the cells was analyzed by plotting cell growth curve with CCK-8 assay. The results indicate that, suppression of BMP/Smad signaling pathway can inhibit the expression of LHR and FSHR, inhibit cell proliferation and decrease E₂ secretion, the mechanism of action maybe reduce the expression of smad9, at the same time, we found that the feedback regulation of smad9 may affect the expression of FSHR and cell proliferation.