The absence of a functional nuclear receptor element A (NREA) in the promoter II of the aromatase P450 gene in rabbit granulosa cells

Estrogen disorders: Interpreting the abnormal regulation of aromatase in granulosa cells (Review)

Ovarian granulosa cells (GCs) are the most important source of estrogen. Therefore, aromatase (estrogen synthase), which is the key enzyme in estrogen synthesis, is not only an important factor of ovarian development, but also the key to estrogen secretion by GCs. Disorders of the ovarian estrogen secretion are more likely to induce female estrogen-dependent diseases and fertility issues, such as ovarian cancer and polycystic ovary syndrome. Hence, aromatase is an important drug target; treatment with its inhibitors in estrogen-dependent diseases has attracted increasing attention. The present review article focuses on the regulation and mechanism of the aromatase activity in the GCs, as well as the specific regulation of aromatase promoters. In GCs, follicle-stimulating hormone (FSH) is dependent on the cyclic adenosine monophosphate (cAMP) pathway to regulate the aromatase activity, and the regulation of this enzyme is related to the activation of signaling pathways, such as phosphatidylinositol 3-kinase (PI3K) and extracellular signal-regulated kinase (ERK). In addition, endocrine-disrupting substance and other related factors affect the expression of aromatase, which eventually create an imbalance in the estrogen secretion by the target tissues. The present review highlights these useful factors as potential inhibitors for target therapy.

miR-326 down-regulate CYP19A1 expression and estradiol-17b production in buffalo granulosa cells through CREB and C/EBP-β

Ovarian granulosa cells, known to be endocrine cells, have well active TLR4-/NFKB signalling mediated innate immune capabilities. We have previously shown that endotoxin not only transiently regulates proinflammatory cytokines but cells become tolerant on repeated exposure to endotoxin and impaired granulosa cells functions, which includes downregulation of CYP19A1 gene. To understand further endotoxin tolerance and impaired granulosa cells function, genome-wide transcriptomic profiling in endotoxin tolerant buffalo granulosa cells (bGCs) identified miR-326 as upregulated amongst top 5 DE miRNAs [unpublished data] and qPCR validation confirmed its upregulation during endotoxin tolerance. In silico analyses showed that miR-326 targets CYP19A1 gene. Therefore, in the present study, we elucidated the role of miR-326 in buffalo granulosa cells (bGCs). We first validated its expression vis-à-vis CYP19A1 gene expression in bGCs, both in vivo and in vitro. Results showed an inverse relationship between miR-326 and CYP19A1 expression. Similarly, transcription factors, known to be involved in CYP19A1 gene regulation, CREB and C/EBP-β expression was also found to be decreased in granulosa cells mimicking pre-ovulatory follicular stage. Further, miR-326 mimic was transfected to bGCs in culture and expression of CYP19A1 and CREB & C/EBP-β and genes encoding other enzymes of steroidogenesis pathway were also analyzed. The present study results showed that miR-326 significantly inhibits the expression of CYP19A1 gene while expression of transcription factors CREB and C/EBP-β was found to be upregulated. The expression of STAR and CYP11A1 was found to be unaffected. To elucidate the molecular mechanism of miR-326 mediated downregulation of CYP19A1, binding analyses of RNA polymerase II and CEBP-β to CYP19A1 gene promoter II was analyzed. The result also showed decreased binding of RNA polymerase II with increased binding of CEBP-β to CYP19A1 gene promoter II in bGCs, transfected with miR-326 as compared to control. In summary, our results suggest that miR-326 upregulate CREB and CREB may activate C/EBP-β and later inhibited the transcription of CYP19A1 and decreased estradiol-17b production. The miR-326 mediated down-regulation of the CYP19A1 gene involving CREB-C/EBP-β can be exploited in developing strategies to attenuate endotoxin-mediated tolerance induced impaired granulosa cells function to ensure proper fertility in females.

Lipodystrophy and severe metabolic dysfunction in mice with adipose tissue-specific insulin receptor ablation

OBJECTIVE

Insulin signaling plays pivotal roles in the development and metabolism of many tissues and cell types. A previous study demonstrated that ablation of insulin receptor (IR) with aP2-Cre markedly reduced adipose tissues mass and protected mice from obesity. However, multiple studies have demonstrated widespread non-adipocyte recombination of floxed alleles in aP2-Cre mice. These findings underscore the need to re-evaluate the role of IR in adipocyte and systemic metabolism with a more adipose tissue-specific Cre mouse line.

METHODS

We generated and phenotyped a new adipose tissue-specific IR mouse model using the adipose tissue-specific Adipoq-Cre line.

RESULTS

Here we show that the Adipoq-Cre-mediated IR KO in mice leads to lipodystrophy and metabolic dysfunction, which is in stark contrast to the previous study. In contrast to white adipocytes, absence of insulin signaling does not affect development of marrow and brown adipocytes, but instead is required for lipid accumulation particularly for the marrow adipocytes. Lipodystrophic IR KO mice have profound insulin resistance, hyperglycemia, organomegaly, and impaired adipokine secretion.

CONCLUSIONS

Our results demonstrate differential roles for insulin signaling for white, brown, and marrow adipocyte development and metabolic regulation.

Involvement of transcription factor GATA-4 in regulation of CYP19 gene during folliculogenesis and luteinization in buffalo ovary

CYP19 gene encode aromatase, the key enzyme of estrogen biosynthesis, is regulated in species- and tissue-specific manner by alternate use of different promoters. Previously, we have reported the cloning and characterization of tissue-specific promoter and transcripts in buffalo ovary and placenta. In human and rat ovary, FSH induces the phosphorylation of transcription factor CREB (cAMP response element binding protein) through PKA pathway which binds to cAMP response element like sequence (CLS) in CYP19 gene ovarian promoter. However, in buffalo as well as in bovine, in silico analysis of ovary specific promoter sequence identified a single base pair deletion in CLS site and is designated as CLS-like sequence. To understand if CLS with a point mutation is still a functional cis-element and is involved in FSH stimulated transactivation of CYP19 gene in buffalo ovary, the present study was thus aimed to functionally characterize the role of buffalo CLS in CYP19 gene transactivation. We also studied the involvement of GATA-4, having consensus binding sites in CYP19 gene ovarian promoter in the vicinity of CLS during different stages of the buffalo estrus cycle. Reporter construct analyses and EMSA results showed that CLS is playing no significant role in CYP19 gene regulation in buffalo ovary. Real time absolute quantification of GATA-4 showed the differential expression of GATA-4 mRNA during folliculogenesis and luteinization with significantly higher transcript abundance in large follicle in comparison to other tissues. Western blot analysis of granulosa cells nuclear protein isolated from different stage of follicular development (small and large follicles) and differentiation (corpus luteum) showed that abundance of phosphorylated GATA-4 (Ser261) was significantly higher in granulosa cell nuclear protein of large follicles as compared to small follicles and corpora lutea. Interestingly, binding studies using ChIP showed significantly enhanced binding to the CYP19 gene promoter in large follicle which was seen to be declined in the luteal tissue. Similar results were obtained in the in vitro experiments as well. Finally, RNAi experiments were performed to validate the involvement of GATA-4 in CYP19 gene regulation. Results of RNAi showed that knockdown of GATA-4 mRNA significantly declined CYP19 gene mRNA as well as 17β-estradiol contents. In conclusion, result of the present study indicated that that in the absence of consensus CRE (cAMP response element); GATA-4 could be a downstream effector of cAMP/PKA pathway in regulation of CYP19 gene during folliculogenesis and luteinization.

cAMP-dependent regulation of CYP19 gene in rabbit preovulatory granulosa cells and corpus luteum

Transcription of the CYP19 gene encoding the aromatase P450 enzyme in ovarian cells is under the control of the two gonadotropins, follicle stimulating hormone (FSH) and luteinizing hormone (LH), via modulation of intracellular cyclic 3',5'-adenosine monophosphate (cAMP) levels. Primary cultures of rabbit ovarian cells were used to identify the functional regions of the ovarian promoter (PII) that are responsive to the gonadotropic secondary messenger and to estradiol. Transfection experiments in granulosa and luteal cells with deleted constructs of the PII promoter show that the region between -274 and -193bp is critical for cAMP-dependent transcriptional activity. A comparison of PII activities in granulosa and small luteal cells highlights a 50% decrease consecutive to the LH surge. Sequence analysis of the above mentioned region revealed the presence of a cAMP responsive element like sequence (CLS) and of a nuclear receptor element A (NREA). Binding of CREB to CLS has been shown using granulosa and luteal cells nuclear extracts. In addition, we identified the expression of NR5A1 (Steroidogenic Factor 1) and NR5A2 (Liver Receptor Homologue 1) in granulosa and luteal cells. However, the binding to NREA is observed only with granulosa cells nuclear extracts. Data suggest that the NR5A factors are not the main regulators of CYP19 gene, in contrast with the others genes of streroidogenesis enzymes, and additional sites may play an important role during the post-LH surge down-regulation of CYP19 transcription.