| Summary: | Clinical studies demonstrated that the ovarian hormone 17β-estradiol (E<sub>2</sub>) is neuroprotective within a narrow window of time following menopause, suggesting that there is a biological switch in E<sub>2</sub> action that is temporally dependent. However, the molecular mechanisms mediating this temporal switch have not been determined. Our previous studies focused on microRNAs (miRNA) as one potential molecular mediator and showed that E<sub>2</sub> differentially regulated a subset of mature miRNAs which was dependent on age and the length of time following E<sub>2</sub> deprivation. Notably, E<sub>2</sub> significantly increased both strands of the miR-9 duplex (miR-9-5p and miR-9-3p) in the hypothalamus, raising the possibility that E<sub>2</sub> could regulate miRNA stability/degradation. We tested this hypothesis using a biochemical approach to measure miRNA decay in a hypothalamic neuronal cell line and in hypothalamic brain tissue from a rat model of surgical menopause. Notably, we found that E<sub>2</sub> treatment stabilized both miRNAs in neuronal cells and in the rat hypothalamus. We also used polysome profiling as a proxy for miR-9-5p and miR-9-3p function and found that E<sub>2</sub> was able to shift polysome loading of the miRNAs, which repressed the translation of a predicted miR-9-3p target. Moreover, miR-9-5p and miR-9-3p transcripts appeared to occupy different fractions of the polysome profile, indicating differential subcellular. localization. Together, these studies reveal a novel role for E<sub>2</sub> in modulating mature miRNA behavior, independent of its effects at regulating the primary and/or precursor form of miRNAs.
|
|---|
