Alexander V. Sirotkin scite author profile

Previous studies have shown that microRNAs (miRNAs) can control steroidogenesis in cultured granulosa cells. In this study we wanted to determine if miRNAs can also affect proliferation and apoptosis in human ovarian cells. The effect of transfection of cultured primary ovarian granulosa cells with 80 different constructs encoding human pre-miRNAs on the expression of the proliferation marker, PCNA, and the apoptosis marker, Bax was evaluated by immunocytochemistry. Eleven out of 80 tested miRNA constructs resulted in stimulation, and 53 miRNAs inhibited expression of PCNA. Furthermore, 11 of the 80 miRNAs tested promoted accumulation of Bax, while 46 miRNAs caused a reduction in Bax in human ovarian cells. In addition, two selected antisense constructs that block the corresponding miRNAs mir-15a and mir-188 were evaluated for their effects on expression of PCNA. An antisense construct inhibiting mir-15a (which precursor suppressed PCNA) increased PCNA, whereas an antisense construct for mir-188 (which precursor did not change PCNA) did not affect PCNA expression. Verification of effects of selected pre-mir-10a, mir-105, and mir-182 by using other markers of proliferation (cyclin B1) and apoptosis (TdT and caspase 3) confirmed specificity of miRNAs effects on these processes. This is the first direct demonstration of the involvement of miRNAs in controlling both proliferation and apoptosis by ovarian granulose cells, as well as the identification of miRNAs promoting and suppressing these processes utilizing a genome-wide miRNA screen.

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Identification of MicroRNAs controlling human ovarian cell steroidogenesis via a genome‐scale screen

Sirotkin

Ovcharenko

Großmann³

et al. 2009

Journal Cellular Physiology

193

123

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The aim of our studies was to identify miRNAs affecting the release of the major ovarian steroid hormones progestagen, androgen and estrogen by human ovarian cells. The effect of transfection of cultured primary ovarian granulosa cells with 80 different gene constructs encoding human pre-miRNAs on release of progesterone, testosterone and estradiol was evaluated by enzyme immunoassay. In addition, effect of two selected antisense constructs blocking corresponding miRNA on progesterone release was tested. Efficiency of transfection (incorporation transfection reagent) and silencing of marker substances (GAPDH mRNA, GAPDH and CREB-1) were validated by fluorescent microscopy, real-time reverse transcription-PCR analysis and immunocytochemical analysis. Thirty-six out of 80 tested miRNA constructs resulted in inhibition of progesterone release in granulosa cells, and 10 miRNAs promoted progesterone release. Transfected of cells with antisense constructs to two selected miRNAs blocking progesterone release induced increase in progesterone output. Fifty-seven miRNAs tested inhibited testosterone release, and only one miRNA enhanced testosterone output. Fifty-one miRNAs suppressed estradiol release, while none of the miRNAs tested stimulated it. This is the first demonstration that miRNAs can control reproductive functions resulting in enhanced or inhibited release of ovarian progestagen, androgen and estrogen. We hypothesize that such miRNA-mediated effects could be potentially used for regulation of reproductive processes, including fertility, and for treatment of reproductive and other steroid-dependent disorders.

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Effects of Chronic Hyperghrelinemia on Puberty Onset and Pregnancy Outcome in the Rat

et al. 2005

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Ghrelin, the endogenous ligand of the GH secretagogue receptor, has been recently involved in a wide array of biological functions, including signaling of energy insufficiency and energy homeostasis. On the basis of the proven reproductive effects of other regulators of energy balance, such as the adipocyte-derived hormone leptin, we hypothesized that systemic ghrelin may participate in the control of key aspects of reproductive function. To test this hypothesis, the effects of daily treatment with ghrelin were assessed in rats, pair-fed with control animals, in two relevant reproductive states, puberty and gestation, which are highly dependent on proper energy stores. Daily sc injection of ghrelin (0.5 nmol/12 h; between postnatal d 33 and 43) significantly decreased serum LH and testosterone levels and partially prevented balano-preputial separation (as an external index of puberty onset) in pubertal male rats. On the contrary, chronic administration of ghrelin to prepubertal females, between postnatal d 23 and 33, failed to induce major changes in serum levels of gonadotropins and estradiol, nor did it modify the timing of puberty, as estimated by the ages at vaginal opening and first estrus. Moreover, females treated with ghrelin at puberty subsequently displayed normal estrous cyclicity and were fertile. Conversely, ghrelin administration (0.5 nmol/12 h) during the first half of pregnancy (d 1-11) resulted in a significant decrease in pregnancy outcome, as estimated by the number of pups born per litter, without changes in the number of successful pregnancies at term or gestational length. Overall, our data indicate that persistently elevated ghrelin levels, as a putative signal for energy insufficiency, may operate as a negative modifier of key reproductive states, such as pregnancy and (male) puberty onset.

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