Shameka Childress scite author profile

Shameka Childress

3Publications

136Citation Statements Received

0Citation Statements Given

How they've been cited

127

How they cite others

118

Affiliations

Pediatrics and Genetics, Johns Hopkins Medicine, Johns Hopkins University

Publications

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Low-Dose Dihydrotestosterone Drives Metabolic Dysfunction via Cytosolic and Nuclear Hepatic Androgen Receptor Mechanisms

Andrisse¹,

Childress²,

Ma³

et al. 2016

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Androgen excess in women is associated with metabolic dysfunction (e.g., obesity, hyperinsulinemia, insulin resistance, and increased risk of type 2 diabetes) and reproductive dysfunction (e.g., polycystic ovaries, amenorrhea, dysregulated gonadotropin release, and infertility). We sought to identify the effects of androgen excess on glucose metabolic dysfunction and the specific mechanisms of action by which androgens are inducing pathology. We developed a mouse model that displayed pathophysiological serum androgen levels with normal body mass/composition to ensure that the phenotypes were directly from androgens and not an indirect consequence of obesity. We performed reproductive tests, metabolic tests, and hormonal assays. Livers were isolated and examined via molecular, biochemical, and histological analysis. Additionally, a low-dose dihydrotestosterone (DHT) cell model using H2.35 mouse hepatocytes was developed to study androgen effects on hepatic insulin signaling. DHT mice demonstrated impaired estrous cyclicity; few corpora lutea in the ovaries; glucose, insulin, and pyruvate intolerance; and lowered hepatic insulin action. Mechanistically, DHT increased hepatic androgen-receptor binding to phosphoinositide-3-kinase (PI3K)-p85, resulting in dissociation of PI3K-p85 from PI3K-p110, leading to reduced PI3K activity and decreased p-AKT and, thus, lowered insulin action. DHT increased gluconeogenesis via direct transcriptional regulation of gluconeogenic enzymes and coactivators. The hepatocyte model recapitulated the in vivo findings. The DHT-induced hepatocyte insulin resistance was reversed by the androgen-receptor antagonist, flutamide. These findings present a phenotype (i.e., impaired glucose tolerance and disrupted glucose metabolism) in a lean hyperandrogenemia model (low-dose DHT) and data to support 2 molecular mechanisms that help drive androgen-induced impaired glucose metabolism.

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Androgen Receptor in the Ovary Theca Cells Plays a Critical Role in Androgen-Induced Reproductive Dysfunction

Andrisse

Chen

et al. 2016

Endocrinology

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Androgen and its receptor (AR) play a critical role in reproductive function under both physiological and pathophysiological conditions. Female AR global knockout mice are subfertile due to both neuroendocrine and ovarian defects. Female offspring from prenatally androgenized heterozygous AR pregnant mice showed rescued estrous cyclicity and fertility. Ar is expressed in granulosa cells, theca interstitial cells, and oocytes in the ovary. We created mice with theca-specific deletion of Ar (ThARKO) by crossing Cyp17-iCre mice that express Cre recombinase under cytochrome P450 17A1 (Cyp17) promoter with Arfl/fl mice. ThARKO mice exhibited no significant differences in pubertal onset or fertility compared with control littermates, and neither estrogen or testosterone levels were different between these groups. Therefore, Ar expression in theca cells likely does not influence fertility nor androgen levels in female mice. We then tested the role of AR in theca cells under hyperandrogenemic condition. After treatment with a pathophysiological level of dihydrotestosterone (DHT), control mice (control-DHT) showed acyclicity and infertility. However, estrous cycles and fertility were altered to a significantly less degree in ThARKO-DHT mice than in control-DHT mice. Messenger RNA (mRNA) levels of Lhcgr (luteinizing hormone receptor) and Timp1 (tissue inhibitor of metalloproteinase 1, and inhibitor of matrix metalloproteinase) were significantly lower in control-DHT ovary compared with control-no DHT ovaries, whereas mRNA levels of Fshr (follicle-stimulating hormone receptor) were significantly higher. Timp1 gene expression was comparable in the ThARKO-DHT and the control-no DHT ovary. We speculate that the preserved level of Timp1 in ThARKO-DHT mice contributes to retained reproductive function.

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Conditional Knockout of the Androgen Receptor in Ovarian Theca Cells Reveals Altered Steroidogenesis in Aged Mice

et al. 2015

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Women with polycystic ovary syndrome (PCOS) exhibit symptoms of hyperandrogenism, oligo/amenorrhea and polycystic ovaries. PCOS is also commonly associated with metabolic syndrome, hyperinsulimia, and insulin resistance in metabolic tissues. It has been reported that elevated androgen levels in women can lead to infertility; however the target organs impacted by the elevated androgen levels are not yet fully known. The aims of the study were to determine the role of androgen signaling in the ovary on the development and reproductive function. Our model system used the cre‐lox system to generate ovarian theca specific androgen receptor knockout (ThARKO) mice. This study examined puberty, cyclicity and fertility in female mice. There was no difference in the age of puberty between control and ThARKO littermates, assessed by the age of vaginal opening and first estrus. Cyclicity and fertility were also studied, and there were no significant differences between control and ThARKO mice. Ovarian gene expression and fertility were compared between 3 months old mice and 8 months old mice. We observed decreased cyp19 (aromatase) mRNA levels in both 3 and 8 moths old groups of the ThARKO compared to control littermates. However, cyp17 (rate limiting enzyme for androgen synthesis) mRNA expression was only significantly reduced (P<0.05) in 8 months old ThARKO mice compared to control littermates. Although fertility was not altered in ThARKO mice, the AR in theca cells may play a role in steroidogenesis of aged mice.

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