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1. In vivo treatment with a non-aromatizable androgen rapidly alters the ovarian transcriptome of previtellogenic secondary growth coho salmon (Onchorhynchus kisutch)

   https://doi.org/10.1371/journal.pone.0311628  

   Monson, Christopher; Goetz, Giles; Forsgren, Kristy; Swanson, Penny; Young, Graham (October 2024, PLOS ONE)

   Schubert, Michael (Ed.)

   Recent evidence suggests that androgens are a potent driver of growth during late the primary stage of ovarian follicle development in teleosts. We have previously shown that the non-aromatizable androgen, 11-ketotestosterone (11-KT), both advances ovarian follicle growth in vivo and dramatically alters the primary growth ovarian transcriptome in coho salmon. Many of the transcriptomic changes pointed towards 11-KT driving process associated with the transition to a secondary growth phenotype. In the current study, we implanted previtellogenic early secondary growth coho salmon with cholesterol pellets containing 11-KT and performed RNA-Seq on ovarian tissue after 3 days in order to identify alterations to the ovarian transcriptome in early secondary growth. We identified 8,707 contiguous sequences (contigs) that were differentially expressed (DE) between control and 11-KT implanted fish and were able to collapse those to 3,853 gene-level IDs, more than a 3-fold more DE contigs than at the primary growth stage we reported previously. These contigs included genes encoding proteins involved in steroidogenesis, vitellogenin and lipid uptake, follicle stimulating hormone signaling, growth factor signaling, and structural proteins, suggesting androgens continue to promote previtellogenic secondary growth. 

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2. The Immp2l Mutation Causes Ovarian Aging Through ROS-Wnt/β-Catenin-Estrogen Pathway: Preventive Effect of Melatonin

   https://doi.org/10.1210/endocr/bqaa119  

   He, Qing; Gu, Lifang; Lin, Qingyin; Ma, Yi; Liu, Chunlian; Pei, Xiuying; Li, P Andy; Yang, Yanzhou (September 2020, Endocrinology)

   Abstract Mitochondria play important roles in ovarian follicle development. Mitochondrial dysfunction, including mitochondrial gene deficiency, impairs ovarian development. Here, we explored the role and mechanism of mitochondrial inner membrane gene Immp2l in ovarian follicle growth and development. Our results revealed that female Immp2l-/- mice were infertile, whereas Immp2l+/- mice were normal. Body and ovarian weights were reduced in the female Immp2l-/- mice, ovarian follicle growth and development were stunted in the secondary follicle stage. Although a few ovarian follicles were ovulated, the oocytes were not fertilized because of mitochondrial dysfunction. Increased oxidative stress, decreased estrogen levels, and altered genes expression of Wnt/β-catenin and steroid hormone synthesis pathways were observed in 28-day-old Immp2l-/- mice. The Immp2l mutation accelerated ovarian aging process, as no ovarian follicles were detected by age 5 months in Immp2l-/- mice. All the aforementioned changes in the Immp2l-/- mice were reversed by administration of antioxidant melatonin to the Immp2l-/- mice. Furthermore, our in vitro study using Immp2l knockdown granulosa cells confirmed that the Immp2l downregulation induced granulosa cell aging by enhancing reactive oxygen species (ROS) levels, suppressing Wnt16, increasing β-catenin, and decreasing steroid hormone synthesis gene cyp19a1 and estrogen levels, accompanied by an increase in the aging phenotype of granulosa cells. Melatonin treatment delayed granulosa cell aging progression. Taken together, Immp2l causes ovarian aging through the ROS-Wnt/β-catenin-estrogen (cyp19a1) pathway, which can be reversed by melatonin treatment. 

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3. Mixtures of phthalates disrupt expression of genes related to lipid metabolism and peroxisome proliferator-activated receptor signaling in mouse granulosa cells

   Hanin, Alahmadi; Stephanie, Martinez; Rivka, Farrell; Rafiatou, Bikienga; Nneka, Arinzeh; Courtney, Potts; Zhong, Li; Genoa, Warner (August 2024, Current research in toxicology)

   Jeffrey, Peters; Alison, Harrill; Kristine, Willett (Ed.)

   Phthalates are a class of known endocrine-disrupting chemicals that are found in common everyday products. Several studies associate phthalate exposure with detrimental effects on ovarian function, including growth and development of the follicle and production of steroid hormones. We hypothesized that dysregulation of the ovary by phthalates may be mediated by phthalate toxicity towards granulosa cells, a major cell type in ovarian follicles responsible for key steps of hormone production and nourishing the developing oocyte. To test the hypothesis that phthalates target granulosa cells, we harvested granulosa cells from adult CD-1 mouse ovaries and cultured them for 96 h in vehicle control, a phthalate mixture, or a phthalate metabolite mixture (0.1 to 100 μg/ml). After culture, we measured metabolism of the phthalate mixture into monoester metabolites by the granulosa cells, finding that granulosa cells do not significantly contribute to ovarian metabolism of phthalates. Immunohistochemistry of phthalate metabolizing enzymes in whole ovaries confirmed that these enzymes are not strongly expressed in granulosa cells of antral follicles and that ovarian metabolism of phthalates likely occurs primarily in the stroma. RNA sequencing of treated granulosa cells identified 407 differentially expressed genes, with overrepresentation of genes from lipid metabolic processes, cholesterol metabolism, and peroxisome proliferator-activated receptor (PPAR) signaling pathways. Expression of significantly differentially expressed genes related to these pathways was confirmed using qPCR. Our results agree with previous findings that phthalates and phthalate metabolites have different effects on the ovary, but both interfere with PPAR signaling in granulosa cells. 

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4. Mathematical recapitulation of the end stages of human ovarian aging

   https://doi.org/10.1126/sciadv.adj4490  

   Lawley, Sean D.; Sammel, Mary D.; Santoro, Nanette; Johnson, Joshua (January 2024, Science Advances)

   Ovarian aging in women can be described as highly unpredictable within individuals but predictable across large populations. We showed previously that modeling an individual woman’s ovarian reserve of primordial follicles using mathematical random walks replicates the natural pattern of growing follicles exiting the reserve. Compiling many simulations yields the observed population distribution of the age at natural menopause (ANM). Here, we have probed how stochastic control of primordial follicle loss might relate to the distribution of the preceding menopausal transition (MT), when women begin to experience menstrual cycle irregularity. We show that identical random walk model conditions produce both the reported MT distribution and the ANM distribution when thresholds are set for growing follicle availability. The MT and ANM are shown to correspond to gaps when primordial follicles fail to grow for 7 and 12 days, respectively. Modeling growing follicle supply is shown to precisely recapitulate epidemiological data and provides quantitative criteria for the MT and ANM in humans. 

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5. Does Rapamycin Delay Ovarian Aging and Decrease Senescence? A First-ever analysis in a Non-human Primate Model

   https://doi.org/10.1016/j.fertnstert.2024.08.080  

   Bonus, Marissa L; Wolf, Shally N; Stanley, Jessica E; Azooz, Masara; Hennebold, Jon D; Krieg, Adam J; Shah, Gaurika; Watanabe, Karen; Zelinski, Mary B (October 2024, Fertility and Sterility)

   OBJECTIVE: Rapamycin prolongs reproductive lifespan in mice by halting primordial follicle activation. The impact of rapamycin on the preantral follicle pool and senescence markers during ovarian aging in macaques was evaluated. MATERIALS AND METHODS: One ovary was removed from young (n=2, 6–9 yr) and old (n=2, 17–21 yr) adult female rhesus macaques during a normal menstrual cycle (pre-treatment). The remaining ovary was obtained after animals were treated with rapamycin (bid, IM, 0.02mg/kg) for 10 months. Ovaries were fixed and serially sectioned for follicle counting (each 10th section, 15-39 sections/ovary). Immunohistochemical analyses were performed for anti-Mullerian hormone (AMH) and cellular senescence markers p16, p53, and p21 (1 slide/ovary). Qualitative comparisons were made due to the small sample size. RESULTS: The primordial follicle pool was decreased in young (3,939 pre-treatment vs. 2,219 post-treatment), but similar in old (555 pre- vs. 574 post-treatment) females after rapamycin. The number of transitional primordial follicles was greater before rapamycin than after in both young (14,920 vs. 4,924) and old (1,915 vs. 1,311) females. The number of primary follicles before (2,617) rapamycin was greater than after (560) in young and old females (518 pre- vs. 428 post-treatment). A similar proportion of follicles positive for p16 was seen before and after rapamycin in both young and old females. Similar findings were also observed for AMH, except there are fewer positive follicles in the rapamycin-treated older group. The proportion of follicles staining positive for both p53 and p21 was increased in both young and old monkeys after treatment. CONCLUSIONS: Rapamycin had no impact on the primordial and primary follicle pools in old female macaques while unexpectedly decreasing both pools in young females. While the number of p16-positive follicles was unaffected by rapamycin treatment, the number of p53 and p21-positive follicles was increased by treatment in both age cohorts. IMPACT STATEMENT: At the dose and treatment interval used, rapamycin does not appear to suppress follicular activation and has mixed effects on senescence markers in aging nonhuman primate ovaries. 

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