Adult Mouse Ovaries Research Articles (Page 1)

Mammalian ovary development is essential for female fertility, involving the complex spatial patterning of diverse cell types to establish the finite reserve of ovarian follicles. While single-cell transcriptome analyses have provided important insights into the mechanisms driving specification and developmental trajectories of ovarian cells, they disrupt this crucial spatial context. To overcome this limitation, we used 10X Genomics Visium HD spatial transcriptomics to analyze the developing mouse ovary while maintaining its native cellular architecture. We captured all ovarian cell types at eight key fetal and postnatal timepoints, generating a near single cell resolution library of spatial gene expression across ovarian development. This comprehensive dataset allows analysis of dynamic transcriptional signatures associated with unique spatial patterning throughout development, including the establishment of cortex and medulla and assembly of ovarian follicles in each region. This dataset represents a fundamental resource for the investigation of regulatory mechanisms driving spatial patterning of the ovary and opens new avenues to explore the spatial determinants of female fertility and reproductive longevity.

Exposure to micro- and nanoplastics is unavoidable. Foods and beverages contain plastic particles from environmental contamination and processing and packaging materials, which are frequently made of polyethylene terephthalate (PET). Micro- and nanoplastics have been detected in human tissues such as the brain, liver, and placenta, as well as in ovarian follicular fluid, but little is known about the effects nanoplastics have on the female reproductive system. In addition, few studies on the health impacts of nanoplastics have been performed using environmentally relevant plastic types and concentrations. Thus, this research tested the hypothesis that nanoplastics made of spherical polystyrene (PS), a common model nanoplastic, would have different effects on cultured mouse ovarian follicles compared to secondary PET nanoplastics at environmentally relevant doses. The ovary is a highly sensitive reproductive organ responsible for the development of follicles, which contain the oocyte, and production of steroid hormones. Follicles were harvested from adult mouse ovaries and cultured for 96 h with vehicle, spherical commercially available 200 nm PS nanoplastics (1–100 μg/mL), or lab-generated 240 nm PET nanoplastics (0.1–10 μg/mL). PS and PET nanoplastic exposure inhibited follicle growth and altered expression of genes related to steroid synthesis, cell cycle, and oxidative stress. PET nanoplastics increased levels of pregnenolone and decreased expression of Cyp17a1. Overall, both plastic types altered ovarian function, but they impacted different genes in similar pathways. These findings suggest that nanoplastic exposure at environmentally relevant concentrations may pose a risk to female reproductive health by disrupting hormonal and molecular pathways. In addition, environmentally relevant plastic types and doses are necessary for studying health impacts of nanoplastics.

In vertebrates, oogonial stem cells (OSCs) contribute to oogenesis in some fish, amphibians, and reptiles, enabling the production of new oocytes during each reproductive cycle. Classical literature from the 19th and 20th centuries established the prevailing notion that, in mammals and birds, the ovarian reserve is formed exclusively during embryogenesis, with OSCs absent in postnatal and adult ovaries. However, in 2004, OSCs were first identified in the ovaries of adult female mice, challenging the long-standing dogma that postnatal neo-oogenesis is impossible in mammals. Despite an increasing number of studies, this issue remains controversial. Advances in molecular and cellular techniques have significantly expanded our understanding of oogenesis across various animal groups. Notably, a recent study of adult chicken ovaries identified the presence of OSCs, further questioning traditional assumptions about ovarian biology in birds. In this review, we examine the evidence for postnatal oogenesis in this group of vertebrates.

Maternal exposure to polystyrene nanoplastics during gestation and lactation caused fertility decline in female mouse offspring.

Abstract Disclosure: B. deSouza: None. F. Huynh: None. K. Anderson: None. I. Batchvarov: None. B. Capel: None. M. Hirschey: None. Breastfeeding confers a wealth of benefits to both children and mothers. Breastfeeding can be impaired by metabolic diseases such as diabetes and obesity, which are known to interfere with both normal mammary gland development and lactogenesis, although mechanisms remain unclear. Our lab recently discovered a novel connection between metabolic regulation and mammary development in Sirt4 knockout (Sirt4-/-) mice. SIRT4 is an NAD+-dependent mitochondrial enzyme with strong deacylase activity. It is known to regulate several metabolic pathways including those of fatty acids, glutamine, and leucine. Sirt4 knockout mice are resistant to developing high-fat diet-induced obesity but develop early-onset insulin resistance. We observed that Sirt4-/- females are incapable of nursing their offspring due to impaired mammary ductal branching. Transplantation of wild-type mammary epithelia into SIRT4KO mice fails to rescue mammary development; however, mammary epithelia from SIRTKO mice transplanted into wild-type mice develop normally. SIRT4 action is thus required outside the mammary gland, which led us to explore the effect of SIRT4 on steroid hormone signaling. Treatment of pre-pubertal SIRT4KO mice with progesterone and estradiol, but not estradiol alone, rescued mammary ductal branching. Likewise, transplants of wild-type ovaries into SIRT4KO mice partially rescued the ductal branching defect. Given these findings, we hypothesized that SIRT4 expression in the ovary is necessary for sufficient progesterone biosynthesis and subsequent mammary development. In ovaries of adult mice, SIRT4 is most highly expressed in differentiated granulosa cells of the corpus luteum, a temporary endocrine structure responsible for synthesizing peak levels of progesterone during the diestrus phase of the mouse estrous cycle. Future experiments will compare peak circulating progesterone levels in Sirt4-/- vs. wild-type mice. We will characterize progesterone signaling in SIRT4KO mammary glands, including determining the expression of progesterone receptor isoforms. Additionally, we will characterize SIRT4 function in the ovary, including its effects on corpus luteum formation, steroid hormone biosynthesis, and import vs. de novo synthesis of the steroidogenic precursor, cholesterol. This work could offer new insights into the impairment of breastfeeding due to metabolic diseases. Presentation: 6/3/2024

Asprosin-mediated regulation of ovarian functions in mice: An age-dependent study

Survival rates of the childhood cancer patients are improving, however cancer treatments such as chemotherapy may lead to infertility due to loss of the primordial follicle (PMF) reserve. Doxorubicin (DXR) is a gonadotoxic chemotherapy agent commonly used in childhood cancers. Anti-Müllerian Hormone (AMH) has been reported to have a protective effect on the mouse ovarian reserve against DXR in vivo. However, whether AMH can prevent PMF loss in conjunction with DXR in human ovarian tissue in vivo has not been determined. In order to investigate this, we first established an optimum dose of DXR that induced PMF loss in cultured mouse ovaries and investigated the efficacy of AMH on reducing DXR-induced PMF loss in mice in vitro. Second, we investigated the effects of DXR on pre-pubertal human ovarian tissue and the ability of AMH to prevent DXR-induced damage comparing using a mouse xenograft model with different transplantation sites. Mouse ovaries treated with DXR in vitro and in vivo had reduced PMF populations and damaged follicle health. We did not observe effect of DXR-induced PMF loss or damage to follicle/stromal health in human ovarian cortex, this might have been due to an insufficient dose or duration of DXR. Although AMH does not prevent DXR-induced PMF loss in pre-pubertal and adult mouse ovaries, in mouse ovaries treated with higher concentration of AMH in vitro, DXR did not cause a significant loss in PMFs. This is the first study to illustrate an effect of AMH on DXR-induced PMF loss on pre-pubertal mouse ovaries. However, more experiments with higher doses of AMH and larger sample size are needed to confirm this finding. We did not observe that AMH could prevent DXR-induced PMF loss in mouse ovaries in vivo. Further studies are warranted to investigate whether AMH has a protective effect against DXR in xenotransplanted human ovarian tissue. Thus, to obtain robust evidence about the potential of AMH in fertility preservation during chemotherapy treatment, alternative AMH administration strategies need to be explored alongside DXR administration to fully interrogate the effect of DXR and AMH on human xenografted tissues.

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.

Abstract Study question Can an aurora kinase B/C inhibitor suppress AML cell line proliferation while not impacting on mouse follicles in vitro? Summary answer Exposure to an aurora kinase inhibitor at a predetermined cytotoxic concentration suppressed AML cell proliferation but had no impact on subsequent follicle health in vitro. What is known already There is a risk that cryopreserved ovarian tissue from young women with a leukaemia diagnosis harbours leukemic cells, which on grafting could transfer disease. Novel chemotherapy agents, specifically aurora kinase inhibitors [ e.g. GSK 1070916 (GSK) ], target proteins involved in chromosomal alignment and segregation during mitosis and meiosis. It is anticipated that aurora kinase inhibitors would have an impact on the development of all somatic cells, including granulosa cells proliferating during follicle growth, however a previous study using ovarian tissue pieces indicated no impact on follicles. Study design, size, duration Primary and secondary follicles (diameter ≤ 100 µm) were manually dissected from adult mouse ovaries and embedded in an extracellular scaffold together with >1,000 AML cells. Individual follicles and AML cells were cultured for 7 days followed by exposure to GSK for 24 hours. GSK was removed by washing and the culture continued for another two days at which time cells were assessed for normal morphology and survival with live/dead staining (Calcein AM/ Ethidium Homodimer-1). Participants/materials, setting, methods The leukemic cell line OC1-AML-3 (DSMZ) was cultured in RPMI-1640 +10% FCS and routinely passaged as recommended. Cell proliferation and cytotoxicity were assessed using the Alamar Blue assay. 20% DMSO was used as a positive control in the cytotoxicity assays and live/dead evaluation. Follicles were cultured in αMEM, ITS, FSH, ascorbic acid and 10% FCS under oil in 5%CO2 : 95% air. Survival and growth were evaluated in two extracellular scaffolds; UltiMatrix and Hystem™-HP. Main results and the role of chance Follicle survival and growth was better (p < 0.05) in UltiMatrix (84.7%; 61/72) compared to Hystem™-HP (72.0%;77/107) with an average increase of 20 µm in diameter at day 7. When OCI-AML-3 cells (0.7 x105/ml) were exposed to a range of concentrations of GSK (10nM to 10µM) for 24hr in an in vitro cytotoxicity assessment, survival was reduced to 0% at a concentration of 10µM. The 20% DMSO positive control also resulted in 0% survival. However, in the 3- dimensional scaffold culture, exposure to 10 µM GSK for 24hr resulted in a mean survival of OCI-AML-3 cells of 27% (100 cells counted/ well) which was similar to the 20% DMSO positive control (32%) and significantly different to the negative (no GSK) control (95%; p < 0.01). Follicles exposed to GSK appeared alive, emitting a strong green fluorescence for both oocyte and granulosa cells, although some of the surface follicular cells were dead. Live/dead staining of GSK exposed follicles was similar to follicles not exposed to GSK. In contrast, the majority of the follicular cells were dead following exposure to 20% DMSO. Limitations, reasons for caution Due to whole mount assessment of the follicles for live/dead staining, it is difficult to determine whether the oocyte is alive. In scaffold culture some of the free cells present may be of follicular origin, potentially resulting in overestimation of the proportion of AML cells alive after GSK treatment. Wider implications of the findings This 3- dimensional culture system, incorporating a follicle and a leukemic cell line within a scaffold provides a good model to assess the impact of chemotherapy on both cell types and could be applicable for human follicles. Trial registration number Not applicable

In mammalian females, quiescent primordial follicles serve as the ovarian reserve and sustain normal ovarian function and egg production via folliculogenesis. The loss of primordial follicles causes ovarian aging. Cellular senescence, characterized by cell cycle arrest and production of the senescence-associated secretory phenotype (SASP), is associated with tissue aging. In the present study, we report that some quiescent primary oocytes in primordial follicles become senescent in adult mouse ovaries. The senescent primary oocytes share senescence markers characterized in senescent somatic cells. The senescent primary oocytes were observed in young adult mouse ovaries, remained at approximately 15% of the total primary oocytes during ovarian aging from 6 to 12 months, and accumulated in aged ovaries. Administration of a senolytic drug ABT263 to 3-month-old mice reduced the percentage of senescent primary oocytes and the transcription of the SASP factors in the ovary, in addition, led to increased numbers of primordial and total follicles and a higher rate of oocyte maturation. Our study provides experimental evidence that primary oocytes, a germline cell type that is arrested in meiosis, become senescent in adult mouse ovaries and that senescent cell clearance reduced primordial follicle loss and mitigated ovarian aging phenotypes.

The transcription factor FOXL2 is required in ovarian somatic cells for female fertility. Differential timing of Foxl2 deletion, in embryonic versus adult mouse ovary, leads to distinctive outcomes, suggesting different roles across development. Here, we comprehensively investigated FOXL2's role through a multi-omics approach to characterize gene expression dynamics and chromatin accessibility changes, coupled with genome-wide identification of FOXL2 targets and on-chromatin interacting partners in somatic cells across ovarian development. We found that FOXL2 regulates more targets postnatally, through interaction with factors regulating primordial follicle formation and steroidogenesis. Deletion of one interactor, ubiquitin-specific protease 7 (Usp7), results in impairment of somatic cell differentiation, germ cell nest breakdown, and ovarian development, leading to sterility. Our datasets constitute a comprehensive resource for exploration of the molecular mechanisms of ovarian development and causes of female infertility.

The functions and molecular mechanisms of long noncoding RNA (lncRNA) in reproduction have been widely studied at present. However, lncRNA regulating hormone synthesis in ovarian follicular granulosa cells has not been sufficiently studied. Our previous research demonstrated that lncRNA Gm2044 could promote estradiol synthesis in follicular granulosa cells. In this study, we identified 21 binding proteins of lncRNA Gm2044 in ovarian follicles using comprehensive identification of RNA-binding proteins by mass spectrometry (ChIRP-MS). RNA immunoprecipitation (RNA IP) and reverse transcription PCR (RT-PCR) confirmed that lncRNA Gm2044 can interact with eukaryotic translation elongation factor 2 (EEF2) protein. Furthermore, we constructed lncRNA Gm2044 knockout mice using the CRISPR/Cas9 method. Although the follicular development and fertility of female lncRNA Gm2044 knockout mice were not affected, the serum estradiol concentration in female lncRNA Gm2044 knockout mice significantly decreased. Western blotting and ELISA revealed that lncRNA Gm2044 may promote the binding of EEF2 to Nr5a1 mRNA and then enhance the Nr5a1 mRNA translation, and the upregulated NR5A1 protein can strengthen estradiol synthesis. To determine the potential signaling pathway of lncRNA Gm2044 regulating estradiol synthesis, transcriptome sequencing was performed for ovaries of adult lncRNA Gm2044 knockout mice, which identified 565 significant up-regulated genes and 303 significant down-regulated genes, which were then analyzed with Gene Ontology (GO) and the Kyoto Encyclopedia of Genes and Genomes (KEGG) and validated by molecular experiments. Understanding how lncRNA Gm2044/EEF2 protein regulates estradiol synthesis will help treat estrogen-related reproductive diseases.

Adropin, a unique peptide hormone, has been associated with the regulation of several physiological processes, including glucose homeostasis, fatty acid metabolism, and neovascularization. However, its possible role in ovarian function is not understood. Our objective was to examine the expression of adropin and its putative receptor, GPR19, in the ovaries of mice at various phases of the estrous cycle. Immunohistochemistry and western blot analysis were performed to explore the localization and changes in expression of adropin and GPR19 in the ovaries during different phases of the estrous cycle in mice. Hormonal assays were performed with ELISA. An in vitro study was performed to examine the direct effect of adropin (10, 100 ng/ml) on ovarian function. A western blot study showed that adropin and GPR19 proteins were maximum during the estrus phase of the estrous cycle. Interestingly, adropin and GPR19 displayed intense immunoreactivity in granulosa cells of large antral follicles and corpus luteum. This suggested the possible involvement of adropin in corpus luteum formation. Adropin treatment stimulated progesterone synthesis by increasing GPR19, StAR, CYP11A1, and 3β-HSD expressions, while it decreased estrogen synthesis by inhibiting 17β-HSD and aromatase protein expressions. Moreover, adropin treatment upregulated the cell cycle arrest-CDK inhibitor 1B (p27kip1), pERK1/2, and angiogenic protein (EG VEGF) that are involved in the process of luteinization. Adropin GPR19 signaling promotes the synthesis of progesterone and upregulates the expression of p27kip1, EG VEGF, and erk1/2, resulting in cell cycle arrest and neovascularization, which ultimately leads to corpus luteum formation.

Nicotinic acetylcholine receptor alpha 7 (nAChRa7), encoded by Chrna7, is expressed by various murine ovarian cells. Morphological and molecular investigations, including a proteomic study of adult Chrna7 knockout (KO) mouse ovaries, reveal the roles of these receptors in the local regulation of the ovary. Nicotinic acetylcholine receptor alpha 7 (nAChRa7), encoded by Chrna7, is involved in cellular functions ranging from synaptic transmission in neurons to regulation of inflammation, cell growth and metabolism to cell death in other cells. Our qPCR results and other studies indicated that nAChRa7 is expressed in the adult mouse ovary, while in situ hybridization and single-cell sequencing data suggested this expression may be shared by several ovarian cells, including fibroblast-like and steroidogenic stroma cells, macrophages and oocytes of small follicles. To explore a possible involvement of nAChRa7 in ovarian functions, we evaluated ovarian morphology of Chrna7-null mutant adult mice (KO) and wildtype mice (WT; 3 months, metestrus) by performing immunohistochemistry, qPCR studies, measurements of serum progesterone and proteomic analyses. The evaluation of serial sections indicated fewer primordial follicles but similar numbers of primary, secondary and tertiary follicles, as well as corpora lutea in KO and WT mice. Atresia was unchanged. Serum progesterone and mRNA levels of proliferation and most apoptosis markers were not changed, yet two typical macrophage markers were elevated. Furthermore, the proteomes of KO ovaries were significantly altered with 96 proteins increased and 32 decreased in abundance in KOs compared to WTs. Among the elevated proteins were markers for stroma cells. Hence, the lack of nAChRa7 causes changes in small follicle counts and alterations of the ovarian stroma cells. The ovarian phenotype of Chrna7 mutant mice links this channel protein to the local regulation of ovarian cells, including stroma cells.

BackgroundThe accurate identification and isolation of ovarian stem cells from mammalian ovaries remain a major challenge because of the lack of specific surface markers and suitable in vitro culture systems. Optimized culture conditions for in vitro expansion of ovarian stem cells would allow for identifying requirements of these stem cells for proliferation and differentiation that would pave the way to uncover role of ovarian stem cells in ovarian pathophysiology. Here, we used three-dimensional (3D) aggregate culture system for enrichment of ovarian stem cells and named them aggregate-derived stem cells (ASCs). We hypothesized that mimicking the ovarian microenvironment in vitro by using an aggregate model of the ovary would provide a suitable niche for the isolation of ovarian stem cells from adult mouse and human ovaries and wanted to find out the main cellular pathway governing the proliferation of these stem cells. ResultsWe showed that ovarian aggregates take an example from ovary microenvironment in terms of expression of ovarian markers, hormone secretion and supporting the viability of the cells. We found that aggregates-derived stem cells proliferate in vitro as long-term while remained expression of germline markers. These ovarian stem cells differentiated to oocyte like cells in vitro spontaneously. Transplantation of these stem cells in to chemotherapy mouse ovary could restore ovarian structure. RNA-sequencing analysis revealed that interleukin6 is upregulated pathway in ovarian aggregate-derived stem cells. Our data showed that JAK/Stat3 signaling pathway which is activated downstream of IL6 is critical for ovarian stem cells proliferation. ConclusionsWe developed a platform that is highly reproducible for in vitro propagation of ovarian stem cells. Our study provides a primary insight into cellular pathway governing the proliferation of ovarian stem cells.

Understanding the molecular pathways that underpin ovarian development and function is vital for improving the research approaches to investigating fertility. Despite a significant improvement in our knowledge of molecular activity in the ovary, many questions remain unanswered in the quest to understand factors influencing fertility and ovarian pathologies such as cancer. Here, we present an investigation into the expression and function of the developmental transcription factor LIM Homeobox 9 (LHX9) in the adult mouse ovary. We have characterized Lhx9 expression in several cell types of the mature ovary across follicle stages. To evaluate possible LHX9 function in the adult ovary, we investigated ovarian anatomy and transcription in an Lhx9+/- knockout mouse model displaying subfertility. Despite a lack of gross anatomical differences between genotypes, RNA-sequencing found that 90 differentially expressed genes between Lhx9+/ - and Lhx9+/+ mice. Gene ontology analyses revealed a reduced expression of genes with major roles in ovarian steroidogenesis and an increased expression of genes associated with ovarian cancer. Analysis of the ovarian epithelium revealed Lhx9+/ - mice have a disorganized epithelial phenotype, corresponding to a significant increase in epithelial marker gene expression. These results provide an analysis of Lhx9 in the adult mouse ovary, suggesting a role in fertility and ovarian epithelial cancer.

Many adult somatic stem cell lineages are comprised of subpopulations that differ in gene expression, mitotic activity, and differentiation status. In this study, we explored if cellular heterogeneity also exists within oogonial stem cells (OSCs), and how chronological aging impacts OSCs. In OSCs isolated from mouse ovaries by flow cytometry and established in culture, we identified subpopulations of OSCs that could be separated based on differential expression of stage-specific embryonic antigen 1 (SSEA1) and cluster of differentiation 61 (CD61). Levels of aldehyde dehydrogenase (ALDH) activity were inversely related to OSC differentiation, whereas commitment of OSCs to differentiation through transcriptional activation of stimulated by retinoic acid gene 8 was marked by a decline in ALDH activity and in SSEA1 expression. Analysis of OSCs freshly isolated from ovaries of mice between 3 and 20 months of age revealed that these subpopulations were present and persisted throughout adult life. However, expression of developmental pluripotency associated 3 (Dppa3), an epigenetic modifier that promotes OSC differentiation into oocytes, was lost as the mice transitioned from a time of reproductive compromise (10 months) to reproductive failure (15 months). Further analysis showed that OSCs from aged females could be established in culture, and that once established the cultured cells reactivated Dppa3 expression and the capacity for oogenesis. Analysis of single-nucleus RNA sequence data sets generated from ovaries of women in their 20s versus those in their late 40s to early 50s showed that the frequency of DPPA3-expressing cells decreased with advancing age, and this was paralleled by reduced expression of several key meiotic differentiation genes. These data support the existence of OSC subpopulations that differ in gene expression profiles and differentiation status. In addition, an age-related decrease in Dppa3/DPPA3 expression, which is conserved between mice and humans, may play a role in loss of the ability of OSCs to maintain oogenesis with age.

Single-cell transcriptome analysis of the mouse and primate ovaries reveals oocyte-specific expression patterns of risk genes in ovarian aging.

BackgroundFertility preservation and restoration in cancer patients/survivors is the need of present times when increased numbers of patients get cured of cancer but face infertility as a serious side effect. Resveratrol has beneficial effects on chemoablated ovaries and testes in mice but has failed to enter the clinics because of extremely poor bioavailability. The present study was undertaken to evaluate the protective and curative effects of Extremely active Resveratrol (XAR™)- a nano-formulation of resveratrol with significantly improved bioavailability- on mouse ovary and testis after chemotherapy. Effects of XAR™ and FSH were compared on stimulation of follicle growth in adult mice ovaries. XAR™ (25 mg/kg) was administered for two days prior to chemotherapy to study the protective effects on the mouse gonads. XAR™ was also administered for 14 days post chemoablation to study the regenerative effects. Besides effect on numbers of primordial and growing follicles and spermatogenesis, the effect of XAR™ was also evaluated on the transcripts specific for ovarian/testicular stem/progenitor/germ cells, their proliferation, differentiation, meiosis, and the antioxidant indices.ResultsSimilar to FSH, XAR™ increased the numbers of primordial follicles (PF) as well as growing follicles. It protected the gonads from the adverse effects of chemotherapy and showed the ability to regenerate non-functional, chemoablated gonads. Besides stimulating follicle growth in adult ovaries similar to FSH, XAR™ also protected the testes from the adverse effects of chemotherapy and improved spermatogenesis. This was accompanied by improved anti-oxidant indices.ConclusionsThe results of the present study potentiate the use of XAR™ in pilot clinical studies to protect gonadal function during oncotherapy and also regenerate non-functional gonads in cancer survivors by improving antioxidant indices and stem cell-based tissue regeneration.

The estrous cycle is regulated by rhythmic endocrine interactions of the nervous and reproductive systems, which coordinate the hormonal and ovulatory functions of the ovary. Folliculogenesis and follicle progression require the orchestrated response of a variety of cell types to allow the maturation of the follicle and its sequela, ovulation, corpus luteum formation, and ovulatory wound repair. Little is known about the cell state dynamics of the ovary during the estrous cycle and the paracrine factors that help coordinate this process. Herein, we used single-cell RNA sequencing to evaluate the transcriptome of >34,000 cells of the adult mouse ovary and describe the transcriptional changes that occur across the normal estrous cycle and other reproductive states to build a comprehensive dynamic atlas of murine ovarian cell types and states.