Biology of Reproduction

Gene analysis of major signaling pathways regulated by gonadotropins in human ovarian granulosa tumor cells (KGN)†

AbstractThe female reproductive function largely depends on timing and coordination between follicle-stimulating hormone (FSH) and luteinizing hormone. Even though it was suggested that these hormones act on granulosa cells via shared signaling pathways, mainly protein kinases A, B, and C (PKA, PKB, and PKC), there is still very little information available on how these signaling pathways are regulated by each hormone to provide such differences in gene expression throughout folliculogenesis. To obtain a global picture of the principal upstream factors involved in PKA, PKB, and PKC signaling in granulosa cells, human granulosa-like tumor cells (KGN) were treated with FSH or specific activators (forskolin, SC79, and phorbol 12-myristate 13-acetate) for each pathway to analyze gene expression with RNA-seq technology. Normalization and cutoffs (FC 1.5, P ≤ 0.05) revealed 3864 differentially expressed genes between treatments. Analysis of major upstream regulators showed that PKA is a master kinase of early cell differentiation as its activation resulted in the gene expression profile that accompanies granulosa cell differentiation. Our data also revealed that the activation of PKC in granulosa cells is also a strong differentiation signal that could control “advanced” differentiation in granulosa cells and the inflammatory cascade that occurs in the dominant follicle. According to our results, PKB activation provides support for PKA-stimulated gene expression and is also involved in granulosa cell survival throughout follicular development. Taken together, our results provide new information on PKA, PKB, and PKC signaling pathways and their roles in stimulating a follicle at the crossroad between maturation/ovulation and atresia.

Inactivation of TRP53, PTEN, RB1, and/or CDH1 in the ovarian surface epithelium induces ovarian cancer transformation and metastasis

AbstractOvarian cancer (OvCa) remains the most common cause of death from gynecological malignancies. Genetically engineered mouse models have been used to study initiation, origin, progression, and/or mechanisms of OvCa. Based on the clinical features of OvCa, we examined a quadruple combination of pathway perturbations including PTEN, TRP53, RB1, and/or CDH1. To characterize the cancer-promoting events in the ovarian surface epithelium (OSE), Amhr2cre/+ mice were used to ablate floxed alleles of Pten, Trp53, and Cdh1, which were crossed with TgK19GT121 mice to inactivate RB1 in KRT19-expressing cells. Inactivation of PTEN, TRP53, and RB1 with or without CDH1 led to the development of type I low-grade OvCa with enlarged serous papillary carcinomas and some high-grade serous carcinomas (HGSCs) in older mice. Initiation of epithelial hyperplasia and micropapillary carcinoma started earlier at 1 month in the triple mutations of Trp53, Pten, and Rb1 mice as compared to 2 months in quadruple mutations of Trp53, Pten, Rb1, and Cdh1 mice, whereas both genotypes eventually developed enlarged proliferating tumors that invaded into the ovary at 3–4 months. Mice with triple and quadruple mutations developed HGSC and/or metastatic tumors, which disseminated into the peritoneal cavity at 4–6 months. In summary, inactivation of PTEN, TRP53, and RB1 initiates OvCa from the OSE. Additional ablation of CDH1 further increased persistence of tumor dissemination and ascites fluid accumulation enhancing peritoneal metastasis.

Niclosamide’s potential direct targets in ovarian cancer

Abstract Recent evidence indicates that niclosamide is an anti-cancer compound that is able to inhibit several signaling pathways. Although niclosamide has previously been identified by high-throughput screening platforms as a potential effective compound against several cancer types, no direct binding interactions with distinct biological molecule(s) has been established. The present study identifies key signal transduction mechanisms altered by niclosamide in ovarian cancer. Using affinity purification with a biotin-modified niclosamide derivative and mass spectrometry analysis, several RNA-binding proteins (RBPs) were identified. We chose the two RBPs, FXR1 and IGF2BP2, for further analysis. A significant correlation exists in which high-expression of FXR1 or IGF2BP2 is associated with reduced survival of ovarian cancer patients. Knockdown of FXR1 or IGF2BP2 in ovarian cancer cells resulted in significantly reduced cell viability, adhesion, and migration. Furthermore, FXR1 or IGF2BP2 deficient ovarian cancer cells exhibited reduced response to most doses of niclosamide showing greater cell viability than those with intact RBPs. These results suggest that FXR1 and IGF2BP2 are direct targets of niclosamide and could have critical activities that drive multiple oncogenic pathways in ovarian cancer.

Whole-exome sequencing reveals potential germline and somatic mutations in 60 malignant ovarian germ cell tumors

AbstractMalignant ovarian germ cell tumors (MOGCTs) are rare and heterogeneous ovary tumors. We aimed to identify potential germline mutations and somatic mutations in MOGCTs by whole-exome sequencing. The peripheral blood and tumor samples from these patients were used to identify germline mutations and somatic mutations, respectively. For those genes with copy number alterations (deletion and duplication region), functional annotation was performed. Immunohistochemistry was performed to evaluate the expression of mutated genes corresponding to CNA deletion region and duplication region. In peripheral blood, copy number loss and gain were mostly found in yolk sac tumors (YSTs). Moreover, POU5F1 was the most significant mutated gene with mutation frequency >10% in both CNA deletion and duplication region. In addition, strong cytoplasm staining of POU5F1 (corresponding to CNA deletion region and duplication region) was found in two YST and nuclear staining in two dysgerminomas tumor samples. Genes corresponding to CNA deletion region were significantly enriched in the signaling pathway of regulating pluripotency of stem cells. In addition, genes corresponding to CNA duplication region were significantly enriched in the signaling pathways of RIG-I (DExD/H-box helicase 58)-like receptor, Toll-like receptor and nuclear factor (NF)-kappa. Keratin 4 (KRT4), ribosomal protein L14 (RPL14), proprotein convertase subtilisin/kexin type 6 (PCSK6), poly(A)-binding protein cytoplasmic 3 (PABPC3), and sterile alpha and TIR motif containing 1 (SARM1) mutations were detected in both peripheral blood and tumor samples. Identification of potential germline mutations and somatic mutations in MOGCTs may provide a new field in understanding the genetic feature of the rare biological tumor type in the ovary.

Macrophages: an indispensable piece of ovarian health

AbstractMacrophages are the most abundant immune cells in the ovary. In addition to their roles in the innate immune system, these heterogeneous tissue-resident cells are responsive to tissue-derived signals, adapt to their local tissue environment, and specialize in unique functions to maintain tissue homeostasis. Research in the past decades has established a strong link between macrophages and various aspects of ovarian physiology, indicating a pivotal role of macrophages in ovarian health. However, unlike other intensively studied organs, the knowledge of ovarian macrophages dates back to the time when the heterogeneity of ontogeny, phenotype, and function of macrophages was not fully understood. In this review, we discuss the evolving understanding of the biology of ovarian tissue-resident macrophages, highlight their regulatory roles in normal ovarian functions, review the association between certain ovarian pathologies and disturbed macrophage homeostasis, and finally, discuss the technologies that are essential for addressing key questions in the field.

The FSH/FSHR axis in reproductive biology and oncogenesis: mechanisms and emerging targeted therapies

Abstract Follicle-stimulating hormone (FSH) and its receptor (FSHR) constitute one of the core signaling axes that regulate the reproductive process of mammals. Studies have shown that the glycosylation pattern of FSH and the polymorphism of receptor genes can affect the ligand-receptor binding efficiency and downstream signal intensity, and are related to the susceptibility and phenotype of diseases such as polycystic ovary syndrome and primary ovarian insufficiency. FSH/FSHR not only regulates normal reproductive function by activating multiple pathways such as cyclic adenosine monophosphate/protein kinase A, PI3K/Akt, β-arrestin, and MEK/ERK, but also promotes the progression of malignant tumors such as ovarian cancer and prostate cancer through mechanisms like activation of cancer stem cells, metabolic reprogramming, and angiogenesis. Therefore, targeting the FSH/FSHR axis has become a highly promising therapeutic strategy. This review summarizes the latest research advances of FSH/FSHR axis in reproductive system diseases and tumors, especially the therapeutic value of FSH/FSHR signaling axis.

Effects of endometriosis, fibroids, and other pathological conditions on muscular contractions in the human fallopian tube

Abstract Background Ectopic pregnancy and tubal endometriosis directly affect the fallopian tube structure and function, while ovarian cysts and uterine fibroids may indirectly influence tubal physiology. These conditions are associated with infertility, but their impact on fallopian tube mechanical contractions remains unclear. This study aimed to assess the effects of these pathologies on fallopian tube contractility. Method Ampulla samples were obtained from women undergoing salpingectomy for benign causes. Based on the menstrual phases, samples were divided into two groups: proliferative (normal proliferative, tubal endometriosis, ovarian cysts, and uterine fibroids) and secretory (normal secretory and ectopic pregnancy). Normal proliferative considered control for the proliferative group, while normal secretory for the ectopic pregnancy. Contractile parameters, maximum contractile force, basal tone, frequency, and amplitude were measured using an isometric force transducer, while in another set of experiments; the oxytocin doses (1 and 10 μM) response was assessed. Smooth muscle organization and structural changes were analyzed through hematoxylin and eosin staining. Result Compared to the normal proliferative, the tubal endometriosis and ovarian cysts groups showed significantly lower maximum contractile force, basal tone, frequency, and amplitude, along with damaged smooth muscle layers, while uterine fibroids showed decreased frequency and amplitude, with organized muscle structure. Ectopic pregnancy showed higher maximum contractile force and basal tone than normal secretory, with increased frequency and amplitude and disorganized smooth muscle. Oxytocin increased contractility at 1 μM and reduced it at 10 μM in most groups. Conclusion This study demonstrated that fallopian tube contractions and tissue structure were differentially affected across groups, with increased contractility observed in the ectopic pregnancy group and reduced contractility in the uterine fibroids, ovarian cysts, and tubal endometriosis groups.

DNA damage response signaling in oocytes from an oncofertility perspective

Abstract The remarkable advances in cancer therapies significantly enhance the survival rates and longevity of cancer patients. Among childhood, adolescent, and young adult female cancer survivors, however, anti-cancer agents frequently cause primary ovarian insufficiency, early menopause, and infertility, primarily due to the depletion of the ovarian reserve. Oocytes, the female germ cells, exhibit a notable susceptibility to DNA damage, given that they remain in meiotic arrest at prophase I for prolonged durations, from months to years, which increases the risks of accumulating DNA damage overtime. To counteract this, a tightly controlled DNA damage response signaling ensures that only oocytes with an intact genome progress to ovulation, fertilization, and next generations. Chemotherapeutic anti-cancer agents, including doxorubicin, cisplatin, cyclophosphamide, along with irradiation, elicit DNA damage via various mechanisms, including DNA crosslinking, single- and double-strand DNA breaks, and oxidative stress. The genotoxic insults activate DDR in the oocytes, which detect and repair DNA damage or initiate apoptosis to eliminate impaired oocytes. Although several protein molecules such as DNA damage-sensing kinases, checkpoint kinases, p53 family transcription factors, and pro-apoptotic molecules have been discovered, the precise mechanisms of DDR in determining the fate of oocytes, particularly how they differ from those in somatic cells and cancer cells, remain poorly understood. From an oncofertility perspective, the current review analyzes the molecular mechanisms of anti-cancer agent-induced DDR in oocytes and discusses knowledge gaps and urgent future research directions for preserving the ovarian reserve, fertility, and endocrine functions of young female cancer patients.

Irradiation with a mixed heavy ion beam induces ovarian follicle loss and dose-dependent mixed ovarian tumor development

Abstract Over 25% of active NASA astronauts are women who will be exposed to low daily doses and dose rates of galactic cosmic rays (GCR) in space. We hypothesized that exposing mice to a preliminary simulated GCR mixed heavy ion beam composed of iron, silicon, and titanium ions induces follicle depletion and dose-dependent ovarian tumors. Female mice were exposed to 10, or 20 cGy each of Fe, Si, and Ti ions or sham-irradiation in quick succession within 15 min for total doses of 0, 30, or 60 cGy of the three beams. 16 months later, their ovaries were removed. Hyperplasia of the ovarian surface epithelium (OSE) was noted in 13%, 59%, and 22% of the 0, 30, and 60 cGy irradiated mice, respectively. The prevalence of mixed ovarian tumors was 0, 6, and 89%, respectively, in the 0, 30, and 60 cGy groups. Low numbers of Ki67 positive OSE and tumor cells supported a benign tumor phenotype. In a separate study, Si ion irradiation alone at 32 cGy did not induce ovarian tumors in mice; however, the mixed heavy ions at all doses and Si ion irradiation alone reduced the total number of healthy ovarian follicles. Mixed heavy ion exposure reduced lipid peroxidation, fibrosis, inflammation, and lipofuscin accumulation at 60 cGy compared to 0 cGy, but elevated inflammation and lipofuscin accumulation at 30 cGy compared to 60 cGy. Preliminary simulated GCR exposure causes ovarian follicle death and tumorigenesis. This study provides insight into space-radiation induced ovarian damage and cancer risk in females.

CXCL12 promotes EMT-mediated malignant transformation of endometriosis-associated ovarian cancer via PI3K/Akt signaling: An integrated transcriptomic and clinical study

Abstract Background Endometriosis-associated ovarian cancer (EAOC) is a distinct form of epithelial ovarian cancer that arises from the malignant transformation of benign endometriotic lesions. While epithelial-mesenchymal transition (EMT) is acknowledged as a crucial process in the progression of EAOC, the upstream regulatory mechanisms and key molecular drivers are not fully understood. This study focuses on the chemokine CXCL12, its biological function, molecular mechanisms, and clinical prognostic significance in the transition from endometriosis to EAOC. Methods Differentially expressed genes (DEGs) between benign endometriosis and EAOC tissues were identified using Gene Expression Omnibus (GEO) datasets. CXCL12 emerged as a candidate regulator. To further elucidate the functional role of CXCL12, we conducted in vitro studies by establishing cell models with either CXCL12 overexpression or knockdown. Additionally, we investigated the underlying mechanism of CXCL12's function, focusing on its interaction with the PI3K/Akt signaling pathway and its regulation of downstream EMT-associated proteins. A retrospective analysis of clinical data from 38 EAOC patients was performed to evaluate the association between CXCL12 expression levels and patient prognosis. Results CXCL12 expression was significantly elevated in EAOC tissues compared to benign endometriosis samples and was closely associated with EMT-related phenotypes. In vitro functional assays demonstrated that CXCL12 enhanced cellular migratory and invasive capacities. Mechanistically, CXCL12 was found to induce EMT by activating the PI3K/Akt signaling pathway. Clinical analysis further revealed that high CXCL12 expression was associated with reduced overall survival and increased recurrence risk in EAOC patients. Multivariate Cox regression analysis identified CXCL12 as an independent adverse prognostic factor in EAOC. Conclusion This study is the first to systematically define the critical role of CXCL12 in the malignant transformation of endometriosis to EAOC.Our findings demonstrate that CXCL12 promotes tumor cell invasion and metastasis through PI3K/Akt-mediated induction of EMT. These results provide novel insights into the pathogenesis of EAOC and highlight CXCL12 as a promising biomarker for early diagnosis and a potential therapeutic target, offering new avenues for precision management of EAOC.

PTEN status on gonadotropin-releasing hormone (GnRH) metabolite, GnRH-(1–5), effects in endometrial cancer cell lines migration, & transcriptomic analysis of basal cell line and tumor gene expressions

Abstract Previous studies have shown that the metabolite of gonadotropin-releasing hormone (GnRH), GnRH-(1–5), promotes migration and invasion in endometrial cancer cell lines through a non-canonical mechanism from its parental peptide. These studies showed that GnRH-(1–5) transactivates the epidermal growth factor receptor/extracellular signal–regulated kinases (EGFR/ERK) signaling pathway through an orphan G-protein-coupled receptor, GPR101, to stimulate matrix metalloproteinase-9 (MMP-9)-mediated EGF release to augment cellular migration and invasion. However, inhibition of the EGFR/ERK signaling pathway showed an incomplete ablation of the effects of GnRH-(1–5) in these studies to suggest that alternative signaling pathways are also involved. Given the incomplete inhibition of GnRH-(1–5) effects by EGFR/ERK pathway blockade, the present study sought to investigate the potential role of transforming growth factor beta (TGF-beta) in complementing the previously observed EGF effects on cellular function. As our previous studies were conducted in Phosphatase and Tensin homolog (PTEN)–negative cell lines, we sought to elucidate the involvement of the TGF-beta signaling pathway and the role of PTEN status in mediating the cellular responses to GnRH-(1–5). The present results show that cellular migration responses to GnRH-(1–5) involve both TGF-beta and EGF signaling pathways and are differentially regulated based on PTEN status. In addition to these cell line studies, we performed differential gene expression analysis of PTEN-positive and PTEN-negative cell lines and tumors using The Cancer Genome Atlas database. Identifying markers associated with PTEN status will allow for a more precise and rapid investigation of GnRH-(1–5) signaling mechanisms in endometrial cancer pathophysiology.

Polyploid giant cancer cells and ovarian cancer: new insights into mitotic regulators and polyploidy

Abstract Current first-line treatment of patients with high-grade serous ovarian cancer (HGSOC) involves the use of cytotoxic drugs that frequently lead to recurrent tumors exhibiting increased resistance to the drugs and poor patient survival. Strong evidence is accumulating to show that HGSOC tumors and cell lines contain a subset of cells called polyploidy giant cancer cells (PGCCs) that act as stem-like, self-renewing cells. These PGCCs appear to play a key role in tumor progression by generating drug-resistant progeny produced, in part, as a consequence of utilizing a modified form of mitosis known as endoreplication. Thus, developing drugs to target PGCCs and endoreplication may be an important approach for reducing the appearance of drug-resistant progeny. In the review, we discuss newly identified regulatory factors that impact mitosis and which may be altered or repurposed during endoreplication in PGCCs. We also review recent papers showing that a single PGCC can give rise to tumors in vivo and spheroids in culture. To illustrate some of the specific features of PGCCs and factors that may impact their function and endoreplication compared to mitosis, we have included immunofluorescent images co-localizing p53 and specific mitotic regulatory, phosphoproteins in xenografts derived from commonly used HGSOC cell lines.

Long non-coding RNA NRSN2-AS1 facilitates tumorigenesis and progression of ovarian cancer via miR-744-5p/PRKX axis

Abstract Newly discovered lncRNA neurensin-2 antisense RNA 1 (NRSN2-AS1) has not been well explored in cancers. Ovarian cancer (OV) is a primary gynecologic cancer worldwide and has the highest mortality rate among gynecologic cancers. Hence, the role and underlying mechanisms of NRSN2-AS1 in OV were worth investigating. According to the results of qantitative real-time polymerase chain reaction, NRSN2-AS1 displayed the remarkably high expression in OV cells, in contrast to human ovarian epithelial cells. Based on online database, the expression level of NRSN2-AS1 was significantly higher in OV tissues than that in normal ovarian tissues. The data from functional experiments indicated that NRSN2-AS1 knockdown inhibited OV cell malignant behaviors in vitro and OV tumor growth in vivo. Moreover, mechanism analysis unveiled that NRSN2-AS1 functioned as a miR-744-5p sponge to regulate PRKX expression in OV cells. The results of TOP/FOP flash and western blot assays suggested that NRSN2-AS1/miR-744-5p/PRKX axis modulated the activity of Wnt/β-catenin signaling pathway. In summary, we validated NRSN2-AS1 functioned as a novel oncogenic lncRNA in OV and elucidated its specific molecular mechanism. This work might advance our understanding of OV and provide evidence for supporting NRSN2-AS1 as a potential biomarker for OV treatment.

Shear wave elastography to assess stiffness of the human ovary and other reproductive tissues across the reproductive lifespan in health and disease

Abstract The ovary is one of the first organs to show overt signs of aging in the human body, and ovarian aging is associated with a loss of gamete quality and quantity. The age-dependent decline in ovarian function contributes to infertility and an altered endocrine milieu, which has ramifications for overall health. The aging ovarian microenvironment becomes fibro-inflammatory and stiff with age, and this has implications for ovarian physiology and pathology, including follicle growth, gamete quality, ovulation dynamics, and ovarian cancer. Thus, developing a non-invasive tool to measure and monitor the stiffness of the human ovary would represent a major advance for female reproductive health and longevity. Shear wave elastography is a quantitative ultrasound imaging method for evaluation of soft tissue stiffness. Shear wave elastography has been used clinically in assessment of liver fibrosis and characterization of tendinopathies and various neoplasms in thyroid, breast, prostate, and lymph nodes as a non-invasive diagnostic and prognostic tool. In this study, we review the underlying principles of shear wave elastography and its current clinical uses outside the reproductive tract as well as its successful application of shear wave elastography to reproductive tissues, including the uterus and cervix. We also describe an emerging use of this technology in evaluation of human ovarian stiffness via transvaginal ultrasound. Establishing ovarian stiffness as a clinical biomarker of ovarian aging may have implications for predicting the ovarian reserve and outcomes of Assisted Reproductive Technologies as well as for the assessment of the efficacy of emerging therapeutics to extend reproductive longevity. This parameter may also have broad relevance in other conditions where ovarian stiffness and fibrosis may be implicated, such as polycystic ovarian syndrome, late off target effects of chemotherapy and radiation, premature ovarian insufficiency, conditions of differences of sexual development, and ovarian cancer. Summary sentence:  Shear Wave Elastography is a non-invasive technique to study human tissue stiffness, and here we review its clinical applications and implications for reproductive health and disease.

Metabolic characteristics of granulosa cell tumor: role of PPARγ signaling

Abstract Granulosa cell tumors are relatively rare, posing challenges for comprehension and therapeutic development due to limited cases and preclinical models. Metabolic reprogramming, a hallmark of cancer, manifests in granulosa cell tumors with notable lipid accumulation and increased expression of peroxisome proliferator–activated receptor gamma (PPARγ), a key lipid metabolism regulator. The roles of these features, however, remain unclear. In our previous work, we established a granulosa cell tumor model in mice by introducing a constitutively active Pik3ca mutant in oocytes, enabling the study of predictable tumor patterns from postnatal day 50. In this study, we characterized metabolic alterations during tumorigenesis (postnatal day 8 to day 50) and tumor growth (day 50 to day 65) in this model and explored the impact of PPARγ antagonism on human granulosa cell tumor proliferation. The tumor exhibited significant lipid accumulation, with PPARγ and the proliferation marker Ki67 co-localizing at postnatal day 65. Transcriptome analysis demonstrates that pathways for lipid metabolism and mitochondrial oxidation are promoted during tumorigenesis and tumor growth, respectively. Overlappingly upregulated genes during tumorigenesis and tumor growth are associated with lipid metabolism pathways. Correspondingly, mouse granulosa cell tumor shows overexpression of peroxisome proliferator–activated receptor gamma and DGAT2 proteins at postnatal day 65. Furthermore, GW9662 reduces the proliferation of KGN human granulosa cell tumor cells and decreases the phosphorylation of AKT and SMAD3. Our findings identify metabolic abnormalities in ooPIK3CA* granulosa cell tumor model and suggest peroxisome proliferator–activated receptor gamma as a potential driver for primary granulosa cell tumor growth.