Explore the vast range of titles available.

Background Polycystic ovary syndrome (PCOS) is a common endocrine disorder among women of reproductive age and a major cause of infertility; however, the pathophysiology of this syndrome is not fully understood. This can be addressed using appropriate animal models of PCOS. In this review, we describe rodent models of hormone‐induced PCOS that focus on the perturbation of the hypothalamic‐pituitary‐ovary (HPO) axis and abnormalities in neuropeptide levels. Methods Comparison of rodent models of hormone‐induced PCOS. Main findings The main method used to generate rodent models of PCOS was subcutaneous injection or implantation of androgens, estrogens, antiprogestin, or aromatase inhibitor. Androgens were administered to animals pre‐ or postnatally. Alterations in the levels of kisspeptin and related molecules have been reported in these models. Conclusion The most appropriate model for the research objective and hypothesis should be established. Dysregulation of the HPO axis followed by elevated serum luteinizing hormone levels, hyperandrogenism, and metabolic disturbance contribute to the complex etiology of PCOS. These phenotypes of the human disease are recapitulated in hormone‐induced PCOS models. Thus, evidence from animal models can help to clarify the pathophysiology of PCOS.

Purpose Relaxin‐3 is a hypothalamic neuropeptide that belongs to the insulin superfamily. We examined whether relaxin‐3 could affect hypothalamic Kiss‐1, gonadotropin‐releasing hormone (GnRH), and pituitary gonadotropin subunit gene expression. Methods Mouse hypothalamic cell models, mHypoA‐50 (originated from the hypothalamic anteroventral periventricular region), mHypoA‐55 (originated from arcuate nucleus), and GT1‐7, and the mouse pituitary gonadotroph LβT2 were used. Expression of Kiss‐1, GnRH, and luteinizing hormone (LH)/follicle‐stimulating hormone (FSH) β‐subunits was determined after stimulation with relaxin‐3. Results RXFP3, a principle relaxin‐3 receptor, was expressed in these cell models. In mHypoA‐50 cells, relaxin‐3 did not exert a significant effect on Kiss‐1 expression. In contrast, the Kiss‐1 gene in mHypoA‐55 was significantly increased by 1 nmol/L relaxin‐3. These cells also express GnRH mRNA, and its expression was significantly stimulated by relaxin‐3. In GT1‐7 cells, relaxin‐3 significantly upregulated Kiss‐1 expression; however, GnRH mRNA expression in GT1‐7 cells was not altered. In primary cultures of fetal rat neuronal cells, 100 nmol/L relaxin‐3 significantly increased GnRH expression. In pituitary gonadotroph LβT2, both LHβ‐ and FSHβ‐subunit were significantly increased by 1 nmol/L relaxin‐3. Conclusions Our findings suggest that relaxin‐3 exerts its effect by modulating the expression of Kiss‐1, GnRH, and gonadotropin subunits, all of which are part of the hypothalamic‐pituitary‐gonadal axis. Relaxin‐3 may exert its effect by modulating the expression of Kiss‐1, GnRH, and gonadotropin subunits, all of which are part of the hypothalamic‐pituitary‐gonadal axis.

Understanding the hypothalamic–pituitary–gonadal (HPG) axis is essential for grasping human responses under extreme physiological and pathological conditions. The HPG axis regulates reproductive and gonadal hormone activities and significantly impacts the body’s response to acute and chronic illnesses. This review explores the fundamental functions of the HPG axis, modifications under critical conditions, and impacts on disease progression and treatment outcomes. In addition, it examines interactions between sex hormones and biomolecules like cytokines and gastrointestinal microorganisms, highlighting their roles in immune response regulation. Clinically, this knowledge can enhance patient prognoses. The review aims to provide a comprehensive framework, based on existing research, for understanding and applying the functions of the HPG axis in managing critical diseases, thereby broadening clinical applications and guiding future research. Plain language summary The response and effects of the hypothalamic-pituitary-gonadal axis during critical illness Our review systematically analyzes the alterations in sex hormone levels during critical illness, delves into the underlying mechanisms, and evaluates the current clinical applications of sex hormone therapies in critical care. In females, critical illness is associated with the reduction of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) levels, alongside the increase in testosterone, estradiol, and progesterone levels. This elevation in estrogen is attributed to two primary factors: (1) a by-product of adrenal activation, and (2) increased aromatization, which is a chemical structural change that converts testosterone into estradiol. The rise in testosterone and progesterone is predominantly due to adrenal and peripheral tissue activity. In males, there is the decrease in FSH, LH, and testosterone levels, coupled with increased levels of estradiol and progesterone. The decline in testosterone is primarily due to: (1) chronic low-level endotoxin exposure and inflammation impairing androgen synthesis, and (2) increased aromatization in peripheral tissues. The rise in progesterone is attributed to stress-induced stimulation of the adrenal glands. These hormonal changes are closely linked to the patient’s critical condition, with hormone levels generally returning to reference ranges as the condition improves.

Precocious puberty (PP) commonly results from premature activation of the hypothalamic–pituitary–gonadal axis (HPGA). Gonadotropin-releasing hormone (GnRH) is the initial trigger for HPGA activation and plays an important role in puberty onset. N-methyl-D-aspartate (NMDA) can promote pulsatile GnRH secretion and accelerates puberty onset. However, the mechanism of N-methyl-D-aspartate receptors (NMDARs) in PP pathogenesis remains obscure. We found that serum GnRH, luteinizing hormone (LH), follicle-stimulating hormone (FSH), estrogen (E2) levels, hypothalamic NMDAR1, and GnRH mRNA expression peaked at the vaginal opening (VO) day. Next, the hypothalamic NMDAR1 mRNA and protein levels in rats treated with danazol, a chemical commonly effecting on the reproductive system, were significantly increased at the VO day (postnatal day 24) compared to controls, accompanied by enhanced serum GnRH, LH, FSH, and E2 levels. Further, microRNA-664-2 (miR-664-2) was selected after bioinformatics analysis and approved in primary hypothalamic neurons, which binds to the 3′-untranslated regions of NMDAR1. Consistently, the miR-664-2 expression in hypothalamus of the Danazol group was decreased compared to Vehicle. Our results suggested that attenuated miR-664-2 might participate in PP pathogenesis through enhancing the NMDAR1 signaling. Summary Sentence Increased hypothalamic NMDAR1 expression correlates to precocious puberty. MiR-664-2 regulates precocious puberty onset. MiR-664-2 targets NMDAR1 and modulates the HPGA activity.

Background Prokineticin 2 (PROK2), an important neuropeptide that plays a key role in the neuronal migration of gonadotropin-releasing hormone (GnRH) in the hypothalamus, is known to have regulatory effects on the gonads. In the present study, the impact of intracerebroventricular (icv) PROK2 infusion on hypothalamic-pituitary–gonadal axis (HPG) hormones, testicular tissues, and sperm concentration was investigated. Methods and results Rats were randomly divided into four groups: control, sham, PROK2 1.5 and PROK2 4.5. Rats in the PROK2 1.5 and PROK2 4.5 groups were administered 1.5 nmol and 4.5 nmol PROK2 intracerebroventricularly for 7 days via an osmotic mini pump (1 µl/h), respectively. Rat blood serum follicle stimulating hormone (FSH), luteinizing hormone (LH) and testosterone hormone levels were determined with the ELISA method in the blood samples after 7 days of infusion. GnRH mRNA expression was determined with the RT-PCR in hypothalamus tissues. analyze Sperm concentration was determined, and testicular tissue was examined histologically with the hematoxylin–eosin staining method. It was observed that GnRH mRNA expression increased in both PROK2 infusion groups. Serum FSH, LH and testosterone hormone levels also increased in these groups. Although sperm concentration increased in PROK2 infusion groups when compared to the control and sham, the differences were not statistically significant. Testicular tissue seminiferous epithelial thickness was higher in the PROK2 groups when compared to the control and sham groups. Conclusion The present study findings demonstrated that icv PROK2 infusion induced the HPG axis. It could be suggested that PROK2 could be a potential agent in the treatment of male infertility induced by endocrinological defects.

Summary In many organisms, food availability is a proximate cue that synchronizes seasonal development of the reproductive system with optimal environmental conditions. Growth of the gonads and secondary sexual characteristics is orchestrated by the hypothalamic–pituitary–gonadal (HPG) axis. However, our understanding of the physiological mechanisms by which food availability modulates activity of the HPG axis is limited. It is thought that many factors, including energetic status, modulate seasonal reproductive activation. We tested the hypothesis that food availability modulates the activity of the HPG axis in a songbird. Specifically, we food‐restricted captive adult male Abert's Towhees Melozone aberti for 2 or 4 weeks during photoinduced reproductive development. A third group (control) received ad libitum food throughout. We measured multiple aspects of the reproductive system including endocrine activity of all three levels of the HPG axis [i.e. hypothalamic gonadotropin‐releasing hormone‐I (GnRH‐I), plasma luteinizing hormone (LH) and testosterone (T)], and gonad morphology. Furthermore, because gonadotropin‐inhibitory hormone (GnIH) and neuropeptide Y (NPY; a potent orexigenic peptide) potentially integrate information on food availability into seasonal reproductive development, we also measured the brain levels of these peptides. At the hypothalamic level, we detected no effect of food restriction on immunoreactive (ir) GnRH‐I, but the duration of food restriction was inversely related to the size of ir‐GnIH perikarya. Furthermore, the number of ir‐NPY cells was higher in food‐restricted than control birds. Food restriction did not influence photoinduced testicular growth, but decreased plasma LH and T, and width of the cloacal protuberance, an androgen‐sensitive secondary sexual characteristic. Returning birds to ad libitum food availability had no effect on plasma LH or T, but caused the cloacal protuberance to rapidly increase in size to that of ad libitum‐fed birds. Our results support the tenet that food availability modulates photoinduced reproductive activation. However, they also suggest that this modulation is complex and depends upon the level of the HPG axis considered. At the hypothalamic level, our results are consistent with a role for the GnIH and NPY systems in integrating information on energetic status. There also appears to be a role for endocrine function at the anterior pituitary gland and testicular levels in modulating reproductive development in the light of energetic status and independently of testicular growth. Lay Summary

Background The human hypothalamic–pituitary‐gonadal (HPG) axis is the regulatory center for pubertal development. This axis involves six G‐protein coupled receptors (GPCRs) encoded by KISS1R, TACR3, PROKR2, GNRHR, LHCGR, and FSHR. Methods Previous studies have identified several rare variants of the six GPCR genes in patients with pubertal disorders. In vitro assays and animal studies have provided information on the function of wild‐type and variant GPCRs. Main Findings Of the six GPCRs, those encoded by KISS1R and TACR3 are likely to reside at the top of the HPG axis. Several loss‐of‐function variants in the six genes were shown to cause late/absent puberty. In particular, variants in KISS1R, TACR3, PROKR2, and GNRHR lead to hypogonadotropic hypogonadism in autosomal dominant, recessive, and oligogenic manners. Furthermore, a few gain‐of‐function variants of KISS1R, PROKR2, and LHCGR have been implicated in precocious puberty. The human HPG axis may contain additional GPCRs. Conclusion The six GPCRs in the HPG axis govern pubertal development through fine‐tuning of hormone secretion. Rare sequence variants in these genes jointly account for a certain percentage of genetic causes of pubertal disorders. Still, much remains to be clarified about the molecular network involving the six GPCRs. The human hypothalamic–pituitary‐gonadal axis involves six G‐protein coupled receptors (GPCRs) and their ligands. Genetic abnormalities of the six GPCRs lead to pubertal disorders.

Peroxisome proliferator-activated receptor gamma （PPARy） is a member of the PPARs, which are transcription factors of the steroid receptor superfamily. PPARy acts as an important molecule for regulating energy homeostasis, modulates the hypothalamic-pituitary-gonadal （HPG） axis, and is reciprocally regulated by HPG. In the human, PPARγprotein is highly expressed in ejaculated spermatozoa, implying a possible role of PPARγ signaling in regulating sperm energy dissipation. PPARγ protein is also expressed in Sertoli cells and germ cells （spermatocytes）. Its activation can be induced during capacitation and the acrosome reaction. This mini-review will focus on how PPARy signaling may affect fertility and sperm quality and the potential reversibility of these adverse effects.

The aim of this study was to determine whether testicular volume is correlated with clinical and biochemical markers of hypothalamic-pituitary-testicular (HPT) axis function. This was a cross-sectional substudy of a larger randomized controlled trial including obese men, body mass index (BMI) ≥30 kg m−2, with a total testosterone level <12 nmol l−1. Testicular volume was measured by orchidometer, testosterone by liquid chromatography/tandem mass spectrometry, and body composition by dual-energy X-ray absorptiometry. Men completed the Aging Males' Symptoms (AMS) score, International Index of Erectile Function-5 (IIEF-5), physical function, and handgrip dynamometer testing. Eighty-nine men participated with a median (interquartile range [IQR]) age of 53.1 (47.6, 59.2) years, BMI of 37.0 (34.6, 40.5) kg m−2, and a total testosterone of 7.0 (6.1, 7.9) nmol l−1. Median testicular volume was 18 (IQR: 10, 20) ml. Testicular volume was negatively correlated with BMI (τ = −0.1952, P = 0.010) and total fat mass (τ = −0.2115, P = 0.005) independent of age and testosterone. When BMI, testosterone, sex hormone-binding globulin (SHBG), and luteinizing hormone (LH) were present in a multivariable model, only BMI (-0.38 ml change in testicular volume per 1 kg m-2BMI; 95% CI: −0.74, −0.02; P = 0.04) and LH (-0.92 ml change in testicular volume per 1 IU l-1 LH; 95% CI: −1.75, −0.095; P = 0.03) remained independent significant predictors of testicular volume. Testicular volume was positively correlated with IIEF-5 (τ = 0.2092, P = 0.021), but not related to handgrip strength, physical function tests, or AMS. In obese men, testicular volume is inversely and independently associated with measures of adiposity, but not with most clinical or biochemical markers of HPT axis action. From a clinical perspective, this suggests that obesity might compromise the reliability of reduced testicular volume as a sign of androgen deficiency in men.

Objective: The quantitative reverse transcription polymerase chain reaction (qPCR) is the most accurate and reliable technique for analysis of gene expression. Endogenous reference genes (RGs) have been used to normalize qPCR data, although their expression may vary in different tissues and experimental conditions. Verification of the stability of RGs in selected samples is a prerequisite for reliable results. Therefore, we attempted to identify the most stable RGs in the hypothalamic–pituitary–gonadal (HPG) axis in sows.Methods: The cycle threshold values of nine commonly used RGs (18S, HPRT1, GAPDH, RPL4, PPIA, B2M, YWHAZ, ACTB, and SDHA) from HPG axis-related tissues in the domestic sows in the different stages of estrus cycle were analyzed using two RG-finding programs, geNorm and Normfinder, to rank the stability of the pool of RGs. In addition, the effect of the most and least stable RGs was examined by normalization of the target gene, gonadotropin-releasing hormone (GnRH), in the hypothalamus.Results: PPIA, HPRT1, and YWHAZ were the most stable RGs in the HPG axis-related tissues in sows regardless of the stages of estrus cycle. In contrast, traditional RGs, including 18S and ACTB, were found to be the least stable under these experimental conditions. In particular, in the normalization of GnRH expression in the hypothalamus against several stable RGs, PPIA, HPRT1, and YWHAZ, could generate significant (p<0.05) elevation of GnRH in the preovulatory phase compared to the luteal phase, but the traditional RGs with the least stability (18S and ACTB) did not show a significant difference between groups.Conclusion: These results indicate the importance of verifying RG stability prior to commencing research and may contribute to experimental design in the field of animal reproductive physiology as reference data.