Spermatogonial stem cells are responsible for the constant production of spermatozoa. These cells differentiate from the gonocytes, but little is known about these cells and their differentiation into spermatogonia. This study analyzed rat gonocyte proliferation, death and distribution as well as their differentiation into spermatogonia. Rat testes were collected at 19 dpc and at 1, 3, 5, 8, 11 and 15 dpp and submitted to apoptosis investigation through morphological analysis and TUNEL, p53 and cleaved caspase 3 labeling. Ki67 and MVH labeling was used to check gonocyte proliferation and quantification, respectively. OCT4 and DBA labeling were used to check gonocyte differentiation. Seminiferous cord length and gonocyte numerical density were measured to check gonocyte distribution along the seminiferous cords. Although a reduction of gonocyte number per testicular section has been observed from 1 to 5 dpp, the total number of these cells did not change. Apoptotic gonocytes were not detected at these ages, suggesting that the reduction in gonocyte number per testicular section was due to their redistribution along the seminiferous cords, which showed continuous growth from 19 dpc to 5 dpp. The first proliferating germ cells were observed at 8 dpp, coinciding with OCT4 upregulation and with the emergence of the first spermatogonia. In conclusion, this study suggests that (a) gonocytes do not die in the first week after birth, but are rather redistributed along the seminiferous cords just before their differentiation into spermatogonia; (b) mitosis resumption and the emergence of the first spermatogonia are coincident with OCT4 upregulation.
The role of differentiated trophoblast glycogen cells (GCs) in the ectoplacental cone (EPC) has not been elucidated yet. Recently, GC progenitors have been shown to be present from embryonic day 7.5 (E7.5), but glycogen is found in GC only from E10.5. Herein, we investigated the origin, localization and characterization of mouse GCs in EPC and their relationship with blood cells and trophoblast giant cells (TGCs) during placentation. Implantation sites (E5.5-E12.5) were processed for histological studies, histochemical detection (glycogen) and immunohistochemical staining (Ki67). Three-dimensional reconstruction of the EPC was obtained from suitably oriented embryos at E7.5. Our findings evidence that GCs are present and assembled in clusters from E6.5 to E12.5, and that they exhibit the classic vacuolated appearance and contain PAS-positive glycogen, which is amylase-sensitive and acetylation-resistant. In fact, only GCs were stained after acetylation, confirming unequivocally their presence in tissues. At E6.5, GCs showed numerous mitoses and vacuoles with scattered glycogen particles. At E7.5, GCs showed low numbers of mitoses and abundant vacuoles full of glycogen. During E7.5-E8.5, GCs were in close proximity to TGCs, and cells were intercalated by thin maternal blood spaces; placental GCs lost maternal blood contact during E9.5-E12.5. Our results indicate that GCs are originated and proliferate in the upper portion in the midregion of EPC at E6.5, and that at E7.5-E8.5 they show consistent glycogen deposits, which are likely metabolized to glucose. This compound may be directly transferred to circulating maternal blood, and used as a source of energy by GCs and TGCs during placentation.
BackgroundPrimordial germ cells (PGC) are the precursors of the gametes. During pre-natal development, PGC undergo an epigenetic reprogramming when bulk DNA demethylation occurs and is followed by sex-specific de novo methylation. The de novo methylation and the maintenance of the methylation patterns depend on DNA methyltransferases (DNMTs). PGC reprogramming has been widely studied in mice but not in rats. We have previously shown that the rat might be an interesting model to study germ cell development. In face of the difficulties of getting enough PGC for molecular studies, the aim of this study was to propose an alternative method to study rat PGC DNA methylation. Rat embryos were collected at 14, 15 and 19 days post-coitus (dpc) for the analysis of 5mC, 5hmC, DNMT1, DNMT3a and DNMT3b expression or at 16dpc for treatment 5-Aza-CdR, a DNMT inhibitor, in vitro.MethodsOnce collected, the gonads were placed in 24-well plates previously containing 45μm pore membrane and medium with or without 5-Aza-CdR. The culture was kept for five days and medium was changed daily. The gonads were either fixed or submitted to RNA extraction.Results5mC and DNMTs labelling suggests that PGC are undergoing epigenetic reprogramming around 14/15dpc. The in vitro treatment of rat embryonic gonads with 1 μM of 5-Aza-CdR lead to a loss of 5mC labelling and to the activation of Pax6 expression in PGC, but not in somatic cells, suggesting that 5-Aza-CdR promoted a PGC-specific global DNA hypomethylation.ConclusionsThis study suggests that the protocol used here can be a potential method to study the wide DNA demethylation that takes place during PGC reprogramming.
Carbamazepine (CBZ) is used in the control of seizure and affective disorders, causing hypothyroidism. Thyroid hormones regulate the Sertoli cell proliferation and differentiation. Clinical aspects must be considered since epileptic fertile women need to continuously use CBZ during pregnancy and lactation. This study aimed to evaluate the effects of CBZ on testis development of rat offspring from dams treated during pregnancy/lactation. Rat dams received CBZ (20 mg kg−1 day−1) or vehicle by intra‐peritoneal route during gestation and lactation. Progenies were euthanised at 4, 14, 41, 63 and 93‐days post‐partum (dpp) for the evaluation of T3, T4 and TSH plasma total levels. Testicular cross sections were submitted to anti‐Ki67, anti‐PCNA, anti‐p27kip1 and anti‐transferrin immunolabelling for the evaluation of Sertoli cells. There was a significant reduction in p27kip1‐positive Sertoli cell numerical densities and an increase in TSH level at 14 dpp. CBZ exposure affected the volume density of transferrin‐positive immunolabelling at 63 dpp. These results suggest that CBZ may cause a dysregulation of the controller system of thyroid hormones homeostasis leading to an increase in the proliferation rate at the neonatal phase and a differentiation delay of the Sertoli cell, culminating in an altered function at late puberty. The occurrence of hypothyroidism cannot be completely discarded.
Overweight and obesity are pandemic problems, occurring in high-, middle-, and low-income countries (particularly in urban areas), in both sexes, and in all age groups. Obesity can cause changes in the levels of sex hormones, in the spermatogenic process, and in sperm maturation, leading to reduced sperm quality, oligospermia, damage to DNA integrity, affecting sperm motility and capacitation, and therefore interfering in the fertilization process and in the quality of the embryo. Moreover, the increase in adipose tissue may cause elevated concentrations of sex steroids, adipokines, and leptin, as well as the aromatization of androgens into estrogens, which may accelerate the onset of puberty and, subsequently, the seminal quality and homeostasis of sex hormones in adulthood. However, the literature is contradictory about the effects of obesity on the onset of puberty, sperm and male fertility.
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