Abstract. The transition from male primitive germ cells (gonocytes) to type A spermatogonia in the neonatal testis is the initial process and a crucial process in spermatogenesis. However, in large domestic animals, the physiological and biochemical characteristics of germ cells during the developmental processes remain largely unknown. In this study, we characterized bovine germ cells in the developing testis from the neonatal stage to the adult stage. The binding of the lectin Dolichos biflorus agglutinin (DBA) and the expression of ubiquitin carboxyl-terminal hydrolase 1 (UCHL1) were restricted to gonocytes in the neonatal testis and spermatogonia in the adult testis. Gonocytes also expressed a germ cell marker (VASA) and stem cell markers (NANOG and OCT3/4), while the expressions of these markers in the adult testis were restricted to differentiated spermatic cells and were rarely expressed in spermatogonia. We subsequently utilized these markers to characterize gonocytes and spermatogonia after culture in vitro. Spermatogonia that were collected from the adult testis formed colonies in vitro only for one week. On the other hand, gonocytes from the neonatal testis could proliferate and form colonies after every passage for 1.5 months in culture. These colonies retained undifferentiated states of gonocytes as confirmed by the expression of both germ cell and stem cell markers. Moreover, a transplantation assay using immunodeficient mice testes showed that long-term cultured cells derived from gonocytes were able to colonize in the recipient testis. These results indicated that bovine gonocytes could maintain germ cell and stem cell potential in vitro. Key words: Gonocytes, Spermatogonia, Spermatogenesis, Stem cells, Testis (J. Reprod. Dev. 57: [355][356][357][358][359][360][361][362][363][364] 2011) erm cells originate from primordial germ cells (PGCs), which are primary cells on the germline lineage in embryos. After migration to the genital ridge, male germ cells become gonocytes [1]. At a certain period after birth, gonocytes migrate to the basement membrane of the testis and differentiate to type A spermatogonia including spermatogonial stem cells (SSCs). SSCs have the potential to self-renew and generate differentiated germ cells, resulting in the production of large numbers of spermatozoa throughout most or all of adult life. Thus, gonocytes have key roles in producing SSCs and initiating spermatogenesis. In mice, the transition of gonocytes to SSCs begins 3 days after birth [2]. Although some report have shown the postnatal testis development in large domestic species including cattle (Bos indicus [3], Bos taurus [4,5]), little is known about gonocytes during their development in cattle.Specific germ cell markers have been identified in the mouse testis. One such marker is VASA, a DEAD (asparagineglutamine-alanine-asparagine) box protein 4 (DDX4) that is required for male germ cell development in mice [6,7]. Additionally, stem cell characteristics of mouse SSCs were determined by a transplantation a...
Gonocytes are primitive germ cells that are present in the neonatal testis and are committed to male germline development. Gonocytes differentiate to spermatogonia, which establish and maintain spermatogenesis in the postnatal testis. However, it is unknown whether large animal species have pluripotency-specific proteins in the testis. Nanog and Pou5f1 (Oct3/4) have been identified as transcription factors essential for maintaining pluripotency of embryonic stem cells in mice. Here, we show that NANOG protein was expressed in the germ cells of neonatal pig testes, but was progressively lost with age. NANOG was expressed in most of the lectin Dolichos biflorus agglutinin-and ZBTB16-positive gonocytes, which are known gonocyte-specific markers in pigs. NANOG was also expressed in Sertoli and interstitial cells of neonatal testes. Interestingly, POU5F1 expression was not detected at either the transcript or the protein level in neonatal pig testis. In the prepubertal testis, NANOG and POU5F1 proteins were primarily detected in differentiated germ cells, such as spermatocytes and spermatids, and rarely in undifferentiated spermatogonia. By using a testis transplantation assay, we found that germ cells from 2-to 4-day-old pigs could colonize and proliferate in the testes of the recipient mice, suggesting that primitive germ cells from neonatal pig testes have stem cell potential.
This study examined the influences of epidermal growth factor (EGF) and growth differentiation factor 9 (GDF9) on in vitro viability and activation of primordial follicles in the ovarian tissue of prepubertal (age, <6 mo) versus adult (age, >8 mo) cats. Ovarian cortical slices were cultured in medium containing EGF and/or GDF9 for 14 days. EGF, but not GDF9, improved (P < 0.05) follicle viability in prepubertal donors in a dose-dependent fashion. Neither EGF nor GDF9 enhanced follicle viability in ovarian tissue from adults, and neither factor activated primordial follicles regardless of age group. We then explored how EGF influenced primordial follicles in the prepubertal donors by coincubation with an inhibitor of EGF receptor (AG1478), mitogen-activated protein kinase (MAPK; U0126), or phosphoinositide 3-kinase (PI3K; LY294002). EGF enhanced (P < 0.05) MAPK and AKT phosphorylation, follicle viability, and stromal cell proliferation. These effects were suppressed (P < 0.05) when the tissue was cultured with this growth factor combined with each inhibitor. To identify the underlying influence of age in response to EGF, we assessed cell proliferation and discovered a greater thriving stromal cell population in prepubertal compared to adult tissue. We conclude that EGF plays a significant role in maintaining intraovarian primordial follicle viability (but without promoting activation) in the prepubertal cat. The mechanism of action is via stimulation of MAPK and PI3K signaling pathways that, in turn, promote ovarian cell proliferation. Particularly intriguing is that the ability of cat ovarian cells to multiply in reaction to EGF is age-dependent and highly responsive in prepubertal females.
Contents Our objective was to examine the influences of differing media, protein supplementation and the microenvironment on cat vs dog primordial follicle viability in vitro. Ovarian cortical slices were cultured for 3, 9 or 15 days in α-minimum essential medium (α-MEM) or MEM supplemented with 10% fetal bovine serum (FBS), 10% knock-out serum replacement (KSR) or 0.1% polyvinyl alcohol (protein free). In a separate study, cat and dog ovarian tissues were cultured in protein-free α-MEM and MEM, respectively, in cell culture inserts, on 1.5% agarose gel or in 24-well cell culture plates (control). Follicle viability was assessed in both studies using calcein AM/ethidium homodimer and histological evaluation with haematoxylin/eosin staining. No cat follicle sustained viability beyond 9 days of in vitro culture in α-MEM compared to 37.5% of those incubated for 15 days in MEM in protein-free condition (p < 0.05). In contrast, α-MEM was superior (p < 0.05) to MEM in maintaining dog follicle viability (32.7% vs 8.1%) in protein-free condition at 15 days. Serum was detrimental (p < 0.05) to follicle survival in both species. Knock-out serum replacement supplementation and a protein-free condition supported cat follicle viability, whereas the latter was superior (p < 0.05) to the former for sustaining dog follicle survival. Likewise, dog follicle viability was enhanced (p < 0.05) by the agarose gel compared to the cell culture insert and control groups after 3 and 9 days of culture. For the cat, the agarose gel better (p < 0.05) supported follicle viability compared to the control, but was equivalent to the cell culture insert. Therefore, sustaining primordial follicle survival from intracortical ovarian slices requires a different in vitro microenvironment for the cat vs the dog. A key factor to enhancing survival of these early stage follicles in culture appears to be the use of agarose gel, which enhances follicle viability, perhaps by promoting gas exchange.
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