The primary aim of this study was to establish a flow cytometric technique for determining the capacitation status of stallion spermatozoa. To this end, a flow cytometric technique that demonstrates changes in plasma membrane fluidity; namely, merocyanine 540 staining, was compared with the more conventional Ca(2+)-dependent fluorescence microscopic technique, chlortetracycline (CTC) staining, for assessing capacitation status. In addition, the effect of bicarbonate/CO(2) on the progress of capacitation and the acrosome reaction (AR) and on temporal changes in sperm motility, with particular regard to hyperactivation, was analyzed. For the study, fresh semen was washed and then incubated for 5 h in bicarbonate-containing or bicarbonate-free medium, with or without Ca(2+) ionophore to induce the AR, and at intervals during incubation aliquots were taken and analyzed for capacitation and acrosome status. The AR was assessed using both the CTC and fluorescein isothiocyanate-peanut agglutinin (FITC-PNA) staining techniques with similar results. In brief, it was found that merocyanine 540 detects capacitation-related changes much earlier than CTC does (0.5 h versus approximately 3 h), and that flow cytometry for evaluation of capacitation and AR was a quicker (10 sec per sample) and more accurate (10,000 cells counted) technique than fluorescence microscopy. Furthermore, it was observed that Ca(2+) ionophore could not induce the AR in the absence of bicarbonate, but that the ionophore synergized the bicarbonate-mediated induction of the AR as detected by CTC (although it was not significant when evaluated using FITC-PNA). The percentage of hyperactive sperm in each sample was not affected by time of incubation under the experimental conditions studied. In conclusion, merocyanine 540 staining is a better method than CTC staining for evaluating the early events of capacitation for stallion spermatozoa incubated in vitro. Furthermore, bicarbonate sperm activation clearly plays a vital role in the induction of the AR in stallion spermatozoa.
Identification and isolation of spermatogonial stem cells (SSCs) are a prerequisite for culture, genetic manipulation, and/or transplantation research. In this study, we established that expression of PGP 9.5 is a spermatogonia-specific marker in porcine testes. The expression pattern of PGP 9.5 in spermatogonia was compared to cell type-specific protein (GATA-4 or PLZF) expression in seminiferous tubules at different ages, and expression levels of PGP 9.5, Vasa, and Oct-4 were compared in different cell fractions. Enrichment of spermatogonia from 2-week-old (2wo) and 10-week-old (10wo) boars by adhesion to laminin, differential plating, or velocity sedimentation followed by differential plating was assessed by identification of spermatogonia using expression of PGP 9.5 as a marker. Compared to the initial samples, spermatogonia were enriched twofold in laminin-selected cells (P < 0.05), and fivefold either in cells remaining in suspension (fraction I) or in cells slightly attached to the culture dish (fraction II) (P < 0.05) after differential plating. Cells in fraction II appeared to be superior for future experiments due to higher viability (>90%) than in fraction I ( approximately 50%). Velocity sedimentation plus differential plating achieved cell populations containing up to 70% spermatogonia with good viability (>80%). Enriched spermatogonia from 2wo and 10wo testes could be maintained in a simple culture medium without additional growth factors for at least 2 weeks and continued to express PGP 9.5. These data provide the basis for future studies aimed at refining conditions of germ cell culture and manipulation prior to germ cell transplantation in pigs.
During mammalian development, morphogenesis of the testis requires the coordinated interplay of somatic cells to form seminiferous cords in which the primitive germ cells reside. These cords are the precursor of the functional male gonad and as such form the basis of male fertility. Cell migration during mammalian organogenesis and formation of complex tissues, such as the testis, are difficult to study in situ. Herein, we report extensive rearrangement of cells to regenerate complete functional testis tissue after implantation of isolated neonatal porcine testis cells under the skin of immunodeficient mice. Somatic cells and germ cells reorganized into structures that have remarkable morphologic and physiologic similarity to normal testis tissue, forming the endocrine and spermatogenic compartment of the testis. This unique in vivo system provides an accessible model for the study of testicular morphogenesis that could be especially useful in nonrodent species.
Grafting of immature mammalian testis tissue to mouse hosts can preserve the male germline. To make this approach applicable to a clinical or field situation, it is imperative that the testis tissue and/or spermatozoa harvested from grafted tissue are preserved successfully. The aim of the present study was to evaluate protocols for the preservation of testis tissue in a porcine model. Testis tissue was stored at 4°C for short-term preservation or cryopreserved by slow-freezing, automated slow-freezing or vitrification for long-term storage. Preserved tissue was transplanted ectopically to mouse hosts and recovered xenografts were analysed histologically. In addition, spermatozoa were harvested from xenografts and cryopreserved. Total cell viability and germ cell viability remained high after tissue preservation. Complete spermatogenesis occurred in xenografts preserved by cooling up to 48 h, whereas spermatogenesis progressed to round spermatids in the xenografts that were frozen–thawed before grafting. Approximately 50% of spermatozoa harvested from xenografts remained viable after freezing and thawing. The in vivo developmental potential of cryopreserved tissue was reduced despite high post-thaw viability. Therefore, it is important to evaluate germ cell differentiation in vivo in addition to cell viability in vitro when optimising freezing protocols for testis tissue.
Recovery of germ cells could be an option for preservation of the genetic pool of endangered animals. In immature males, xenografting of testis tissue provides the opportunity to recover sperm from these animals. In adult animals, xenografting has been less successful, but de novo morphogenesis of functional testis tissue from dissociated testis cells could be an alternative. To assess the potential use of these techniques in endangered bovid species, the domestic sheep was used as a model. Testes from 2-week-old lambs were grafted as tissue fragments or cell suspensions into nude mice. Grafts were recovered at 4, 8, 12 and 16 weeks post grafting. For isolated cells, two additional time points at 35 and 40 weeks after grafting were added. In addition, to analyse the possible effect of social stress among mice within a group on the development of the grafts, testis tissue grafts were recovered 13 weeks post grafting from mice housed individually and in groups. Complete spermatogenesis occurred in sheep testis xenografts at 12 weeks, similar to the situation in situ. Isolated sheep testis cells were able to reorganize and form functional testicular tissue de novo. Housing mice individually or in groups did not have any effect on the development of xenografts. Xenografting of testis tissue might be useful to obtain sperm from immature endangered ungulates that die prematurely. Testis tissue de novo morphogenesis from isolated cells could open interesting options to recover germ cells from mature males with impaired spermatogenesis. Reproduction (2008) 136 85-93
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