Microsatellite detection of donor-derived sperm DNA following germ cell transplantation in cattle

Although autologous and heterologous transplantation has resulted in colonisation of recipient testes in cattle, the ability of the transplanted spermatogonial stem cells to complete spermatogenesis has not yet been determined. The objective of the present study was to identify and validate microsatellite markers that can distinguish the genotype of different individuals and therefore can be used to detect the presence of donor DNA in recipient semen samples. In a previous study by this group, successful colonisation of recipient testes by heterologous transfer using a fluorescent dye was shown. In the present work, some of the same recipient animals were investigated further to monitor donor-derived sperm production. The bovine microsatellite detection method was developed specifically to test the ejaculates of the recipients and can also be used to pre-match individuals before germ cell transplantation. Semen was collected from the recipients 52–98 weeks after transfer and the presence of donor DNA in the samples was determined using microsatellite markers. In one of the recipients, all collected semen samples were shown to be positive for donor-derived cells; however, the percentage of donor spermatozoa in the recipient ejaculate declined with time. The donor DNA was also detected in both single cell suspensions and testis tissue from this recipient. These results demonstrate for the first time that testicular germ cell transplantation between different breeds of cattle is feasible and the recipients thereof are able to produce spermatozoa of donor origin. This technology has potential applications in livestock breeding systems and may provide an alternative to artificial insemination

Large quantity cryopreservation of bovine testicular cells and its effect on enrichment of type A spermatogonia

Cryopreservation has become an integral component of any cell transplantation technique helping to overcome the issues associated with known spatial and temporal barriers between donor and recipient. The aim of this study was to develop a protocol for large quantity cryopreservation of bovine testicular germ cells. The impact of 3 different packaging methods (5 ml semen straw, 20 ml freezing bag and 1.5 ml cryovial) and varying cell densities (3 × 10⁶, 9 × 10⁶, or 18 × 10⁶ cells/ml) on the survival of testis germ cells was examined. Cells processed in 5 ml semen straws had a significantly higher viability (70.7 ± 1.2%,

Irradiation Enhances the Efficiency of Testicular Germ Cell Transplantation in Sheep

Testis germ cell transplantation in livestock has the potential for production of transgenic genotypes and for use as an alternative to artificial insemination in animal breeding systems. In a pilot experiment, we investigated a workable protocol for testis germ cell transplantation in sheep, including donor cell isolation, rete testis injection, and microsatellite detection of donor spermatozoa in recipient semen. In a second experiment, the effect of depletion of endogenous stem cells with a single irradiation dose of 9 Gy (n = 5) or 15 Gy (n = 5) on the outcome of germ cell transplantation was investigated. Irradiation of recipient testes with a single dose of 15 Gy, followed by transplantation 6 wk after depletion, may be most advantageous because it resulted in all recipients (five of five) producing donor-derived spermatozoa, while the 9-Gy and control groups had limited success rates (two of five and one of three, respectively). Using microsatellite markers to detect the presence of donor DNA, 10 rams were identified that produced spermatozoa of donor origin. The proportion of donor DNA was between 1% and 30% of total ejaculate DNA. When three of these positive rams were used in breeding experiments, four donor-derived offspring (four of 50 [8% of progeny])resulted from a recipient in Merino to Merino transplantation. Six lambs (six of 41 [15% of progeny]) were sired by donor-derived Border Leicester sperm produced in a Merino recipient ram; however, no donor-derived offspring were detected among 34 progeny from a second Border Leicester to Merino combination. These results confirm that preparation of recipient animals with a correct dose of irradiation not only enhances the success rate of the transplantation procedure but also increases the proportion of donor spermatozoa in recipient semen. This study represents the first report of the production of live progeny following testis germ cell transplantation using irradiated recipients in a livestock species

A comparison of methods for preparing enriched populations of bovine spermatogonia

The objective of the present study was to identify an efficient and practical enrichment method for bovine type A spermatogonia. Four different enrichment methods were compared: differential plating on laminin- or Datura stramonium agglutinin (DSA)-coated flasks, percoll-gradient isolation, magnetic-activated cell sorting (MACS) and fluorescence-activated cell sorting (FACS). The isolated cells were characterised with Dolichos biflorus agglutinin (DBA) lectin staining for type A spermatogonia and vimentin-antibody staining for Sertoli cells. A 2 x 2 factorial design was used to investigate the enrichment efficiency on laminin and DSA. In the laminin- enrichment groups, 2 h incubation in plates coated with 20 mu g mL(-1) laminin yielded a 3.3-fold increase in DBA-positive cells in the adherent fraction, while overnight incubation in flasks coated with 20 mu g mL(-1) DSA produced a 3.6-fold increase in the non-adherent fraction. However, the greatest enrichment (5.3-fold) of DBA-positive cells was obtained after 2 h incubation in control flasks (coated with bovine serum albumin). Percoll-gradient centrifugation yielded a 3-fold increase in DBA-positive cells. MACS results showed a 3.5- to 5-fold enrichment while FACS produced a 4-fold increase in DBA-positive cells. It is concluded that differential plating is a better method of recovering large numbers of type A spermatogonia for germ cell transplantation, while MACS or FACS can provide highly enriched viable type A spermatogonia for in vitro culture. Further, the combination of differential plating and other enrichment techniques may increase the purification efficiency of type A spermatogonia