The effect of donor age on progression of spermatogenesis in canine testicular tissue after xenografting into immunodeficient mice

The objective of this study was to examine the effect of donor age on progression of spermatogenesis in dog (Canis lupus familiaris) testis tissue after xenografting. In Experiment 1, canine testes were obtained by surgical castration. Based on developmental pattern of spermatogenesis at the time of grafting, donors were categorized as immature, young, and adult (<4, 4 to 6, and >6 mo old, respectively). Fragments of testis tissue were implanted subcutaneously on the back of immunodeficient mice; xenografts were retrieved and analyzed 4, 6, or 8 mo later. At 4 mo postgrafting, immature and young groups had higher graft recovery rates, graft weights, vesicular gland indices, seminiferous tubule numbers, and larger seminiferous tubular diameters compared with those of adult donor xenografts. At 8 mo postgrafting, immature donor xenografts had maintained growth and development as exhibited by greater graft weights, vesicular gland indices, seminiferous tubule numbers, and tubular diameters compared with those of adult donor xenografts. At this time point, growth and development of xenografts did not differ between immature and young donors, whereas those from young donors had greater seminiferous tubule numbers and diameters compared with those of adult donor xenografts. Elongated spermatids were the most advanced germ cell type present at 4 and 8 mo postgrafting in xenografts of immature age groups. In Experiment 2, the longer-term efficiency of spermatogenesis and the potential sperm production in xenografts from immature donor dogs were determined. Testis tissue from 2-mo-old donor dogs were grafted into recipient mice, and xenografts were retrieved after 13 mo. Complete spermatogenesis was present in 5 of 29 recovered xenografts, with isolation of fully formed sperm (up to 36.3 × 10⁶ per gram tissue). In conclusion, immature and young donors (<6 mo of age) were the most promising donors for dog testis tissue xenografting. This strategy may offer an alternative for male germ-line preservation for canids that die prematurely or must be castrated before maturation.     

Grafting period and donor age affect the potential for spermatogenesis in bovine ectopic testis xenografts

Bovine testis tissue xenografts contain elongating spermatids 6 mo after grafting. The percentage of seminiferous tubule cross sections with elongating spermatids at the time of graft removal varies depending on donor age and rarely exceeds 10%. These data indicate significant changes are occurring to bovine testicular cells during the first weeks of life. The objective of this research was to xenograft testis tissue from multiple ages of bull calves for 24 or 36 wk in order to gain a better understanding of early bovine testis development. Testis tissue from 1-, 2-, 4-, and 8-wk-old calves was grafted onto the backs of castrated immunodeficient mice. Testis tissue from all donor ages grew, differentiated, and produced testosterone and elongating spermatids. Testis tissue grafts from 1- and 8-wk-old calves had elongating spermatids in greater than 5.5% of seminiferous tubule cross sections at the time of graft removal regardless of grafting period. Four-week-old donor tissue never had more than 5.2% of seminiferous tubule cross sections with elongating spermatids. Extending the grafting period from 24 to 36 wk resulted in an increase in the percentage of seminiferous tubule cross sections with elongating spermatids from 2% to 10% in 2-wk donor tissue. These data demonstrate that both donor age and grafting period may be important factors regulating the maturation of bovine testis xenografts, indicating that intrinsic differences exist within testis tissue at these donor ages. These data provide the framework for further study of bovine spermatogenesis using ectopic testis xenografting.     

Establishment of spermatogenesis in neonatal bovine testicular tissue following ectopic xenografting varies with donor age

Ectopic testicular xenografting can be used to investigate spermatogenesis and as an alternative means for generating transgenic spermatozoa in many species. Improving the efficiency of spermatogenesis in xenografted testicular tissue will aid in the application of using this approach. The present study was conducted to evaluate age-related differences in the establishment of spermatogenesis in grafted testicular tissue from bulls between 2 and 16 wk of life. Testicular tissue was ectopically xenografted under the skin on the backs of castrated nude mice and subsequently evaluated for growth, testosterone production, and establishment of spermatogenesis 24 wk after grafting. The greatest weight increases occurred in donor tissue from calves of the ages 2, 4, and 8 wk compared with the ages of 12 and 16 wk. Recipient mouse serum testosterone concentration was at normal physiological levels 24 wk after grafting and no significant differences were detected between recipients grafted with testicular tissue from bull calves of different ages. The development of germ cells to elongated spermatids were observed in seminiferous tubules of grafts from donor calves of the ages 4, 8, 12, and 16 wk but not observed in grafts from 2-wk donors, which contained round spermatids as the most advanced germ cell stage. Grafts from 8-wk donors contained a significantly higher (10-fold) average percentage of seminiferous tubules with elongated spermatids than all other donor ages. These data demonstrate differences in the ability of testicular tissue from donor animals of different ages to establish spermatogenesis following ectopic testicular xenografting.     

Xenografting of adult mammalian testis tissue

Xenografting of testis tissue from immature males from several mammalian species to immunodeficient mouse hosts results in production of fertilization-competent sperm. However, the efficiency of testis tissue xenografting from adult donors has not been critically evaluated. Testis tissue xenografting from sexually mature animals could provide an option to preserve the genetic material from valuable males when semen for cryopreservation cannot be collected. To assess the potential use of this technique for adult individuals, testes from adult animals of six species (pig, goat, cattle, donkey, horse and rhesus monkey) were ectopically grafted to host mice. Grafts were recovered and analyzed at three time points: less than 12 weeks, between 12 and 24 weeks and more than 24 weeks after grafting. Histological analysis of the grafts revealed effects of species and donor tissue maturity: all grafts from species with greater daily sperm production (pig and goat) were found to have degenerated tubules or grafts were completely degenerated. None of the xenografts from mature adult bull and monkeys contained differentiated spermatogenic cells when examined more than 12 weeks post-grafting but tubules with Sertoli cells only remained. In grafts from a young adult bull, Sertoli cells persisted much longer than with the mature adult grafts. In grafts from a young adult horse, spermatogenesis proceeded to meiosis. In grafts from a young adult donkey and monkey, however, complete spermatogenesis was found in the grafts. These results show that testis tissue grafts from mature adult donors did not support germ cell differentiation but seminiferous tubules with Sertoli cells only survived in some species. The timing and progression of tubular degeneration after grafting of adult testis tissue appear to be related to the intensity of spermatogenesis at the time of grafting. Testis tissue from sub-adult donors survives better as xenograft than tissue from mature adult donors, and complete spermatogenesis can occur albeit with species-specific differences.     

Spermatogenesis in ferret testis xenografts: a new model

Testis xenografting is both a promising tool to study spermatogenesis and a means to preserve the genetic information and reproductive potential of prepubertal male animals. The present study was conducted to evaluate this technique using testis tissue from domestic ferrets, an important biomedical model and a model for the conservation of small carnivore species. Fresh testis tissue from 8-wk-old ferrets was implanted ectopically under the skin on the backs of castrated nude mice and subsequently evaluated for testosterone production and establishment of spermatogenesis at 10, 20, 25, and 30 wk after xenografting. A total of 40% of fresh ferret xenografts were harvested. Seminal vesicles were collected from the recipient mice and weighed as an assay for bioactive testosterone. The weights of seminal vesicles from the mice showed no significant difference from those of uncastrated, control nude mice, indicating that the xenografts were producing physiologically relevant amounts of testosterone. The ferret testis xenografts produced differentiating germ cells and sperm at the same time as did testis from age-matched control ferrets. These data demonstrate the ability of Mustelidae testicular tissue to establish spermatogenesis in nude mice after testis xenografting.     

Accelerated maturation of primate testis by xenografting into mice

Testicular maturation and sperm production throughout the life of the male form the basis of male fertility. It is difficult to elucidate the intricate processes controlling testicular maturation and spermatogenesis in primates in vivo due to the long time span required for sexual maturation and also to the lack of accessible in vitro or in vivo models of primate spermatogenesis. Ectopic xenografting of neonatal testis tissue into mice provides an accessible model to study and manipulate the propagation and differentiation of male germ cells from immature donor animals. However, it was not clear whether this approach would be applicable to slowly maturing primates. Here we report that grafting of testis tissue from immature rhesus monkeys (Macaca mulatta) into host mice resulted in the acceleration of testicular maturation and production of fertilization-competent sperm in testis xenografts. The system reported here provides a powerful, practical approach to study timing and control of testicular maturation and regulation of primate spermatogenesis without the necessity for experimentation in primates. This approach could potentially be applied to produce fertile sperm from sexually immature individuals of rare or valuable primate species or from prepubertal boys undergoing sterilizing therapy for cancer.     

Spermatogenesis and germ cell transgene expression in xenografted bovine testicular tissue

The present study was conducted to evaluate the development of spermatogenesis and utility of using electroporation to stably transfect germ cells with the beta-galactosidase gene in neonatal bovine testicular tissue ectopically xenografted onto the backs of recipient nude mice. Bull testicular tissue from 4-wk donor calves, which contains a germ cell population consisting solely of gonocytes or undifferentiated spermatogonia, was grafted onto the backs of castrated adult recipient nude mice. Testicular grafts significantly increased in weight throughout the grafting period and the timing of germ cell differentiation in grafted tissue was consistent with postnatal testis development in vivo relative to the bull. Seminiferous tubule diameter also significantly increased with advancing time after grafting. At 1 wk after grafting, gonocytes in the seminiferous cords completed migration to the basement membrane and differentiated germ cell types could be observed 24 wk after grafting. The presence of elongating spermatids at 24 wk confirmed that germ cell differentiation occurred in the bovine tissue. Leydig cells in the grafted bovine tissue were also capable of producing testosterone in the castrated recipient mice from 4 wk to 24 wk after grafting at concentrations that were similar to levels in intact, nongrafted control mice. The testicular tissue that had been electroporated with a beta-galactosidase expression vector showed tubule-specific transgene expression 24 wk after grafting. Histological analysis showed that transgene expression was present in both Sertoli and differentiated germ cells but not in interstitial cells. The system reported here has the potential to be used for generation of transgenic bovine spermatozoa.     

Cryopreservation of immature porcine testis tissue to maintain its developmental potential after xenografting into recipient mice

The purpose of this study was to develop effective strategies for cooling and cryopreservation of immature porcine testis tissue that maintain its developmental potential. Testes from 1-wk-old piglets (Sus domestica) were subjected to 1 of 12 cooling/cryopreservation protocols: as intact testes, cooling at 4 °C for 24, 48, or 72 h (Experiment 1); as fragments, programmed slow-freezing with dimethyl sulfoxide (DMSO), glycerol, or ethylene glycol (Experiment 2); or solid-surface vitrification using DMSO, glycerol, or ethylene glycol, each using 5-, 15-, or 30-min cryoprotectant exposure times (Experiment 3). For testis tissue xenografting, four immunodeficient recipient mice were assigned to each protocol, and each mouse received eight grafts. Recipient mice were killed 16 wk after grafting to assess the status of graft development. Based on morphology and in vitro assessment of cell viability, cooling of testis tissue for up to 72 h maintained structural integrity, cell viability, in vivo growth, and developmental potential up to complete spermatogenesis comparable with that of fresh tissue (control). In frozen-thawed testis tissues, higher numbers of viable cells were present after programmed slow-freezing using glycerol compared with that after DMSO or ethylene glycol (P < 0.001). Among the vitrified groups, exposure to DMSO for 5 min yielded numerically higher viable cell numbers than that of other groups. Cryopreserved tissue fragments recovered after xenografting had normal spermatogenesis; germ cells advanced to round and elongated spermatids after programmed slow-freezing using glycerol, as well as after vitrification using glycerol with 5- or 15-min exposures, or using DMSO for a 5-min exposure.     

Germ Cell Transplantation and Testis Tissue Xenografting in Mice

Germ cell transplantation was developed by Dr. Ralph Brinster and colleagues at the University of Pennsylvania in 1994^1,2. These ground-breaking studies showed that microinjection of germ cells from fertile donor mice into the seminiferous tubules of infertile recipient mice results in donor-derived spermatogenesis and sperm production by the recipient animal². The use of donor males carrying the bacterial β-galactosidase gene allowed identification of donor-derived spermatogenesis and transmission of the donor haplotype to the offspring by recipient animals¹. Surprisingly, after transplantation into the lumen of the seminiferous tubules, transplanted germ cells were able to move from the luminal compartment to the basement membrane where spermatogonia are located³. It is generally accepted that only SSCs are able to colonize the niche and re-establish spermatogenesis in the recipient testis. Therefore, germ cell transplantation provides a functional approach to study the stem cell niche in the testis and to characterize putative spermatogonial stem cells. To date, germ cell transplantation is used to elucidate basic stem cell biology, to produce transgenic animals through genetic manipulation of germ cells prior to transplantation^4,5, to study Sertoli cell-germ cell interaction^6,7, SSC homing and colonization^3,8, as well as SSC self-renewal and differentiation^9,10.Germ cell transplantation is also feasible in large species¹¹. In these, the main applications are preservation of fertility, dissemination of elite genetics in animal populations, and generation of transgenic animals as the study of spermatogenesis and SSC biology with this technique is logistically more difficult and expensive than in rodents. Transplantation of germ cells from large species into the seminiferous tubules of mice results in colonization of donor cells and spermatogonial expansion, but not in their full differentiation presumably due to incompatibility of the recipient somatic cell compartment with the germ cells from phylogenetically distant species¹². An alternative approach is transplantation of germ cells from large species together with their surrounding somatic compartment. We first reported in 2002, that small fragments of testis tissue from immature males transplanted under the dorsal skin of immunodeficient mice are able to survive and undergo full development with the production of fertilization competent sperm¹³. Since then testis tissue xenografting has been shown to be successful in many species and emerged as a valuable alternative to study testis development and spermatogenesis of large animals in mice¹⁴.     

Quantitative Analysis of the Cellular Composition in Seminiferous Tubules in Normal and Genetically Modified Infertile Mice

The aim of this study was to establish a quantitative standard for the cellular composition in seminiferous tubules at each stage of spermatogenesis in the mouse testis, and thereby evaluate abnormalities in the infertile mouse testis. We applied a combination of lectin histochemistry for acrosomes and immunohistochemistry for various specific cell markers, both of which were visualized with fluorescence, on paraffin sections of the testis. We first examined seminiferous tubules from normal mice and counted the number of each cell type at each stage of spermatogenesis. We then examined seminiferous tubules from genetically modified mice deficient (-/-) for one of the cell adhesion molecules, nectin-2 or nectin-3, and compared the number of each cell type at each stage of spermatogenesis with the corresponding value in normal mice. In both nectin-2^-/- and nectin-3^-/- mice, which are infertile despite the apparently normal morphology of the seminiferous epithelia, we measured a progressive loss in the later-step spermatids, with significantly lower numbers of step 11–16 spermatids in nectin-3^-/- mice and step 15–16 spermatids in nectin-2^-/- mice as compared with that in normal control mice. The present study demonstrated that a quantitative analysis of cellular compositions at different stages in seminiferous tubules was useful for evaluating abnormalities in spermatogenesis.     

Effect of vascular endothelial growth factor and testis tissue culture on spermatogenesis in bovine ectopic testis tissue xenografts

Bovine ectopic testis tissue grafting is a technique that can be used to study bovine spermatogenesis and for the production of germ cells for a variety of applications. Approximately 10% of seminiferous tubule cross sections in testis grafts contain spermatids, providing a unique tool to investigate what regulates germ cell differentiation. We hypothesized that manipulation of testis tissue grafts would increase the percentage of seminiferous tubule cross sections undergoing complete germ cell differentiation. To test this hypothesis, bovine testis tissue was treated with vascular endothelial growth factor (VEGF) at the time of grafting or explant cultured for 1 wk prior to grafting. For the VEGF experiment, 8-wk donor tissue and graft sites were treated with 1 microg of VEGF in order to increase angiogenesis at the graft site. For the testis tissue culture experiment, 4-wk-old donor testis was cultured for 1 wk prior to grafting to stimulate spermatogonial stem cell proliferation. Testis tissue grafts were removed from the mice 24 wk after grafting. VEGF treatment increased graft weight and the percentage of seminiferous tubule cross sections with elongating spermatids at the time of graft removal. Cultured testis tissue grafts were smaller and had fewer seminiferous tubules per graft. However, there was no difference in the percentage of seminiferous tubule cross sections that contained any germ cell type between groups. These data indicate for the first time that bovine testis tissue can be manipulated to better support germ cell differentiation in grafted tissue.     

Slow Freezing,but Not Vitrification Supports Complete Spermatogenesis in Cryopreserved,Neonatal Sheep Testicular Xenografts

The ability to spur growth of early stage gametic cells recovered from neonates could lead to significant advances in rescuing the genomes of rare genotypes or endangered species that die unexpectedly. The purpose of this study was to determine, for the first time, the ability of two substantially different cryopreservation approaches, slow freezing versus vitrification, to preserve testicular tissue of the neonatal sheep and subsequently allow initiation of spermatogenesis post-xenografting. Testis tissue from four lambs (3-5 wk old) was processed and then untreated or subjected to slow freezing or vitrification. Tissue pieces (fresh, n = 214; slow freezing, then thawing, n = 196; vitrification, then warming, n = 139) were placed subcutaneously under the dorsal skin of SCID mice and then grafts recovered and evaluated 17 wk later. Grafts from fresh and slow frozen tissue contained the most advanced stages of spermatogenesis, including normal tubule architecture with elongating spermatids in ~1% (fresh) and ~10% (slow frozen) of tubules. Fewer than 2% of seminiferous tubules advanced to the primary spermatocyte stage in xenografts derived from vitrified tissue. Results demonstrate that slow freezing of neonatal lamb testes was far superior to vitrification in preserving cellular integrity and function after xenografting, including allowing ~10% of tubules to retain the capacity to resume spermatogenesis and yield mature spermatozoa. Although a first for any ruminant species, findings also illustrate the importance of preemptive studies that examine cryo-sensitivity of testicular tissue before attempting this type of male fertility preservation on a large scale.     

Expression and localization of prolyl oligopeptidase in mouse testis and its possible involvement in sperm motility

Prolyl oligopeptidase (POP) expression in mouse testis during sexual maturation was examined. Northern blot analysis showed that POP mRNA expression was highest at 2 weeks of age, and gradually reduced thereafter. However, enzyme activity was almost constant during the examined period. In situ hybridization study revealed a change in the expression site of POP mRNA in testis during sexual maturation. Positive signals were detected in all types of cells in the seminiferous tubules before maturation, and were restricted to spermatids at the spermatogenesis cycle stages I-VIII in adult mice. POP was detected in the insoluble fraction of sperm by Western blot analysis. Immunohistochemical analyses showed that POP is localized in the spermatids at steps 12-16 of spermiogenesis and in the midpiece of the sperm fragellum. It was also found that specific POP inhibitors, poststatin and benzyloxycarbonyl-proline-prolinal, suppressed sperm motility. These results suggest that POP may be involved in meiosis of spermatocytes, differentiation of spermatids, and sperm motility in the mouse.     

Generation of normal progeny by intracytoplasmic sperm injection following grafting of testicular tissue from cloned mice that died postnatally

Animal cloning by nuclear transfer has been successful in several species and was expected to become an alternative reproductive technique. Among the problems associated with this cloning technique, however, are its low success rate and high mortality of cloned animals even if they develop to term. Nuclear transfer has thus come to be considered too difficult to apply as a reproductive technique. The transplantation of male germ cells or pieces of testicular tissue has enabled the induction of spermatogenesis from fetal or postnatal male mice. In the present study, we examined whether functional male gametes could be obtained by the transplantation of pieces of testicular tissue from cloned mice that died immediately after birth with typical aberrant phenotypes, such as large offspring syndrome. Donor testicular tissues were retrieved from cloned mice that died postnatally and were transplanted into the testes of recipient nude mice. Two to three months after transplantation, the grafted donor testicular tissue had grown in the host testis, and histological analysis showed that spermatogenesis occurred within the graft. Intracytoplasmic sperm injection demonstrated that the testicular sperm generated in the grafted donor tissue were able to support full-term development of progeny. These results clearly showed that functional spermatogenesis could be induced by transplanting testicular tissue from cloned mice that died postnatally into recipient mice. The strategy presented here will be applicable to cloned animals of other species, because the xenografting of testicular tissue into mice has been demonstrated previously to be possible.     

Effects of different storage protocols on cat testis tissue potential for xenografting and recovery of spermatogenesis

The loss of genetic diversity due to premature death of valuable individuals is a significant problem in animal conservation programs, including endangered felids. Testis tissue xenografting has emerged as a system to obtain spermatozoa from dead immature animals, however protocols to store this tissue before xenografting are still lacking. This study focused on testis tissue cryopreservation and storage from the domestic cat (Felis catus) classified as “pre-pubertal” and “pubertal” according to spermatogenesis development. Grafts from testis tissue cryopreserved with DMSO 1.4M, recovered after 10 weeks xenografting, presented seminiferous tubules with no germ cells. On the contrary, testis tissue from pre-pubertal animals preserved in ice-cold medium for 2 to 5 days presented no loss of viability or spermatogenic potential, while the number of grafts of pubertal cat testis tissue with germ cells after 10 weeks of xenografting decreased with increasing storage time. Nevertheless, even grafts from pre-pubertal cat testis tissue presented lower anti-DDX4 and anti-BOULE staining (proteins necessary for the meiosis completion), when compared with adult cat testis. Finally, a strong correlation found between testis weight and xenograft outcome may help choose good candidates for xenografting.     

Transplantation of germ cells from rabbits and dogs into mouse testes.

Spermatogonial stem cells of a fertile mouse transplanted into the seminiferous tubules of an infertile mouse can develop spermatogenesis and transmit the donor haplotype to progeny of the recipient mouse. When testis cells from rats or hamsters were transplanted to the testes of immunodeficient mice, complete rat or hamster spermatogenesis occurred in the recipient mouse testes, albeit with lower efficiency for the hamster. The objective of the present study was to investigate the effect of increasing phylogenetic distance between donor and recipient animals on the outcome of spermatogonial transplantation. Testis cells were collected from donor rabbits and dogs and transplanted into testes of immunodeficient recipient mice in which endogenous spermatogenesis had been destroyed. In separate experiments, rabbit or dog testis cells were frozen and stored in liquid nitrogen or cultured for 1 mo before transplantation to mice. Recipient testes were analyzed, using donor-specific polyclonal antibodies, from 1 to >12 mo after transplantation for the presence of donor germ cells. In addition, the presence of canine cells in recipient testes was demonstrated by polymerase chain reaction using primers specific for canine alpha-satellite DNA. Donor germ cells were present in the testes of all but one recipient. Donor germ cells predominantly formed chains and networks of round cells connected by intercellular bridges, but later stages of donor-derived spermatogenesis were not observed. The pattern of colonization after transplantation of cultured cells did not resemble spermatogonial proliferation. These results indicate that fresh and cryopreserved germ cells can colonize the mouse testis but do not differentiate beyond the stage of spermatogonial expansion.     

Recipient preparation is critical for spermatogonial transplantation in the rat

Testis cell transplantation from mice or rats into recipient mouse seminiferous tubules results in donor cell-derived spermatogenesis in nearly all host testes. Normal spermatozoa are produced and, in the most successful mouse transplantations, the donor haplotype is transmitted to progeny of the recipient. However, few studies have been performed in other species. In this report, we demonstrate that rat and mouse testis cells will generate donor cell-derived spermatogenesis in recipient rat seminiferous tubules. Depletion of endogenous spermatogenesis before donor cell transplantation was more difficult in rat than reported for mouse recipients. A protocol employing treatment of neonatal rats with busulfan was most effective in preparing recipients and allowed more than 90% of testes to be colonized by donor cells. Transplantation of mouse testis cells into rat seminiferous tubules was most successful in recipients made cryptorchid and treated with busulfan. In the best experiments, about 55% of rat testes were colonized by mouse cells. Both rat and mouse donor cell-derived spermatogenesis were improved by treatment of rat recipients with leuprolide, a gonadotropin-releasing hormone agonist. The studies indicated that recipient preparation for spermatogonial stem cell transplantation was critical in the rat and differs from the mouse. However, modification of currently used techniques should allow male germ line stem cell transplantation in many species.     

Spermatogenesis in testis xenografts grafted from pre-pubertal Holstein bulls is re-established by stem cell or early spermatogonia

Xenografting of testis explants into recipient mice has resulted in successful restoration of spermatogenesis in several species. Most studies have utilized neonatal donor tissue, although a few have used prepubertal testes. In Holstein bulls, prepubertal development of the testis occurs between 16 and 32 weeks of age. The purpose of the present study was to determine the optimal age during prepubertal development of Holstein bulls for testis grafting. Explants of testis tissue from Holstein bulls between 12 and 32 weeks of age (2 bulls/age; 6 ages) were subcutaneously grafted into castrated or intact immunocompromised mice (n=8/age), then recovered after 75 and 173 days (n=4 mice/grafting period) and evaluated histologically for spermatogenic progression. Seminiferous tubules were assigned a score based on the most advanced type of germ cell present within the tubule and the average for all tubules scored (n=25) within an explant was calculated. Scores for all explants per mouse (n=6) were averaged to give a single spermatogenic progression score per mouse. No difference in spermatogenic progression of grafts between intact and castrated recipients was observed. Spermatocytes were observed in testis grafts from bulls of all ages 75 days post-grafting. At 173 days, the spermatogenic progression score for explants derived from 20 weeks bulls was greater than all ages except 12 weeks donors (p<0.05), with 8% of tubules containing spermatids. Donor material from bulls older than 20 weeks had lesser spermatogenic progression scores largely attributed to the greater number of atrophic tubules in grafts from older donors. Grafts from 28 and 32 weeks donors showed signs of degeneration by 75 days post-grafting, with 30 and 55% atrophic tubules, respectively, and lesser spermatogenic efficiency scores. By 173 days post-grafting, 72% of tubules in explants from 32 weeks donors were atrophic. The results of the present study suggest that the early stages of prepubertal development are optimal for testis grafting while advanced spermatogenesis in the donor tissue prior to grafting had a negative effect on graft development. Spermatogenesis within the grafts apparently needs to be re-established by spermatogonial stem cells or early spermatogonia.