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.     

睾丸组织块和精原干细胞异种移植的发展及现状

精原干细胞是精子发生的前提和基础,精原干细胞的存在为男性保存和恢复生育能力提供了可能.精原干细胞和睾丸组织移植技术已经被用来研究生精细胞的增殖与分化,这项技术对恢复无精子症或睾丸肿瘤患者的生育能力等有着重要的应用前景.综述了睾丸组织块和精原干细胞的移植技术的发展、现状及在医学领域的应用前景.     

Heterotopic transplantation of testes in newly hatched chickens and subsequent production of offspring via intramagnal insemination

Transplantation of testicular tissue onto the back of immunodeficient nude mice provides a tool to examine testicular development and preserve fertility in mammals. There is no immunodeficient model in birds, but we recently transplanted ovarian tissue between newly hatched chicks from two lines of chickens and produced donor-derived offspring, showing that experimental transplantation is possible in newly hatched chicks. In the present study testicular tissue from newly hatched Barred Plymouth Rock (BPR) chicks was transplanted under the skin of the back, under the skin of the abdomen, or in the abdomen of White Leghorn chicks that had been surgically castrated and immunocompromised. Recipient birds were killed at 10 mo of age. Transplanted tissue was observed in one of five hosts receiving tissue under the skin of the back, two of five hosts receiving tissue under the skin of the abdomen, and three of five chicks with grafts inside the abdominal cavity. In recipients with no regeneration of host testes, testicular transplants grew to the size of normal testes, and histologic analysis showed active spermatogenesis. Subsequent collection of sperm from two successful transplants and surgical insemination of the sperm into the magna of the oviducts of BPR hens resulted in the production of 24 donor-derived chicks. These results demonstrate that the combination of testicular tissue transplantation with intramagnal insemination can produce viable, normal chicks, which could provide a simple approach for the recuperation of live offspring in avian species.     

Characterization of spermatogonial stem cell maturation and differentiation in neonatal mice

Initiation of the first wave of spermatogenesis in the neonatal mouse testis is characterized by the differentiation of a transient population of germ cells called gonocytes found in the center of the seminiferous tubule. The fate of gonocytes depends upon these cells resuming mitosis and developing the capacity to migrate from the center of the seminiferous tubule to the basement membrane. This process begins approximately Day 3 postpartum in the mouse, and by Day 6 postpartum differentiated type A spermatogonia first appear. It is essential for continual spermatogenesis in adults that some gonocytes differentiate into spermatogonial stem cells, which give rise to all differentiating germ cells in the testis, during this neonatal period. The presence of spermatogonial stem cells in a population of cells can be assessed with the use of the spermatogonial stem cell transplantation technique. Using this assay, we found that germ cells from the testis of Day 0-3 mouse pups can colonize recipient testes but do not proliferate and establish donor-derived spermatogenesis. However, germ cells from testes of Day 4-5 postpartum mice colonize recipient testes and generate large areas of donor-derived spermatogenesis. Likewise, germ cells from Day 10, 12, and 28 postpartum animals and adult animals colonize and establish donor-derived spermatogenesis, but a dramatic reduction in the number of colonies and the extent of colonization occurs from germ cell donors Days 12-28 postpartum that continues in adult donors. These results suggest spermatogonial stem cells are not present or not capable of initiating donor-derived spermatogenesis until Days 3-4 postpartum. The analysis of germ cell development during this time frame of development and spermatogonial stem cell transplantation provides a unique system to investigate the establishment of the stem cell niche within the mouse testis.     

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.     

Cografting of hamster (Phodopus sungorus) and marmoset (Callithrix jacchus) testicular tissues into nude mice does not overcome blockade of early spermatogenic differentiation in primate grafts

The ectopic xenotransplantation of testicular tissues into nude mice is a tool to generate sperm from immature testes. Immunodeficient mice as recipients of xenografts offered an appropriate microenvironment for differentiation of testicular tissue from hamsters, goats, pigs, and macaques. One exception is the neotropical primate Callithrix jacchus. Spermatogenesis in testicular grafts from marmosets does not proceed beyond the spermatogonial stage. The most likely cause for the poor graft development of marmosets is a deletion of exon 10 in the luteinizing hormone-receptor (LHR) gene, which renders this species insensitive to LH but responsive to chorionic gonadotropin (CG). We investigated whether cografting of testicular tissue from Djungarian hamsters would overcome the blockade in marmoset graft development. We also tested if exogenous administration of human CG (hCG) to the recipient would stimulate development of the marmoset tissue. No difference in graft survival was noted between hamster and monkey tissue. Seminiferous lumina were present in marmoset and hamster grafts but were significantly larger in hamster grafts. In the hamster grafts, a high proportion of the tubules contained meiotic and postmeiotic germ cells. In contrast, the marmoset tubules were populated with gonocytes and premeiotic spermatogonia. These results indicate that neither normal serum androgen levels nor the high local testosterone levels were sufficient to initiate marmoset spermatogenesis, nor was administration of hCG successful in overcoming the developmental blockade in marmoset tissue. Our results indicate that the conditions needed for initiation of spermatogenesis in the marmoset are remarkably different from those present in most other mammals.     

Effects of sublethal dose of chlorfluazuron on testicular development and spermatogenesis in the common cutworm, Spodoptera litura

This paper describes the physiological mechanism of action of chlorfluazuron on testicular development and spermatogenesis when sublethal doses (LD₁₀: 1.00 ng/larva or LD₃₀: 3.75 ng/larva) are applied topically to the cuticle of newly moulted fifth instars of the common cutworm Spodoptera litura (F.) (Lepidoptera, Noctuidae). These doses disrupt the growth and development of testes by decreasing the volume and weight of testes and thickness of testes sheath as compared with that of the controls. Sublethal doses of chlorfluazuron also significantly reduce the protein content of the testis, but do not affect the carbohydrate and lipid contents in newly emerged treated males when measured in μg/mg of testis as compared with that of the controls. Additionally, such doses disrupt spermatogenesis by reducing the number and size of eupyrene and apyrene sperm bundles in the testis. Very few or no eupyrene sperm bundles are observed in vas deferens of pre‐ and newly moulted adults compared with controls. This result shows that the transfer of sperm bundles from testes to vas deferens is delayed in treated males. The effects of chlorfluazuron on testicular development and spermatogenesis is thought to be one of the factors responsible for the reduction in fecundity, fertility and hatchability caused by sublethal doses of chlorfluazuron.     

Testicular concentration of meiosis-activating sterol is associated with normal testicular descent

In the cryptorchid stallion, spermatogenesis is arrested at various levels before the completion of meiosis. In men, infantile cryptorchidism is also often associated with oligo- and azoospermia during adulthood. An impairment of spermatogenesis might be reflected in the level of locally produced factors. Formerly, a meiosis-activating sterol (T-MAS) has been isolated in murine and bovine testes. This sterol possesses the potential to trigger resumption of meiosis in cultured mouse oocytes, indicating that it might play an important role in the regulation of the meiotic process in the female gamete. The function of T-MAS in the testis is still unclear, but T-MAS may be associated with spermatogenesis. The objectives of this study were 1) to demonstrate the presence of T-MAS in equine testes, 2) to compare the contents of T-MAS in testicular tissue of stallions with complete and incomplete testicular descent and 3) to compare testicular T-MAS concentration before and after puberty Testes were collected from 16 normal and cryptorchid stallions submitted for castration and stored at -80 degrees C until the content of T-MAS was measured quantitatively with an HPLC-assay. In stallions > or = 2 years of age, the content of T-MAS was higher (P < 0.001) in normal testes (19.3+/-1.1 microg T-MAS/g, n=7) than in inguinally (4.1+/-2.4 microg T-MAS/g, n=4) or abdominally located testes (1.6+/-0.2 microg T-MAS/g, n=2). The contents of T-MAS in normal testes from stallions < 2 years of age (2.8+/-1.5 microg T-MAS/g, n=4) was lower than in normal testes from stallions > or =2 years of age (P < 0.001) From the present study it can be concluded that T-MAS is present in equine testicular tissue. Furthermore, the present study demonstrates that the production of T-MAS in testicular tissue is, concurrently with spermatogenesis, associated with normal testicular descent and is temporarily related to the onset of puberty.     

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.     

Impaired spermatogenesis and fertility in mice carrying a mutation in the Spink2 gene expressed predominantly in testes

Spermatogenesis is a complex process involving an intrinsic genetic program composed of germ cell-specific and -predominant genes. In this study, we investigated the mouse Spink2 (serine protease inhibitor Kazal-type 2) gene, which belongs to the SPINK family of proteins characterized by the presence of a Kazal-type serine protease inhibitor-pancreatic secretory trypsin inhibitor domain. We showed that recombinant mouse SPINK2 has trypsin-inhibitory activity. Distribution analyses revealed that Spink2 is transcribed strongly in the testis and weakly in the epididymis, but is not detected in other mouse tissues. Expression of Spink2 is specific to germ cells in the testis and is first evident at the pachytene spermatocyte stage. Immunoblot analyses demonstrated that SPINK2 protein is present in male germ cells at all developmental stages, including in testicular spermatogenic cells, testicular sperm, and mature sperm. To elucidate the functional role of SPINK2 in vivo, we generated mutant mice with diminished levels of SPINK2 using a gene trap mutagenesis approach. Mutant male mice exhibit significantly impaired fertility; further phenotypic analyses revealed that testicular integrity is disrupted, resulting in a reduction in sperm number. Moreover, we found that testes from mutant mice exhibit abnormal spermatogenesis and germ cell apoptosis accompanied by elevated serine protease activity. Our studies thus provide the first demonstration that SPINK2 is required for maintaining normal spermatogenesis and potentially regulates serine protease-mediated apoptosis in male germ cells.     

Germ cell transplantation in an azoospermic Klinefelter bull

Germ cell transplantation is a technique that transfers donor testicular cells into recipient testes. A population of germ cells can colonize the recipient testis, initiate spermatogenesis, and produce sperm capable of fertilization. In the present study, a nonmosaic Klinefelter bull was used as a germ cell recipient. The donor cell suspension was introduced into the rete testis using ultrasound-guided puncture. A pulsatile administration of GnRH was performed to stimulate spermatogenesis. The molecular approach to detect donor cells was done by a quantitative polymerase chain reaction with allele discrimination based on a genetic mutation between donor and recipient. Therefore, a known genetic mutation, associated with coat-color phenotype, was used to calculate the ratio of donor to recipient cells in the biopsy specimens and ejaculates for 10 mo. After slaughtering, meiotic preparations were performed. The injected germ cells did not undergo spermatogenesis. Six months after germ cell transplantation, the donor cells were rejected, which indicates that the donor cells could not incorporate in the testis. The hormone stimulation showed that the testosterone-producing Leydig cells were functionally intact. Despite subfertility therapy, neither the recipient nor the donor cells underwent spermatogenesis. Therefore, nonmosaic Klinefelter bulls are not suitable as germ cell recipients. Future germ cell recipients in cattle could be mosaic Klinefelters, interspecies hybrids, bulls with Sertoli cell-only syndrome, or bulls with disrupted germ cell migration caused by RNA interference.     

Comparison of cryosurvival and spermatogenesis efficiency of cryopreserved neonatal mouse testicular tissue between three vitrification protocols and controlled-rate freezing

Grafting of cryopreserved testicular tissue is a promising tool for fertility and testicular function preservation in endangered species, mutant animals, or cancer patients for future use. In this study, we aimed to improve the whole neonatal mouse testicular tissue cryopreservation protocols by comparing cryosurvival, spermatogenesis, and androgen production of grafted testicular tissue after cryopreservation with three different vitrification protocols and an automated computed controlled-rate freezing. Whole neonatal mouse testes were vitrified with various vitrification solutions (V1) 40% EG + 18% Ficoll + 0.35 M Sucrose, (V2) DAP 213 (2 M DMSO + 1 M Acetamid + 3 M PG), or (V3) 15% EG + 15% PG + 0.5 M Sucrose (total solute concentration V1:74.34%, V2:44.0%, and V3:49.22% wt/vol). Alternatively, neonatal testicular tissue was also frozen in 0.7 M DMSO +5% fetal bovine serum using controlled-rate freezing and compared to fresh grafted testicular tissue, sham grafted controls, and the vitrification protocol groups. Fresh (n = 4) and frozen-thawed (n = 4) testes tissues were grafted onto the flank of castrated male NCr Nude recipient mouse. The grafts were harvested after three months. Fresh or frozen-thawed grafts with controlled-rate freezing had the highest rate of tissue survival compared to other vitrified protocols after harvesting (p < 0.05). Both controlled-rate freezing and V1 protocol groups displayed the most advanced stages of spermatogenesis with elongated spermatids and spermatozoa in 17.6 ± 1.3% and 16.3 ± 1.9% of seminiferous tubules based on histopathological evaluation, respectively. Hosts of the testicular graft from controlled-rate freezing had higher levels of serum testosterone compared to all other vitrified-thawed graft groups (p < 0.05). This study shows that completed spermatogenesis from whole neonatal mouse testes were obtained when frozen with controlled-rate freezing and V1 vitrification solution and that testicular cryopreservation efficacy vary with the protocol and vitrification technique.     

Phospholipid hydroperoxide glutathione peroxidase: expression pattern during testicular development in mouse and evolutionary conservation in spermatozoa

Phospholipid hydroperoxide glutathione peroxidase (PHGPx) is a selenoprotein belonging to the family of glutathione peroxidases and has been implicated in antioxidative defense and spermatogenesis. PHGPx accounts for almost the entire selenium content of mammalian testis. In an attempt to verify the expression pattern of PHGPx, testes of mouse mutants with arrest at different stages of germ cell development and testes of mice at different ages were subjected to immunostaining with a monoclonal anti-PHGPx antibody. PHGPx was detected in Leydig cells of testes in all developmental stages. In the seminiferous tubuli, the PHGPx staining was first observed in testes of 21-day-old mice which is correlated with the appearance of the first spermatids. This result was confirmed when the testes of mutant mice with defined arrest of germ cell development were used. An immunostaining was observed in the seminiferous tubuli of olt/olt and qk/qk mice which show an arrest at spermatid differentiation. In Western blot analysis of proteins extracted from testes of mutant mice and from developing testes, two signals at 19- and 22-kDa were observed which confirm the existence of two PHGPx forms in testicular cells. In mouse spermatozoa, a subcellular localization of PHGPx and sperm mitochondria-associated cysteine-rich protein (SMCP) was demonstrated, indicating the localization of PHGPx in mitochondria of spermatozoa midpiece. For verifying the midpiece localization of PHGPx in other species, spermatozoa of Drosophila melanogaster, frog, fish, cock, mouse, rat, pig, bull, and human were used in immunostaining using anti-PHGPx antibody. A localization of PHGPx was found in the midpiece of spermatozoa in all species examined. In electronmicroscopical analysis, PHGPx signals were found in the mitochondria of midpiece. These results indicate a conserved crucial role of PHGPx during sperm function and male fertility.     

Development to blastocyst is impaired when intracytoplasmic sperm injection is performed with abnormal sperm from infertile mice harboring a mutation in the protein phosphatase 1cgamma gene

Idiopathic azoospermia, characterized by abnormal spermatogenesis, is commonly treated by performing intracytoplasmic sperm injection (ICSI) with sperm retrieved from testicular biopsies. However, no controlled experiments have been performed using an animal model to assess the efficacy or safety of the procedure. We have performed ICSI with testicular sperm obtained in a similar manner from testes of male mice homozygous for a null mutation in the protein phosphatase 1cgamma gene (PP1cgamma) or those of their wild-type littermates. PP1cgamma mutant testicular sperm are less resistant to sonication than are wild-type sperm and display a range of morphological abnormalities, similar to those reported for testicular sperm from idiopathic azoospermic men. PP1cgamma mutant sperm are unable to support development to the blastocyst stage, resulting in arrested development either before or just after compaction. A comparison of testicular and epididymal sperm from wild-type males revealed that the epididymal sperm caused embryos to fragment at an elevated rate. These results suggest that ICSI with any kind of testicular sperm carries an increased risk of embryo fragmentation and that abnormal testicular sperm has an added risk of embryo wastage at later preimplantation stages.     

SPATC1L maintains the integrity of the sperm head‐tail junction

Spermatogenesis is a tightly regulated process involving germ cell‐specific and germ cell‐predominant genes. Here we investigate a novel germ cell‐specific gene, Spatc1l (spermatogenesis and centriole associated 1 like). Expression analyses show that SPATC1L is expressed in mouse and human testes. We find that mouse SPATC1L localizes to the neck region in testicular sperm. Moreover, SPATC1L associates with the regulatory subunit of protein kinase A (PKA). Using CRISPR/Cas9‐mediated genome engineering, we generate mice lacking SPATC1L. Disruption of Spatc1l in mice leads to male sterility owing to separation of sperm heads from tails. The lack of SPATC1L is associated with a reduction in PKA activity in testicular sperm, and we identify capping protein muscle Z‐line beta as a candidate target of phosphorylation by PKA in testis. Taken together, our results implicate the SPATC1L‐PKA complex in maintaining the stability of the sperm head‐tail junction, thereby revealing a new molecular basis for sperm head‐tail integrity.     

Restoration of spermatogenesis and male fertility by transplantation of dispersed testicular cells in the chicken

Transplantation of male germ cells into sterilized recipients has been widely used in mammals for conventional breeding and transgenesis purposes. This study presents a workable approach for germ cell transplantation between male chickens. Testicular cells from adult and prepubertal donors were dispersed and transplanted by injection directly into the testes of recipient males sterilized by repeated gamma irradiation. We describe the repopulation of the recipient seminiferous epithelium up to the production of heterologous sperm in about 50% of transplanted males. In comparison to males transplanted with testicular cell preparations from adult donors, in which the first ejaculates with sperm were recovered about 5 wk after transfer, a substantial interval (about 10 wk) was necessary to obtain ejaculates after the transfer of testicular cells from prepubertal donors. However, in both cases, recipient males produced ejaculates capable of fertilizing ova and producing progeny expressing donor genes.     

Is there a clinical future for spermatogonial stem cells?

Like every other adult stem cell in the human body, spermatogonial stem cells (SSCs) have the capacity to either renew themselves or to start the differentiation process, namely, spermatogenesis. Due to the continuation of the stem cell population in the testis, several possible options for preservation and re-establishment of the reproductive potential exist. Currently, spermatogonial stem cell transplantation (SSCT) is considered the most promising tool for fertility restoration in young cancer patients. This technique involves the injection of a testicular cell suspension from a fertile donor into the testis of an infertile recipient. Although, SSCT could prove important for fertility preservation, this technique is not without any risk. Testicular cell suspensions from cancer patients may be contaminated with cancerous cells. It is obvious that reintroduction of malignant cells into an otherwise cured patient must be omitted. Decontamination strategies to solve this problem are discussed. Another alternative to preserve male fertility could be in-vitro culture of SSCs. This approach may be applied to generate spermatozoa in-vitro from cultured spermatogonial stem cells, which, in turn, could be used for intracytoplasmic sperm injection. Xenogeneic transplantation and xenografting are two other hypothetical methods to preserve fertility. However, because of the ethical and biological concerns inherent to these approaches, xenogeneic transplantation and xenografting should be limited to research. When SSCT or SSC culture becomes available for clinical use, efficient protocols for the cryopreservation of SSCs and testicular tissue will be of great benefit. The search for an optimal freezing protocol is discussed. Apart from fertility preservation, SSC studies are useful for other applications as well, such as transgenerational gene therapy and cell-based organ regeneration therapy.     

The effects of gossypol on spermatogenesis and development of the eyefluke, Philophthalmus gralli, and its chicken host

To determine the effects of gossypol, a male antifertility drug, on the eyefluke, P. gralli, this chemical was administered orally to chickens in long-term and short-term regimens. Gossypol acetic acid (GAA), fed to juvenile chickens from 1 to 35 days, caused a decreased weight gain when compared to controls on untreated feed. An FeSO4 supplement to the GAA-fed chickens provided partial protection from the toxic effects of GAA. Worms from GAA-fed chickens were significantly larger than controls, while those from chickens fed GAA + FeSO4 were intermediate in size. Sperm development in these worms was unaffected by GAA. In a second experiment, GAA was administered either in the feed of the hosts from days 35 to 70 or by capsule from days 63 to 77. Worms were exposed to [3H] thymidine, transplanted to the host's eyes, removed on a timed schedule, and processed for autoradiography to determine the rate of spermatogenesis in both GAA-feed and GAA-capsule groups. Early stages of spermatogenesis in both groups were unaffected by GAA and later stages developed at a slightly faster rate than reported for worms from chickens on untreated feed. Higher frequencies of testicular anomalies were observed in both groups including 3 testes, 1 testis, no testes, fused testes, degenerating testes, ovarian tissue in the testes, deformed sperm, and encapsulated sperm. Testes from chickens in both groups showed a significantly lower weight and no signs of spermatogenesis when compared to control chickens.     

The fertilising ability of spermatogenic cells derived from cultured mouse immature testicular tissue

There are many reports about the in vitro culture of spermatogenic cells, but no-one has succeeded in inducing the differentiation from spermatogonia to intact sperm. Also the study of in vitro testicular tissue culture has hardly advanced. We studied the culture of mouse immature testicular tissue derived from 5-day-old mice. We aimed to achieve the differentiation of spermatogenic cells in order to observe spermatogenesis in testicular tissue in vitro. We also froze mature testicular tissue and immature testicular tissue cultured for 2 weeks. Furthermore, spermatogenic cells differentiated by culturing were injected into metaphase II oocytes to determine whether these differentiated cells and frozen-thawed testicular tissue have fertilising and developmental ability. Under the culture conditions employed, secondary spermatocytes and a few round spermatids differentiated from spermatogonia were observed in the immature testicular tissue cultured for 2 weeks. When spermatogenic cells derived from cultured immature testicular tissue, cultured frozen immature testicular tissue and frozen-thawed mature testicular tissue were injected into ooplasm, the oocytes were fertilised and fertilised oocytes developed to the 8-cell stage. We suggest that spermatogenic cells derived from cultured immature testicular tissue have fertilising and developmental abilities equivalent to that of sperm. Also these abilities of spermatogenic cells obtained from cultured frozen immature testicular tissue and frozen-thawed mature testicular tissue were better than those of the same cells before freezing.