Informing offspring of their conception by gamete donation

The Ethics Committee supports disclosure from parents to offspring about the use of donor gametes in their conception. The merits of further disclosure are discussed, and suggestions are made for policies for programs and sperm banks.

Biotechnology: surrogate broodstock produces salmonids

A worldwide decline in the number of wild salmonids calls for strategies to restore endangered populations. Here we show that germ cells can be transplanted between two different salmonid species, with the subsequent production of xenogenic, donor-derived offspring. This pioneering xenotransplantation technology may eventually find applications in facilitating the production of commercially valuable fish, as well as in species conservation.

Attempts to enhance production of porcine chimeras from embryonic germ cells and preimplantation embryos

Porcine embryonic germ (EG) cells share common features with porcine embryonic stem (ES) cells, including morphology, alkaline phosphatase activity and capacity for in vitro differentiation. Porcine EG cells are also capable of in vivo development by producing chimeras after blastocyst injection; however, the proportion of injected embryos that yield a chimera and the proportion of cells contributed by the cultured cells in each chimera are too low for practical use in genetic manipulation. Moreover, somatic, but not germ-line chimerism, has been reported from blastocyst injection using porcine ES or EG cells. To test whether efficiency of chimera production from blastocyst injection can be improved upon by changing the host embryo, we used as host embryos four groups according to developmental stage or length in culture: fresh 4-cell and 8-cell stage embryos subsequently cultured into blastocysts, fresh morulae, fresh blastocysts, and cultured blastocysts. Injection and embryo transfer of fresh and cultured blastocysts produced similar percentages of live piglets (17% versus 19%). Four piglets were judged to have a small degree of pigmentation chimerism, but microsatellite analysis failed to confirm chimerism in these or other piglets. Polymerase chain reaction analysis for detection of the porcine SRY gene in female piglets born from embryos injected with male EG cells identified six chimeras, at least one, but not more than two, from each treatment. Chimerism was confirmed in two putative pigmentation chimeras and in four piglets without overt signs of chimerism. The low percentage of injected embryos that yielded a chimera and the small contribution by EG cells to development of each confirmed chimera indicated that procedural changes in how EG cells were combined with host embryos were unsuccessful in increasing the likelihood that porcine EG cells will participate in embryonic development. Alternatively, our results suggested that improvements are needed in EG cell isolation and culture procedures to ensure in vitro maintenance of EG cell developmental capacity.

Generation of live fry from intraperitoneally transplanted primordial germ cells in rainbow trout

Germ cell transplantation has tremendous applications in transgenic animal production, assisted reproductive technology, and germline stem cell research. Here, we report for the first time the production of individuals from intraperitoneally transplanted primordial germ cells (PGCs) in animals. To trace the behavior of exogenous PGCs in recipients, PGCs visualized by a green fluorescent protein gene were used as donors. The PGCs prepared from the genital ridges of hatching embryos were transplanted into recipients at various developmental stages. The PGCs injected into the peritoneal cavities of hatching embryos had the ability to migrate toward, and to colonize, the genital ridges of recipient embryos. Furthermore, donor-derived PGCs proliferated and differentiated into mature eggs and sperm in the allogenic gonads; the resulting gametes produced live fry, showing the donor-derived phenotype, through fertilization. Combined with in vitro culture, genetic modification, and cryopreservation of PGCs, this technique provides new approaches for fish bioengineering.

Birth of germline chimeras by transfer of chicken embryonic germ (EG) cells into recipient embryos

This study reports for the first time the production of chicken germline chimeras by transfer of embryonic germ (EG) cells into recipient embryos of different strain. EG cells were established by the subculture of gonadal tissue cells retrieved from stage 28 White Leghorn (WL) embryos with I/I gene. During primary culture (P(0)), gonadal primordial germ cells (gPGCs) in the stromal cells began to form colonies after 7 days in culture with significant (P < 0.0001) increase in cell population. Colonized gPGCs were then subcultured with chicken embryonic fibroblast monolayer for EG cell preparation. Prepared EG cells or gPGCs at P(0) were transferred to stage 17 Korean Ogol chicken (KOC) embryos with i/i gene. The recipient chickens were raised for 6 months to sexual maturity, then a testcross analysis by artificial insemination was conducted for evaluating germline chimerism. As results, transfer of EG cells and gPGCs yielded total 17 germline chimeras; 2 out of 15 (13.3%) and 15 of 176 sexually matured chickens (8.5%), respectively. The efficiency of germline transmission in the chimeras was 1.5-14.6% in EG cells, while 1.3-27.6% in gPGCs. In conclusion, chicken germline chimeras could be produced by the transfer of EG cells, as well as gPGCs, which might enormously contribute to establishing various innovative technologies in the field of avian transgenic research for bioreactor production.

Homing efficiency and proliferation kinetics of male germ line stem cells following transplantation in mice

Stem cells in the male germ line (spermatogonial stem cells [SSCs]) are an important target for male fertility restoration and germ line gene modification. To establish a model system to study the biology and the applications of SSCs in mice, I used a sequential transplantation strategy to analyze the process by which SSCs colonize the stem cell niche after transplantation and to determine the efficiency of the process (homing efficiency). I further analyzed the proliferation kinetics of SSCs after colonization. The number of SSCs gradually decreased during the homing process, and only 12% of SSCs successfully colonized the niche on Day 7 after transplantation, but the number of SSCs increased by Day 14. Thus, homing efficiency of adult mouse SSCs is 12%. These results indicate that SSCs are rapidly lost upon transplantation and require approximately 1 wk to settle into their niches before initiating expansion. Using this SSC homing efficiency, I calculated that approximately 3000 SSCs exist in one normal adult testis, representing approximately 0.01% of total testis cells. Between 7 days and 1 mo after transplantation, SSCs proliferated 7.5-fold. However, they did not significantly proliferate thereafter until 2 mo, and only 8 SSCs supported one colony of donor-derived spermatogenesis from 1 to 2 mo. These results suggest that self-renewal and differentiation of SSCs are strictly regulated in coordination with the progress of an entire unit of regenerating spermatogenesis.

Restoration of fertility by germ cell transplantation requires effective recipient preparation

Spermatogonial transplantation provides access to the mammalian germline and has been used in experimental animal models to study stem cell/niche biology and germline development, to restore fertility, and to produce transgenic models. The potential to manipulate and/or transplant the germline has numerous practical applications that transcend species boundaries. To make the transplantation technology more broadly accessible, it is necessary to develop practical recipient preparation protocols. In the current study, mouse recipients for spermatogonial transplantation were prepared by treating pregnant females with the chemotherapeutic agent busulfan at different times during gestation. Donor germ cells were introduced into the testes of male progeny between 5 and 12 days postpartum. Analysis of recipient animals revealed that busulfan treatment of pregnant females on 12.5 days postcoitum was the most effective; male progeny transplanted with donor germ cells became fertile and passed the donor genotype to 25% of progeny. This approach was effective because 1) the cytoablative treatment reduced (but did not abolish) endogenous spermatogenesis, creating space for colonization by donor stem cells, 2) residual endogenous germ cells contributed to a healthy testicular environment that supported robust donor and recipient spermatogenesis, and 3) fetal busulfan-treated males could be transplanted as pups, which have been established as better recipients than adults. Laboratory mice provide a valuable experimental model for developing the technology that now can be applied and evaluated in other species.

Stem cell biology and therapeutic applications

PURPOSE OF REVIEW

Chronic diseases are common and deadly. Stem cell therapies have received intense interest for the repopulation of damaged or diseased tissues. A detailed understanding of the similarities and differences between embryonic stem cells and somatic stem cells will enhance our understanding of mechanisms of tissue repair or cellular augmentation. In addition, emerging technologies will be useful in the definition of the molecular regulation of the respective stem cell populations.

RECENT FINDINGS

A number of postnatal tissues have a population of somatic stem cells, which function in the maintenance and repair of tissues. Using molecular technologies these somatic stem cell populations have been shown to be pluripotent when placed in a permissive environment. Recent studies have utilized emerging technologies to define a molecular signature of embryonic stem cells and selected somatic stem cell populations. These strategies will be useful for the definition of a molecular program that promotes a stem cell phenotype (i.e. stemness phenotype).

SUMMARY

Recent studies suggest that embryonic and somatic stem cell populations hold promise as sources for tissue engineering. The use of cell biological and molecular technologies will enhance our understanding of embryonic and somatic stem cell populations and their molecular regulatory events that promote multipotentiation.

Human embryonic germ cell derivatives facilitate motor recovery of rats with diffuse motor neuron injury

We have investigated the potential of human pluripotent cells to restore function in rats paralyzed with a virus-induced motor neuronopathy. Cells derived from embryonic germ cells, termed embryoid body-derived (EBD) cells, introduced into the CSF were distributed extensively over the rostrocaudal length of the spinal cord and migrated into the spinal cord parenchyma in paralyzed, but not uninjured, animals. Some of the transplanted human cells expressed the neuroglial progenitor marker nestin, whereas others expressed immunohistochemical markers characteristic of astrocytes or mature neurons. Rare transplanted cells developed immunoreactivity to choline acetyltransferase (ChAT) and sent axons into the sciatic nerve as detected by retrograde labeling. Paralyzed animals transplanted with EBD cells partially recovered motor function 12 and 24 weeks after transplantation, whereas control animals remained paralyzed. Semi-quantitative analysis revealed that the efficiency of neuronal differentiation and extension of neurites could not account for the functional recovery. Rather, transplanted EBD cells protected host neurons from death and facilitated reafferentation of motor neuron cell bodies. In vitro, EBD cells secrete transforming growth factor-alpha (TGF-alpha) and brain-derived neurotrophic factor (BDNF). Neutralizing antibodies to TGF-alpha and to BDNF abrogated the ability of EBD-conditioned media to sustain motor neuron survival in culture, whereas neutralizing antibodies to BDNF eliminated the axonal outgrowth from spinal organotypics observed with direct coculture of EBD cells. We conclude that cells derived from human pluripotent stem cells have the capacity to restore neurologic function in animals with diffuse motor neuron disease via enhancement of host neuron survival and function.

Functional analysis of the p53 gene in apoptosis induced by heat stress or loss of stem cell factor signaling in mouse male germ cells

Apoptosis plays an important role in controlling germ cell numbers and restricting abnormal cell proliferation during spermatogenesis. The tumor suppressor protein, p53, is highly expressed in the testis, and is known to be involved in apoptosis, which suggests that it is one of the major causes of germ cell loss in the testis. Mice that are c-kit/SCF mutant (Sl/Sld) and cryptorchid show similar testicular phenotypes; they carry undifferentiated spermatogonia and Sertoli cells in their seminiferous tubules. To investigate the role of p53-dependent apoptosis in infertile testes, we transplanted p53-deficient spermatogonia that were labeled with enhanced green fluorescence protein into cryptorchid and Sl/Sld testes. In cryptorchid testes, transplanted p53-deficient spermatogonia differentiated into spermatocytes, but not into haploid spermatids. In contrast, no differentiated germ cells were observed in Sl/Sld mutant testes. These results indicate that the mechanism of germ cell loss in the c-kit/SCF mutant is not dependent on p53, whereas the apoptotic mechanism in the cryptorchid testis is quite different (i.e., although the early stage of differentiation of spermatogonia and the meiotic prophase is dependent on p53-mediated apoptosis, the later stage of spermatids is not).

Gonadal tissue cryopreservation and transplantation

Transplantation of ovarian and testicular tissue has been practised for over a century, mainly for experimental purposes. It is now being considered as a potential strategy for preserving fertility in young patients, including children, undergoing sterilizing treatment for cancer and other diseases. Ovarian tissue biopsies can be stored at liquid nitrogen temperatures indefinitely so that, after thawing, they can be returned as either ortho- or heterotopic grafts to the original patient. A different approach is needed for preserving male germ cells to restore fertile potential. Experimental studies have shown that spermatogonial stem cells injected into the rete testis/seminiferous tubules can re-initiate spermatogenesis after sterilizing treatment with alkylating agents; alternatively, in prepubertal cases, testicular biopsies that have been cryopreserved can be grafted subcutaneously to generate enough spermatozoa for intracytoplasmic sperm injection (ICSI). These strategies have been demonstrated in animal models and are now undergoing clinical testing.

From what should we protect future generations: germ-line therapy or genetic screening?

This paper discusses the issue of whether we have responsibilities to future generations with respect to genetic screening, including for purposes of selective abortion or discard. Future generations have been discussed at length among scholars. The concept of 'Guardian for Future Generations' is tackled and its main criticisms discussed. Whilst germ-line cures, it is argued, can only affect family trees, genetic screening and testing can have wider implications. If asking how this may affect future generations is a legitimate question and since we indeed make retrospective moral judgements, it would be wise to consider that future generations will make the same retrospective judgements on us. Moreover such technologies affect present embryos to which we indeed can be considered to have an obligation.

Transplantation of bovine germinal cells into mouse testes

To develop techniques for spermatogonial transplantation in bulls, it is essential to have an effective bioassay procedure to evaluate the transplantation efficiency of spermatogonial stem cell collection, purification, and culture techniques. The objective of the present study was to develop a mouse bioassay model to evaluate transplantation efficiency of fresh and cultured bovine germ cells. Bull calves of four ages (1, 2, 3, and 4 mo) were used as a source of donor testes cells. Two calves were used for each age point, one calf was experimentally made cryptorchidistic at 1 wk of age and the other left normal. A STO (mouse fibroblast) feeder cell line was used to culture bovine testes cells for 2 wk preceding transfer into recipient testes. Immunodeficient nude mice (nu/nu) in which endogenous spermatogenesis had been abolished by busulfan treatment served as recipient animals for transplantation. Donor bovine germ cells were microinjected into mouse seminiferous tubules. Mouse testes were analyzed 2 wk after transplant with the use of a bovine-specific antibody and whole-mount immunohistochemistry for the presence of bovine donor germ cells. Bovine testis cells were present in all recipient mouse testes analyzed. Fresh bovine testes cells were observed as colonies of round cells within mouse seminiferous tubules, indicating spermatogonial expansion and colonization; however, cultured bovine testes cells appeared as fibrous tissue and not as spermatogenic colonies. The average number of colonies resulting from donor cryptorchid testes was not different (P > 0.05) from noncryptorchid, 56+/-4 and 78+/-7, respectively. Fresh donor cells from calves older than 1 mo gave rise to a greater average number of colonies within recipient testes (P <0.05) (1 mo, 33+/-4; 2 mo, 70+/-8; 3 mo, 63+/-6; 4 mo, 87+/-9). Fresh bovine germ cells are capable of colonization in the busulfan-treated nude mouse testis, making it a suitable model for evaluation and development of spermatogonial transplant techniques in bulls.

Biological activity and enrichment of spermatogonial stem cells in vitamin A-deficient and hyperthermia-exposed testes from mice based on colonization following germ cell transplantation

Spermatogenesis is a complex process in which spermatogonial stem cells divide and subsequently differentiate into spermatozoa. This process requires spermatogonial stem cells to self-renew and provide a continual population of cells for differentiation. Studies on spermatogonial stem cells have been limited due to a lack of unique markers and an inability to detect the presence of these cells. The technique of germ cell transplantation provides a functional assay to identify spermatogonial stem cells in a cell population. We hypothesized that vitamin A-deficient (VAD) and hyperthermically treated testes would provide an enriched in vivo source of spermatogonial stem cells. The first model, hyperthermic treatment, depends on the sensitivity of maturing germ cells to high temperatures. Testes of adult mice were exposed to 43 degrees C for 15 min to eliminate the majority of differentiating germ cells. Treated donor testes were 50% of normal adult testis size and, when transplanted into recipients, resulted in a 5.3- and 19-fold (colonies and area, respectively) increase in colonization efficiency compared to controls. The second model, VAD animals, also lacked differentiating germ cells, and testes weights were 25% of control values. Colonization efficiency of germ cells from VAD testes resulted in a 2.5- and 6.2-fold (colonies and area, respectively) increase in colonization compared to controls. Hyperthermically treated mice represent an enriched source of spermatogonial stem cells. In contrast, the low extent of colonization with germ cells from VAD animals raises important questions regarding the competency of stem cells from this model.

Germ line stem cell competition in postnatal mouse testes

Niche is believed to affect stem cell behavior. In self-renewing systems for which functional transplantation assays are available, it has long been assumed that stem cells are fixed in the niche and that ablative treatments to remove endogenous stem cells are required for successful donor engraftment. Our results demonstrate that enriched populations of donor stem cells can produce long-lasting spermatogenic colonies in testes of immature and mature, nonablated mice, albeit at a lower frequency than in ablated mice. Colonization of nonablated recipient testes by neonate, pup, and cryptorchid adult donor spermatogonial stem cells demonstrates that competition for niche begins soon after birth and that endogenous stem cells influence the degree and pattern of donor cell colonization. Thus, a dynamic relationship between stem cell and niche exists in the testis, as has been suggested for hematopoiesis. Therefore, similar competitive properties of donor stem cells may be characteristic of all self-renewing systems.

Germ cell transplantation

Transplantation of germ cells leads to restoration of spermatogenesis from spermatogonial stem cells. The original description of germ cell transplantation in 1994 has led to new approaches to explore many basic aspects of spermatogonial physiology. Combining germ cell transplantation with culture and cryopreservation of spermatogonia opens new pathways for genetic engineering and conservation of livestock. In addition, autologous transfer of spermatogonia might be used as an approach for fertility preservation in oncological patients. This review summarises the history of germ cell transplantation and presents an outlook on future research on spermatogonial stem cells.

The allocation and differentiation of mouse primordial germ cells

Analysis of the lineage potency of epiblast cells of the early-streak stage mouse embryo reveals that the developmental fate of the cells is determined by their position in the germ layer. Epiblast cells that are fated to become neuroectoderm can give rise to primordial germ cells (PGCs) and other types of somatic cells when they were transplanted to the proximal region of the epiblast. On the contrary, proximal epiblast cells transplanted to the distal region of the embryo do not form PGCs. Therefore, the germ line in the mouse is unlikely to be derived from a predetermined progenitor population, but may be specified as a result of tissue interactions that take place in the proximal epiblast of the mouse gastrula. The initial phase of the establishment of the PGC population requires, in addition to BMP activity emanating from the extraembryonic ectoderm, normal Lim1 and Hnf3beta activity in the germ layers. The entire PGC population is derived from a finite number of progenitor cells and there is no further cellular recruitment to the germ line after gastrulation. The XX PGCs undergo X-inactivation at the onset of migration from the gut endoderm and re-activate the silenced X-chromosome when they enter the urogenital ridge. Germ cells that are localised ectopically in extragonadal sites do not re-activate the X-chromosome, even when nearly all germ cells in the fetal ovary have restored full activity of both X-chromosomes. XXSxr germ cells can re-activate the X-chromosome in the sex-reversed testis, suggesting that the regulation of X-chromosome activity is independent of ovarian morphogenesis.

Germ cell transplantation in pigs

Spermatogonial stem cells form the foundation of spermatogenesis, and their transplantation provides a unique opportunity to study spermatogenesis and may offer an alternative approach for animal transgenesis. This study was designed to extend the technique of spermatogonial transplantation to an economically important, large-animal model. Isolated immature pig testes were used to develop the intratesticular injection technique. Best results of intratubular germ cell transfer were obtained when a catheter was inserted into the rete testis under ultrasound guidance. The presence of infused dye or labeled cells was confirmed in the seminiferous tubules from 70 of 89 injected isolated testes. Infusion of 3-6 ml of dye solution or cell suspension could fill the rete and up to 50% of seminiferous tubules. The technique was subsequently applied in vivo. Donor cells included testis cells from 1- or 10-wk-old boars (from the recipients' contralateral testis or unrelated donors) and those from mice carrying a marker gene. Porcine testis cells were labeled with a fluorescent marker before transplantation. Testes were examined for the presence and localization of labeled donor cells immediately after transplantation or every week for 4 wk. Labeled porcine donor cells were found in numerous seminiferous tubules from 10 of 11 testes receiving pig cells. These results indicate that germ cell transplantation is feasible in immature pigs, and that porcine transplanted cells are retained in the recipient testis for at least 1 mo. This study represents a first step toward successful spermatogonial transplantation in a farm animal species.

Germ cell transplantation and the study of testicular function

Spermatogonial stem cell transplantation is a novel technique in which donor testicular cells are transferred into recipient testes. A population of germ cells from a transgenic or mutant donor is introduced into the seminiferous tubules of recipient testes by microinjection. Following injections, spermatogonial stem cells can colonize the recipient testis, initiate spermatogenesis and produce sperm capable of fertilization. This technique will allow scientists to: (1) investigate fundamental aspects of spermatogenesis; (2) provide a method to regenerate spermatogenesis in infertile individuals; and (3) genetically manipulate spermatogonial stem cells to develop transgenic animals.

Screening gamete donors for cystic fibrosis status

Gamete donors are currently not tested for cystic fibrosis, even though carriers have a very high risk of producing children with the disease. We recommend that gamete donors be routinely tested for cystic fibrosis. Similar arguments exist for antenatal screening for cystic fibrosis.

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.

Immunomagnetic purification of viable primordial germ cells of Japanese quail (Coturnix japonica)

Immunomagnetic cell sorting (MACS) with the monoclonal antibody (mAb) QCR1 was compared with the Ficoll density-gradient centrifugation system (FICS) in terms of the efficiency of enrichment of quail (Coturnix japonica) primordial germ cells (PGCs) from blood. The purified PGCs were tested for their ability to settle in the chick (Gallus domesticus) embryonic gonad. Blood containing 60-100 PGCs microliter-1 was taken from the dorsal aorta of quail embryos at Hamburger and Hamilton's stages 14-16. The amount and concentration of PGCs in the PGC-rich fraction purified by MACS were greater than in the fraction purified by FICS. Purified quail PGCs were transfused into chick embryos at stages 14-16 and immunohistochemically stained with mAb QCRI on day 8 of chick development. Transfused PGCs purified by either MACS or FICS were positively stained in the chick embryonic gonads.

Germ cells and germ cell transplantation

The germ cell lineage in mice is established about a week after fertilization, in a group of cells that have left the epiblast and moved to an extraembryonic site. They migrate back into the embryo, along the hind gut and into the gonads. Germ cells in male and female embryos then pursue different pathways: in the testis the germ cells cease proliferating and enter mitotic arrest, while germ cells in the ovary, like those in male embryos that remain outside the gonads, enter meiotic prophase. Studies on explanted germ cells suggest that all germ cells may enter meiosis at a certain stage of their development, unless prevented from doing so by some inhibitory influence of the testis. Germ cells during the migratory stage can be cultured, but do not enter meiosis unless embedded in somatic tissue. Addition of certain growth factors and cytokines to the culture medium allows germ cells to proliferate indefinitely in vitro: Like embryonic stem cells, these immortalized EG (embryonic germ) cells will colonize all cell lineages if introduced into a blastocyst. After birth, germ cells undergo gametogenesis; oogenesis in the female, spermatogenesis in the male. Brinster and his colleagues have shown that spermatogonial stem cells injected into a germ-cell depleted testis will repopulate the seminiferous tubules and undergo spermatogenesis, giving rise to functional spermatozoa. Stem cells from frozen testicular tissue are still capable of giving rise to spermatogenesis in a host testis. Rat testicular tissue can undergo spermatogenesis in a mouse testis, to form morphologically normal rat spermatozoa, even though the Sertoli cells that support them are of endogenous mouse origin. These findings are of fundamental importance for our understanding of spermatogenesis and the interactions between germ cells and Sertoli cells; but they also have significant practical implications, in relation to both agricultural practice and clinical treatment of infertility.

Male germ cell transplantation: present achievements and future prospects

Germ cells are unique, since their surviving descendants can undergo meiosis and differentiate into gametes, which transmit genetic material from one generation to another. We now know that male germ cells, whether they be primordial germ cells in gonadal ridges, gonocytes, or stem spermatogonia, are transplantable. The donor cells can be transferred by direct microinjection into the seminiferous tubules, rete testis or efferent ducts, depending on the recipient species. Following transplantation, the donor cells undergo spermatogenesis in the host's seminiferous tubules in rats and mice, and have even sired offspring in mice. Interspecific germ cell transfer is possible if the recipient's immune system is defective; nude or SCID mice can even produce rat spermatozoa. However, the major obstacle restricting widespread use of this new technology is its extremely low success rate. This article discusses some ideas for improving the success rate of the transfer technique, and considers several potential applications.

Development of tumors from bovine primordial germ cells transplanted to athymic mice

Intact genital ridges containing primordial germ cells (PGC) and isolated PGC from murine and bovine embryos were examined for in vivo growth and differentiation after transplantation under the kidney capsule of athymic mice. Genital ridges were collected from day 11.5 and 12.5 murine and day 34 and 37 bovine embryos. Murine genital ridges and isolated PGC collected at 11.5 days post-coitus (dpc) and isolated murine PGC collected at 12.5 dpc developed into tumors. Day 34 and 37 bovine genital ridges, but not isolated PGC developed into tumors. The bovine origin of the tumors was confirmed by an analysis of the bovine DNA sequences. Tumors from both species consisted primarily of mesoderm-derived cell types, including connective tissue, cartilage, smooth muscle, fibroblasts, osteoblasts and bone matrix. No detectable ectodermal derivatives were observed in tumors of either species. Undifferentiated stem cells were not detected in the tumors, suggesting that the tumors were benign teratomas. Results of this study demonstrate the pluripotency of bovine PGC by experimental induction of teratomas after xenotransplantation under the kidney capsule of athymic mice. Stimulation of PGC survival and proliferation in an ectopic graft could be useful toward the isolation of pluripotent embryo-derived stem cells.

Donor primordial germ cell-derived offspring from recipient germline chimaeric chickens: absence of long-term immune rejection and effects on sex ratios

1. Germline chimaeric chickens were produced by the transfer of primordial germ cells, and the generation of donor-derived offspring was examined for a maximum of 146 weeks. 2. The frequencies of donor-derived offspring from the chimaeras were 47% to 97%, and no apparent changes in frequency were observed with increasing age during the test period. 3. Differentiation of donor primordial germ cells into functional gametes appeared to be restricted to a degree at some developmental stage in the gonads of chimaeric chickens of the opposite sex.

Nanos and Pumilio have critical roles in the development and function of Drosophila germline stem cells

The zinc-finger protein Nanos and the RNA-binding protein Pumilio act together to repress the translation of maternal hunchback RNA in the posterior of the Drosophila embryo, thereby allowing abdomen formation. nanos RNA is localized to the posterior pole during oogenesis and the posteriorly synthesized Nanos protein is sequestered into the germ cells as they form in the embryo. This maternally provided Nanos protein is present in germ cells throughout embryogenesis. Here we show that maternally deposited Nanos protein is essential for germ cell migration. Lack of zygotic activity of nanos and pumilio has a dramatic effect on germline development of homozygous females. Given the coordinate function of nanos and pumilio in embryonic patterning, we analyzed the role of these genes in oogenesis. We find that both genes act in the germline. Although the nanos and pumilio ovarian phenotypes have similarities and both genes ultimately affect germline stem cell development, the focus of these phenotypes appears to be different. While pumilio mutant ovaries fail to maintain stem cells and all germline cells differentiate into egg chambers, the focus of nanos function seems to lie in the differentiation of the stem cell progeny, the cystoblast. Consistent with the model that nanos and pumilio have different phenotypic foci during oogenesis, we detect high levels of Pumilio protein in the germline stem cells and high levels of Nanos in the dividing cystoblasts. We therefore suggest that, in contrast to embryonic patterning, Nanos and Pumilio may interact with different partners in the germline.

Different fate of primordial germ cells and gonocytes following transplantation

We have previously demonstrated that both donor primordial germ cells (PGCs) and gonocytes are capable of establishing spermatogenesis in the lumen of the seminiferous tubules of an adult host following transplantation in rats. Here we show that the PGCs, either in crude suspensions or after purification, undergo spermatogenesis only in the intraluminal compartment of the host's seminiferous tubules, while 4-5 days postpartum gonocytes also interdigitate with the host's seminiferous epithelium. The donor seminiferous epithelium was always in synchrony with the cycles of the host's spermatogenesis. It seems that the pattern of spermatogenesis of donor germ cells following transplantation in terms of its spacial location and the connection with the host's seminiferous epithelium depends on their developmental stages at transfer.

Production of germline chimeric chickens by transfer of cultured primordial germ cells

Primordial germ cells (PGCs) from stage 27 (5.5-day-old) Korean native ogol chicken embryonic germinal ridges were cultured in vitro for 5 days. As in in vivo culture, these cultured PGCs were expected to have already passed beyond the migration stage. Approximately 200 of these PGCs were transferred into 2.5-day-old white leghorn embryonic blood stream, and then the recipient embryos were incubated until hatching. The rate of hatching was 58.8% in the manipulated eggs. Six out of 60 recipients were identified as germline chimeric chickens by their feather colour. The frequency of germline transmission of donor PGCs was 1.3-3.1% regardless of sex. The stage 27 PGCs will be very useful for collecting large numbers of PGCs, handling of exogenous DNA transfection during culture, and for the production of desired transgenic chickens.

The cause of the decreased number of primordial germ cells in albino Xenopus resides not in the micro-environment but in the presumptive PGC

The number of primordial germ cells (PGC) in albino tadpoles of Xenopus is significantly decreased as compared with that of the wild-type. Whether the decreased number of PGC is caused by the presumptive PGC (pPGC) themselves or the micro-environment surrounding those cells in the albino, or both was investigated in the present study. [3H]thymidine-labeled pPGC of wild-type and albino were implanted into unlabeled, host neurulae of wild-type or albino and wild-type, respectively. Labeled PGC in the genital ridges of experimental tadpoles were examined by autoradiography. There were no significant differences in the proportion of tadpoles with labeled PGC and in the average number of those PGC between the albino and wild-type tadpoles, into which wild-type pPGC had been implanted. The proportion in wild-type tadpoles with albino pPGC was much lower than that in wild-type tadpoles with wild-type pPGC. These results suggest that the pPGC of the albino and not the micro-environment are responsible for the decreased number of PGC.

Transfer of male or female primordial germ cells of quail into chick embryonic gonads

Blood from an individual quail embryo at stages 13-16, when primordial germ cells (PGCs) were in circulation, was taken from its marginal vein and transfused into the marginal vein of a chick embryo at stages 13-16. Both donor and recipient embryos were cultured in vitro until day 8 of development and their sex was determined by morphological and histological observations of the gonads. Sections of recipient gonads were stained immunohistochemically with QCR1 monoclonal antibody positive for quail PGCs but negative for chick PGCs. Donor and recipient embryos were sexed in 17 pairs which included all four sex combinations. Transferred PGCs, either female-derived ZW type or male-derived ZZ type, were observed in the gonads of both sexes of 15 recipient embryos. The population of donor PGCs ranged from 20 to over 2500. In all four sex combinations, there was a higher population in the left than the right gonad of the embryos.

Essential role of the posterior morphogen nanos for germline development in Drosophila

In many animal groups, factors required for germline formation are localized in germ plasm, a region of the egg cytoplasm. In Drosophila embryos, germ plasm is located in the posterior pole region and is inherited in pole cells, the germline progenitors. Transplantation experiments have demonstrated that germ plasm contains factors that can form germline, and germ plasm also directs abdomen formation. Genetic analysis has shown that a common mechanism directs the localization of the abdomen and germline-forming factors to the posterior pole. The critical factor for abdomen formation is the nanos (nos) protein (nanos). Here we show that nos is also essential for germline formation in Drosophila; pole cells lacking nanos activity fail to migrate into the gonads, and so do not become functional germ cells. In such pole cells, gene expression, which normally initiates within the gonad, begins prematurely during pole-cell migration. Premature activation of genes in germline precursors may mean that these cells fail to develop normally. A function for nos protein in Drosophila germline formation is compatible with observations of its association with germ plasm in other animals.

Sexual differentiation of chimeric chickens containing ZZ and ZW cells in the germline

The developmental fate of male and female cells in the ovary and testis was evaluated by injecting blastodermal cells from Stage X (Eyal-Gliadi and Kochav, 1976: Dev Biol 49:321-337) chicken embryos into recipients at the same stage of development to form same-sex and mixed-sex chimeras. The sex of the donor was determined by in situ hybridization of blastodermal cells to a probe derived from repetitive sequences in the W chromosome. The sex of the recipient was assigned after determination of the chromosomal composition of erythrocytes from chimeras at 10, 20, 40, and 100 days of age. If the sex chromosome complement of all of the erythrocytes was the same as that of blastodermal cells from the donor, the sex of the recipient was assumed to be the same as that of the donor. Conversely, if the sex-chromosome complement of a portion of the erythrocytes of the chimera differed from that of the donor blastodermal cells, the sex of the recipient was assumed to differ from that of the donor. Injection of male blastodermal cells into female recipients produced both male and female chimeras in equal proportions whereas injection of female cells into male recipients produced only by male chimeras. One phenotypically male chimera developed with a left ovotestis and a right testis although sexual differentiation was usually resolved into an unambiguous sexual phenotype during development when ZZ and ZW cells were present in a chimera. Donor cells contributed to the germline of 25-33% of same-sex chimeras whereas 67% of male chimeras produced by injecting male donor cells into female recipients incorporated donor cells into the germline. When ZW cells were incorporated into chimeric males, W-chromosome-specific, DNA sequences were occasionally present in DNA extracted from semen. To examine the potential of W-bearing spermatozoa to fertilize ova, males producing ZW-derived offspring and semen in which W-chromosome-specific DNA was detected by Southern analysis were mated to sex-linked albino hens. Since sex-linked albino female progeny were not obtained from this mating, it was concluded that the W-bearing sperm cells were unable to fertilize ova. The production of Z-derived, but not W-derived, offspring from ZW spermatogonia indicates that female primordial germ cells can become spermatogonia in the testes. In the testes, ZW spermatogonia enter meiosis I and produce functional ZZ spermatocytes. The ZZ spermatocytes complete the second meiotic division, continue to differentiate during spermiogenesis, and leave the seminiferous tubules as functional spermatozoa. By contrast, the WW spermatocytes do not appear to complete spermiogenesis and, therefore, spermatozoa bearing the W-chromosome are not produced. When cells from male embryos were incorporated into a female chimera, ZZ "oogonia" were included within the ovarian follicles and the chromosome complement of genetically male oogonia was processed normally during meiosis. Following ovulation, the male-derived ova were fertilized and produced normal offspring. This is the first reported evidence that genetically male avian germ cells can differentiate into functional ova and that genetically female germ cells can differentiate into functional sperm.

[Chronological changes in autoantigenicity of autologous testicular germ cells in C3H/He mice during the postnatal period]

Our recent studies demonstrated that experimental autoimmune orchitis (EAO) model was produced in C3H/He mice with high incidence by two subcutaneous injections of viable syngeneic testicular germ cells (TC) without the use of any adjuvants or immunopotentiators. In this study the developmental patterns of autoantigenicity of TC during postnatal period were investigated by examining the orchitogenic activity of TC, the lymphostimulatory activities of TC (including the TC-induced in vitro lymphocyte proliferative response and the cytokine release from sensitized spleen cells (SPC) in response to TC) and the immunohistochemical localization of target autoantigens in the testes of mice at various weeks of age. Delayed-type hypersensitivity-inducing capacity and anti-TC antibody-eliciting capacity were initially observed in mice that were immunized with TC of 4-week old (w.o.) mice. The TC from 6-w.o. mice had the capability of inducing EAO (orchitogenicity) for the first time. A significant stimulation of in vitro lymphocyte proliferative response, as well as of interleukin (IL) 5 and IL-6 production by sensitized SPC were detectable when TC of mice 3-w.o. or more than were employed as stimulant. IL-2 and interferon gamma production were detected with TC of 4-w.o. mice. Immunohistochemical staining reaction with anti-TC antisera was primarily localized at the acrosomal portion of spermatids and spermatozoa in the seminiferous tubules, being already detected in spermatids of as early as 3-w.o. mice. Thus, from these data it is suggested that the appearance of the lymphostimulatory activities of TC consistently precedes that of the orchitogenic activity and that relatively mature germ cells such as spermatids and spermatozoa developing in the testes during the postnatal weeks may be responsible for the induction of disease and relevant immune responses in our EAO system.

Production of germline chimeric chickens, with high transmission rate of donor-derived gametes, produced by transfer of primordial germ cells

Germline chimeric chickens were produced by transfer of primordial germ cells from White Leghorn to Barred Plymouth Rock, and vice versa. Blood was collected from stage 13-15 embryos and primordial germ cells were concentrated by Ficoll density gradient centrifugation. Approximately 200 primordial germ cells were injected into the bloodstream through the dorsal aorta of stage 14-15 recipient embryos from which blood had been drawn via the dorsal aorta prior to the injection. Intact embryos were also prepared as recipients for White Leghorns only. The manipulated embryos were cultured in recipient eggshells until hatching. Germline chimerism of the chickens reaching maturity was examined by mating them with Barred Plymouth Rocks and donor-derived offspring were identified based on their feather color. The efficiency of production of germline chimeras was 95% (19/20). When primordial germ cells were transferred from White Leghorn to Barred Plymouth Rock, the average frequency of donor-derived offspring was 81% for three male chimeras (96% for one female chimera), and it was approximately 3.5 times higher for transfer in the opposite direction (23% for 6 male chimeras). Removing blood from recipient embryos prior to primordial germ cell injection enhanced the frequency of donor-derived offspring by 10% in resulting male chimeras. Male chimeras produced donor-derived offspring more frequently (approximately 3.8 times) than female chimeras. Increases, decreases, or no changes were observed in the frequency of donor-derived offspring from the germline chimeras with increasing age.(ABSTRACT TRUNCATED AT 250 WORDS)

Germ-cell migration. Finding the way to the gonad in Drosophila

Transplantation experiments show that the timing of germ-cell migration in Drosophila embryos is determined by the surrounding somatic tissue.

Sex determination in the germ line of Drosophila melanogaster: activation of the gene Sex-lethal

The germ line exhibits sexual dimorphism as do the somatic tissues. Cells with the 2X;2A chromosome constitution will follow the oogenic pathway and X;2A cells will develop into sperm. In both somatic and germ-line tissues, the sexual pathway chosen by the cells depends on the gene Sex-lethal (Sxl), whose function is continuously needed for female development. In the soma, the sex of the cells is autonomously determined by the X:A signal while, in the germ line, the sex is determined by cell autonomous (the X:A signal) and somatic inductive signals. Three X-linked genes have been identified, scute (sc), sisterless-a (sis-a) and runt (run), that determine the initial functional state of Sxl in the soma. Using pole cell transplantation, we have tested whether these genes are also needed to activate Sxl in the germ line. We found that germ cells simultaneously heterozygous for sc, sis-a, run and a deficiency for Sxl transplanted into wild-type female hosts develop into functional oocytes. We conclude that the genes sc, sis-a and run needed to activate Sxl in the soma seem not to be required to activate this gene in the germ line; therefore, the X:A signal would be made up by different genes in somatic and germ-line tissues. The Sxlf7M1/Sxlfc females do not have developed ovaries. We have shown that germ cells of this genotype transplanted into wild-type female hosts produce functional oocytes. We conclude that the somatic component of the gonads in Sxlf7M1/Sxlfc females is affected, and consequently germ cells do not develop.(ABSTRACT TRUNCATED AT 250 WORDS)

A method to obtain avian germ-line chimaeras using isolated primordial germ cells

Primordial germ cells (PGCs), collected from the blood of 2-day-old chick embryos, were concentrated by Ficoll density centrifugation. The blood contained 0.048% PGCs and the concentrated fraction contained 3.9% PGCs in blood cells. The PGCs were picked up with a fine glass pipette, and one hundred were then injected into the terminal sinuses of 2-day-old Japanese quail embryos (24 somites); bubbles were then inserted to prevent haemorrhage. The embryos were further incubated at 38 degrees C for 24 h, and then fixed. Serial sections were stained with the periodic acid-Schiff reagent (PAS) to demonstrate chicken PGCs and with Feulgen stain to identify quail cells. On the basis of the differences in staining properties, 63.6 +/- 5.3 chick PGCs were detected in the quail embryo in the area where the gonads develop. Furthermore, 39.3 +/- 4.5 chick PGCs were incorporated into the quail germinal epithelium within 24 h of the injection. A similar percentage of the host (quail) PGCs had also migrated to the germinal epithelium at the same stage of development. This technique for obtaining germ-line chimaeras will facilitate research on avian germ-line differentiation.

Establishment of an experimental model of autoimmune epididymo-orchitis induced by the transfer of a T-cell line in mice

A murine T-cell line derived from BALB/c mice (designated B.T.1) was established which was capable of adoptively transferring experimental autoimmune orchitis (EAO) in normal recipients. The protocol consisted of preparing lymphocytes obtained from the mice that were immunized with syngenetic testicular germ cells (TGC) and the subsequent repeated selection of the lymphocytes in vitro by stimulation with murine testicular antigens (mTA). Phenotypic analysis revealed that B.T.1 cells were CD4+ T-cells. Intra-peritoneal inoculation of as few as 1 x 10(5) B.T.1 cells, that were stimulated in vitro with mTA before the inoculation, was capable of transferring EAO to naive recipients. In the latter, both delayed type hypersensitivity (DTH) and humoral responses to TGC were augmented. The transferred lesion was characterized by infiltration of inflammatory cells into the epididymis and rete testis and widespread aspermatogenesis in the testis. The transfer of EAO was unsuccessful when the recipients received B.T.1 cells that were maintained in culture medium without stimulation with mTA. In these recipients, anti-TC DTH was not detected, although the specific humoral response was observed. In-vitro characterization of the biological activity of B.T.1 cells revealed that the line had no cytolytic activity against TGC but the culture supernatant had macrophage migration inhibitory activity involved in the DTH response. Therefore, the DTH responsiveness transferred by B.T.1 cells was found to correlate with their orchitis-inducing capacity.

Histochemical identification and behavior of quail primordial germ cells injected into chick embryos by the intravascular route

The behavior of quail primordial germ cells (PGC) after injection into chick embryos by the intravascular route was examined. The quail (donor) PGC, taken from the bloodstream of quail embryos (recipient) at stage 13-14, were injected into the vitelline vessels of chick embryos (recipient) at stage 15. In the recipient embryos, the PGC of the quail and the chick were histochemically distinguished by a double-staining technique involving a lectin, from Wistaria floribunda (WFA) and the PAS reaction. One day after injection, quail PGC appeared in the prospective gonadal region of recipient chick embryos, being localized among the recipient chick PGC. This result indicates that a staining technique specific for WFA lectin is useful for identification of quail PGC and that quail PGC can be transferred by a vascular route for the production of germline chimeras.

Germ-line gene therapy: a new stage of debate

Ethical debate on human germ-line gene therapy is in a new stage. After an era when only individual convictions could be examined, technology is on a threshold of real possibilities. Germ-line gene therapy can conceivably be carried out in either of two practical ways: 1) insertion of a gene into a pre-embryo, which is the subject of this paper, or 2) insertion of a gene into the germ cells of an individual.

Transgenic animal research and pre-implantation embryo diagnosis have implications for human embryonic germ-line experiments to correct single gene disorders. When would such experiments be feasible and ethically acceptable? If further animal research supports it, we argue for a moral obligation to learn if human germ-line experiments are feasible and safe to attempt. The obligation is grounded in several social-ethical principles that lead society and researchers to set gods for studies that promisc to relieve and to prevent human suffering and premature death. These principles also shape the practices and restrictions of biomedical research.

Assessment of functional gametes in chickens after transfer of primordial germ cells

The ability of primordial germ cells (PGCs) transferred from donor to recipient embryos to form functional gametes was assessed using feather colour as a phenotypic marker. Donor primordial germ cells were obtained in blood samples taken from Dwarf White Leghorn embryos, homozygous for the dominant allele at the locus for 'dominant white' plumage (I), which had been incubated for 52 h. Blood samples containing PGCs were transferred by intravascular injection to Barred Plymouth Rock embryos (ii) incubated for 53, 72 and 96 h. Of the embryos which hatched, 28 were male and 31 were female. All chicks were raised to sexual maturity and test mated with Barred Plymouth Rock fowl. All of the 3117 offspring exhibited the typical Barred Plymouth Rock phenotype; no Barred Plymouth Rock x Dwarf White Leghorn chicks were obtained. The results of this study suggest that the frequency of transmission of the donor line genotype after PGC transfer must be improved for this technique to be useful for the routine development of transgenic poultry.

Behavior of chick primordial germ cells injected into the blood stream of quail embryos

The distribution and behavior of chick primordial germ cells (PGC) injected into quail embryos were examined. PGC from chick embryos at stages 13-14 were injected into the blood stream of quail embryos at stages 15-20. After one day, the quail embryos were examined histologically. The chick PGC in the quail embryos could be readily identified by the histochemical PAS technique, whereas quail PGC were never stained by PAS. When the chick PGC were injected into the quail embryos during stages 15-18, they appeared mostly in the gonadal region of the recipient quail embryos. A few PGC were found at extragonadal sites. When the chick PGC were injected into the quail embryos at stages 19-20, in which the PGC of the recipient quail embryos had finished their migration into the gonads, most of the donor chick PGC were found at ectopic sites, in the head, trunk and limbs. These results indicate that most of the chick PGC, injected at the earlier stages 15-18, migrated to the gonadal anlagen of the recipient, while following later injection (from stage 19), most of the chick PGC migrated to ectopic sites.

Evidence for a change in expression of DNA ligase genes in the Pleurodeles waltlii germ line during gonadogenesis

The expression of DNA ligase genes was studied using the nuclear transplantation approach in the germ line of Pleurodeles waltlii (P. waltlii) just before and during gonadogenesis. Germ cell (GC) nuclei were isolated from larvae of P. waltlii and transplanted into unfertilized Ambystoma mexicanum eggs. DNA ligase activity in these eggs was then analyzed after sucrose gradient fractionation. The activity of DNA ligase I (heavy form, 7.5 S) of P. waltlii was present when the transplanted GC nuclei were isolated before the first histological appearance of gonadogenesis. At the beginning of genital ridge formation and thereafter, DNA ligase I activity was replaced by that of DNA ligase II (light form, 7 S). Expression of form I was found to be sensitive to inhibitors of translation and transcription, while that of form II was not. Therefore, the change in DNA ligase activity of the transferred nuclei of P. waltlii germ cells was assumed to be the consequence of a change in gene activity, namely, the repression of the gene encoding DNA ligase I. This change in the gene-regulated state could be linked to protein modifications of the chromatin. These results indicate that, at the beginning of gonadogenesis, germ cells receive information leading to a new state of differentiation.