Reconstitution of spermatogenesis from frozen spermatogonial stem cells.

Spermatozoa from a number of species can be cryopreserved and then subsequently used to fertilize eggs. However, this technique has several limitations. First, the freezing protocol varies for each species and must be determined empirically, and for some species appropriate methods have not yet been identified. Second, because these cells are fully differentiated, they will not undergo replication when thawed, and recombination of genetic information cannot occur. We now demonstrate, by using the recently developed spermatogonial transplantation technique, that male germline stem cells can be successfully cryopreserved. Donor testis cells isolated from prepubertal or adult mice and frozen from 4 to 156 days at -196 degrees C were able to generate spermatogenesis in recipient seminiferous tubules. Relatively standard preservation techniques were used, suggesting that male germ cells from other species can also be stored for long periods. Because transplanted testis stem cells will ultimately undergo replication and meiotic recombination during spermatogenesis, one might consider these preserved male germ lines as biologically immortal.

Transplantation of male germ line stem cells restores fertility in infertile mice.

Azoospermia or oligozoospermia due to disruption of spermatogenesis are common causes of human male infertility. We used the technique of spermatogonial transplantation in two infertile mouse strains, Steel (Sl) and dominant white spotting (W), to determine if stem cells from an infertile male were capable of generating spermatogenesis. Transplantation of germ cells from infertile Sl/Sld mutant male mice to infertile W/Wv or Wv/W54 mutant male mice restored fertility to the recipient mice. Thus, transplantation of spermatogonial stem cells from an infertile donor to a permissive testicular environment can restore fertility and result in progeny with the genetic makeup of the infertile donor male.

Transplantation of testis germinal cells into mouse seminiferous tubules.

In the adult male, germ cell differentiation takes place in the seminiferous tubules of the testis by a complex, highly organized and very efficient process. A population of diploid stem-cell spermatogonia that lie on the basement membrane of the tubule continuously undergoes self-renewal and produces progeny cells, which initiate the process of cellular differentiation to generate mature spermatozoa. Each testis contains many seminiferous tubules, which are connected at both ends to a collecting system called the rete testis. The mature spermatozoa pass from the tubules into the rete and are then carried through efferent ducts to the epididymis for final maturation before they are ready to fertilize an egg. In previous studies, we have demonstrated that donor testis cells collected from a fertile mouse are able to generate spermatogenesis when transplanted to the seminiferous tubules of an infertile male. The spermatozoa produced by the recipient from the donor-derived spermatogonial stem cells are able to fertilize eggs and produce progeny carrying the donor male haplotype. Furthermore, donor testis stem cells from a rat will generate normal rat spermatozoa following transplantation to a mouse testis. The spermatogonial transplantation technique is clearly valuable and applicable to many species, but it is difficult. Therefore, several procedures to introduce donor cells into the seminiferous tubules of a recipient have been developed using the mouse as a model, and they are described here in detail. The results indicate that microinjection of cell suspensions into the seminiferous tubules, efferent ducts or rete testis are equally effective in generating donor cell-derived spermatogenesis in recipients. Each approach is likely to be useful for different experimental purposes in a variety of species.

Retrovirus-mediated gene delivery into male germ line stem cells.

The male germ line stem cell is the only cell type in the adult that can contribute genes to the next generation and is characterized by postnatal proliferation. It has not been determined whether this cell population can be used to deliberately introduce genetic modification into the germ line to generate transgenic animals or whether human somatic cell gene therapy has the potential to accidentally introduce permanent genetic changes into a patient's germ line. Here we report that several techniques can be used to achieve both in vitro and in vivo gene transfer into mouse male germ line stem cells using a retroviral vector. Expression of a retrovirally delivered reporter lacZ transgene in male germ line stem cells and differentiated germ cells persisted in the testis for more than 6 months. At least one in 300 stem cells could be infected. The experiments demonstrate a system to introduce genes directly into the male germ line and also provide a method to address the potential of human somatic cell gene therapy DNA constructs to enter a patient's germ line.

Leuprolide, a gonadotropin-releasing hormone agonist, enhances colonization after spermatogonial transplantation into mouse testes.

Spermatogonial stem cells can be transplanted from a fertile donor mouse to the testis of an infertile recipient where they establish spermatogenesis and produce spermatozoa. In the present study we investigated whether treatment of recipient mice with the gonadotropin-releasing hormone (GnRH) agonist leuprolide acetate could alter the efficiency of colonization by donor spermatogonial stem cells in the recipient testis. Six recipient mice were treated with busulfan to destroy endogenous spermatogenesis followed by injection of leuprolide acetate to three of the mice. Testis cells from mice carrying the ZFlacZ transgene, which produces beta-galactosidase in spermatids, were used as donor cells for transplantation to allow for identification of donor spermatogenesis in the recipient testis by staining for enzyme activity. The extent of donor cell colonization was compared between leuprolide treated recipients and untreated control mice 3 months after transplantation. Efficiency of colonization by donor cells was markedly enhanced in recipient mice treated with the GnRH agonist leuprolide acetate, which makes the technique of spermatogonial transplantation applicable to a wide range of experimental situations. The present study also indicates that this technique can be used as a biological assay system to investigate factors controlling the establishment and progression of spermatogenesis.

Effect of the GnRH-agonist leuprolide on colonization of recipient testes by donor spermatogonial stem cells after transplantation in mice.

Gonadotropin-releasing hormone (GnRH)-agonist or antagonist treatment supports recovery of spermatogenesis after irradiation damage in the rat and appears to be beneficial to colonization of recipient testes after spermatogonial transplantation from fertile donors to the testes of infertile recipients in rats and mice. In the present study, we quantified the effect of treatment of recipient mice with the GnRH-agonist leuprolide acetate on the extent of colonization by donor spermatogonial stem cells in the recipient testis. Testis cells from mice carrying transgenes, which produce beta-galactosidase in spermatogenic cells, were used as donor cells for transplantation to allow for quantification of donor spermatogenesis in the recipient testis by staining for enzyme activity. Donor cell colonization 3 months after transplantation was compared between recipients receiving leuprolide in different treatment protocols and untreated control mice. Two injections of leuprolide 4 weeks apart prior to transplantation with as little as 3.8 mg/kg resulted in a pronounced improvement in the number of donor-derived spermatogenic colonies as well as in the in the area of recipient seminiferous tubules occupied by donor cell spermatogenesis. Improved colonization efficiency by treatment with GnRH-agonist can make the technique of spermatogonial transplantation applicable to situations when only low numbers of donor cells are available.

Culture of mouse spermatogonial stem cells.

Spermatogenesis occurs within the seminiferous tubules of mammals by a complex process that is highly organized, extremely efficient and very productive. At the foundation of this process is the spermatogonial stem cell that is capable of both self-renewal and production of progeny cells, which undergo differentiation over a period of weeks to months in order to generate mature spermatozoa. It had been thought that germ cells survive only a brief period in culture, generally less than a few weeks. However, an accurate assessment of the presence of spermatogonial stem cells in any cell population has only recently become possible with development of the spermatogonial transplantation technique. Using this technique, we have demonstrated that mouse spermatogonial stem cells can be maintained in culture for approximately 4 months and will generate spermatogenesis following transplantation to the seminiferous tubules of an appropriate recipient. Extensive areas of cultured donor cell-derived spermatogenesis are generated in the host, and production of mature spermatozoa occurs. Cultivation of the testis cells on STO feeders is beneficial to stem cell survival. These results provide the first step in establishing a system that will permit spermatogonial stem cells to be cultivated and their number increased in vitro to allow for genetic modification before transplantation to a recipient testis.

Development of germ cell transplants: morphometric and ultrastructural studies.

Mouse-to-mouse transplants were studied at 10 min, 9 h, 24 h, 1 week, 1 month, 2 months, and 3 months post-transplantation. Data from a previous light microscope study were confirmed and extended using morphometric and ultrastructural techniques. As soon as 10 min after introduction of the germ cells from one mouse into the tubule lumen of a recipient mouse they developed relationships with small Sertoli cell processes. The extent of this surface-to-surface relationship increased in animals sacrificed up to 1 week post-transplantation. Most transplanted germ cells retained the characteristics of the donor germ cells after they had been isolated and pelleted. Nearly all transplanted cells eventually underwent phagocytosis by the recipient Sertoli cells. The presence of small apparent clones of germ cells after 1 week of transplantation indicated that some germ cells may divide and survive for short periods within the epithelium. No discernible qualitative subcellular changes in the host Sertoli cell accompanying the development of transplant spermatogenesis were noted. Macrophages were present in the region of the boundary tissue between myoid cells and appeared to increase in number in the peritubular tissue of transplanted testes. Images suggest that they migrated into the tubule to gain entrance to the lumen and there take on the form of activated macrophages. Some macrophages phagocytose sperm at 2 months and 3 months post-transplantation. A testis weight increase previously demonstrate to occur at 24 h post-introduction of germ cells was found to be due to an increase in the volume of the tubular lumen. The increase of lumen size at 24 h was not related to the volume of the injected material. It is suggested that the presence of injected cells, likely germ cells, in the tubule lumen stimulated increased secretion by the Sertoli cell.

Germline transmission of donor haplotype following spermatogonial transplantation.

Spermatogenesis is a complex, highly organized, very efficient process that is based upon the capacity of stem cell spermatogonia simultaneously to undergo self-renewal and to provide progeny that differentiate into mature spermatozoa. We report here that testis-derived cells transplanted into the testis of an infertile mouse will colonize seminiferous tubules and initiate spermatogenesis in > 70% of recipients. Testis-derived cells from newborn mice were less effective in colonizing recipient testes than cells from 5- to 15- or 21- to 28-day-old mice. Increasing the number of Sertoli cells in the donor cell population did not increase the efficiency of colonization. Unmodified embryonic stem cells were not able to substitute for testis-derived cells in colonizing testes but instead formed tumors in syngeneic as well as nonsyngeneic hosts. Finally, with recipients that maintained endogenous spermatogenesis, testis cell transplantation yielded mice in which up to 80% of progeny were sired by donor-derived spermatozoa. The technique of spermatogonial cell transplantation should provide a means to generate germline modifications in a variety of species following development of spermatogonial culture techniques and should have additional applications in biology, medicine, and agriculture.

Germ cell transplantation from large domestic animals into mouse testes.

Donor-derived spermatogenesis after spermatogonial transplantation to recipient animals could serve as a novel approach to manipulate the male germ line in species where current methods of genetic modification are still inefficient. The objective of the present study was to investigate germ cell transplantation from boars, bulls, and stallions, which are economically important domestic animals, to mouse recipients. Donor testis cells (fresh, cryopreserved, or cultured for 1 month) were transplanted into testes of immunodeficient recipient mice in which endogenous spermatogenesis had been destroyed. Recipient testes were analyzed from 1 to > 12 months after transplantation for the presence of donor germ cells by donor-specific immunohistochemistry. Donor cells were present in most recipient testes with species-dependent differences in pattern and extent of colonization. Porcine donor germ cells formed chains and networks of round cells connected by intercellular bridges but later stages of donor-derived spermatogenesis were not observed. Transplanted bovine testis cells initially appeared similar but then developed predominantly into fibrous tissue within recipient seminiferous tubules. Few equine germ cells proliferated in mouse testes with no obvious difference between cells recovered from a scrotal or a cryptorchid donor testis. The pattern of colonization after transplantation of cultured cells did not resemble spermatogonial proliferation. These results indicate that fresh or cryopreserved germ cells from large animals can colonize the mouse testis but do not differentiate beyond the stage of spermatogonial expansion. Species-specific differences in the compatibility of large animal donors and mouse recipients were detected which cannot be predicted solely on the basis of phylogenetic distance between donor and recipient species.

beta1- and alpha6-integrin are surface markers on mouse spermatogonial stem cells.

Although spermatogenesis is essential for reproduction, little is known about spermatogonial stem cells. These cells provide the basis for spermatogenesis throughout adult life by undergoing self-renewal and by providing progeny that differentiate into spermatozoa. A major impediment to our understanding of the biology of these stem cells is the inability to distinguish them from spermatogonia that are committed to differentiation. We made use of the known association of stem cells with basement membranes and our spermatogonial transplantation assay system to identify specific molecular markers on the stem cell surface. Selection of mouse testis cells with anti-beta1- or anti-alpha6-integrin antibody, but not anti-c-kit antibody, produced cell populations with a significantly enhanced ability to colonize recipient testes and generate donor cell-derived spermatogenesis. We demonstrate spermatogonial stem cell-associated antigens by using an assay system based on biological function. Furthermore, the presence of surface integrins on spermatogonial stem cells suggests that these cells share elements of a common molecular machinery with stem cells in other tissues.

Pattern and kinetics of mouse donor spermatogonial stem cell colonization in recipient testes.

Recently a system was developed in which transplanted donor spermatogonial stem cells establish complete spermatogenesis in the testes of an infertile recipient. To obtain insight into stem cell activity and the behavior of donor germ cells, the pattern and kinetics of mouse spermatogonial colonization in recipient seminiferous tubules were analyzed during the 4 mo following transplantation. The colonization process can be divided into three continuous phases. First, during the initial week, transplanted cells were randomly distributed throughout the tubules, and a small number reached the basement membrane. Second, from 1 wk to 1 mo, donor cells on the basement membrane divided and formed a monolayer network. Third, beginning at about 1 mo and continuing throughout the observation period, cells in the center of the network differentiated extensively and established a colony of spermatogenesis, which expanded laterally by repeating phase two and then three. An average of 19 donor cell-derived colonies developed from 10(6) cells transplanted to the seminiferous tubules of a recipient testis; the number of colonized sites did not change between 1 and 4 mo. However, the length of the colonies increased from 0.73 to 5.78 mm between 1 and 4 mo. These experiments establish the feasibility of studying in a systematic and quantitative manner the pattern and kinetics of the colonization process. Using spermatogonial transplantation as a functional assay, it should be possible to assess the effects of various treatments on stem cells and on recipient seminiferous tubules to provide unique insight into the process of spermatogenesis.

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.

Functional analysis of spermatogonial stem cells in Steel and cryptorchid infertile mouse models.

Spermatogenesis is a complex and productive process that originates from stem cell spermatogonia and ultimately results in formation of mature spermatozoa. The stem cell undergoes self-renewal throughout life, but study of its biological characteristics has been difficult because a very small number (2 to 3 in 10(4) cells) exist in the testis and they can only be identified by function. Although the development of the spermatogonial transplantation technique has provided an assay system for stem cells, efficient methods to enrich stem cells have not been available. Here, we examined two infertile mouse models, Steel/Steel(Dickie)(Sl/Sl(d)) and experimental cryptorchid, as a source of testis cell populations enriched in stem cells. The Sl/Sl(d) testis showed little enrichment, which raises questions about how adult stem cell number is determined and about the currently accepted belief that adult stem cells are independent of Sl factor. The cells recovered from cryptorchid testes were enriched for stem cells 25-fold (colonies) or 50-fold (area) compared to wild-type testes. The cryptorchid condition does not affect stem cell activity, but eliminates almost all differentiated cells, and about 1 in 200 cells is a stem cell. Thus, cryptorchid testes provide an important approach for purification and characterization of spermatogonial stem cells.

Computer assisted image analysis to assess colonization of recipient seminiferous tubules by spermatogonial stem cells from transgenic donor mice.

Transplantation of spermatogonial stem cells from fertile, transgenic donor mice to the testes of infertile recipients provides a unique system to study the biology of spermatogonial stem cells. To facilitate the investigation of treatment effects on colonization efficiency an analysis system was needed to quantify colonization of recipient mouse seminiferous tubules by donor stem cell-derived spermatogenesis. In this study, a computer-assisted morphometry system was developed and validated to analyze large numbers of samples. Donor spermatogenesis in recipient testes is identified by blue staining of donor-derived spermatogenic cells expressing the E. coli lacZ structural gene. Images of seminiferous tubules from recipient testes collected three months after spermatogonial transplantation are captured, and stained seminiferous tubules containing donor-derived spermatogenesis are selected for measurement based on their color by color thresholding. Colonization is measured as number, area, and length of stained tubules. Interactive, operator-controlled color selection and sample preparation accounted for less than 10% variability for all collected parameters. Using this system, the relationship between number of transplanted cells and colonization efficiency was investigated. Transplantation of 10(4) cells per testis only rarely resulted in colonization, whereas after transplantation of 10(5) and 10(6) cells per testis the extent of donor-derived spermatogenesis was directly related to the number of transplanted donor cells. It appears that about 10% of transplanted spermatogonial stem cells result in colony formation in the recipient testis. The present study establishes a rapid, repeatable, semi-interactive morphometry system to investigate treatment effects on colonization efficiency after spermatogonial transplantation in the mouse.

Translation of globin messenger RNA by the mouse ovum.

It has been demonstrated that the Xenopus oocyte can translate rabbit haemoglobin messenger RNA (mRNA) following microinjection of the message into the cell. The Xenopus oocyte has since been shown to be capable of translating a variety of messenger RNAs from different species. This system has proved useful in un-erstanding the mechanism of message translation and has also provided information about the translation capability of the Xenopus oocyte. Several other cell types, including HeLa cells and fibroblasts, can also translate exogenous message injected into the cell. However, there have been no reports of injection of mRNA into oocytes or fertilised one-cell ova of mammalian species. Nevertheless, the latter system could be of considerable use in studying the processing of exogenous messages in a mammalian system undergoing development, as well as providing insight into the way the early embryo processes injected messages and the protein products of such messages. We report here the results of injecting message into the fertilised one-cell mouse ovum and show that both mouse and rabbit globin mRNA are translated in this system.

Xenogeneic spermatogenesis following transplantation of hamster germ cells to mouse testes.

It was recently demonstrated that rat spermatogenesis can occur in the seminiferous tubules of an immunodeficient recipient mouse after transplantation of testis cells from a donor rat. In the present study, hamster donor testis cells were transplanted to mice to determine whether xenogeneic spermatogenesis would result. The hamster diverged at least 16 million years ago from the mouse and produces spermatozoa that are larger than, and have a shape distinctly different from, those of the mouse. In four separate experiments with a total of 13 recipient mice, hamster spermatogenesis was identified in the testes of each mouse. Approximately 6% of the tubules examined demonstrated xenogeneic spermatogenesis. In addition, cryopreserved hamster testis cells generated spermatogenesis in recipients. However, abnormalities were noted in hamster spermatids and acrosomes in seminiferous tubules of recipient mice. Hamster spermatozoa were also found in the epididymis of recipient animals, but these spermatozoa generally lacked acrosomes, and heads and tails were separated. Thus, defects in spermiogenesis occur in hamster spermatogenesis in the mouse, which may reflect a limited ability of endogenous mouse Sertoli cells to support fully the larger and evolutionarily distant hamster germ cell. The generation of spermatogenesis from frozen hamster cells now adds this species to the mouse and rat, in which spermatogonial stem cells also can be cryopreserved. This finding has immediate application to valuable animals of many species, because the cells could be stored until suitable recipients are identified or culture techniques devised to expand the stem cell population.

Germ cell genotype controls cell cycle during spermatogenesis in the rat.

Spermatogenesis is one of the most productive self-renewing systems in the body: on the order of 10(7) spermatozoa are produced daily per gram of testis tissue. In each mammalian species, the time required for completion of the process is unique and unalterable. Because the process is supported by somatic Sertoli cells, it has generally been thought that cell-cell interaction between germ and Sertoli cells controls the duration of cell cycles and cellular organization. We have used the newly developed technique of spermatogonial transplantation to examine which cell type(s) determines the rate at which germ cells proceed through spermatogenesis. Rat germ cells were transplanted into a mouse testis, and the mouse was killed 12.9-13 days after administration of a single dose of [3H]thymidine. The most advanced rat cell type labeled was the pachytene spermatocyte at stages VI-VIII of the spermatogenic cycle. In animals given only rat cells, some endogenous spermatogenesis of the mouse recovered. The most advanced labeled mouse cell types in recipients killed 12.9-13 days after administration of a single dose of [3H]thymidine were meiotic cells or young spermatids, which is consistent with a spermatogenic cycle length comparable to the 8.6 days reported for the mouse. The same results were obtained if a mixture of rat and mouse cells were transplanted. There existed two separate timing regimens for germ cell development in the recipient mouse testis; one of rat and one of mouse duration. Rat germ cells that were supported by mouse Sertoli cells always differentiated with cell cycle timing characteristic of the rat and generated the spermatogenic structural pattern of the rat, demonstrating that the cell differentiation process of spermatogenesis is regulated by germ cells alone.

Remodeling of the postnatal mouse testis is accompanied by dramatic changes in stem cell number and niche accessibility.

Little is known about stem cell biology or the specialized environments or niches believed to control stem cell renewal and differentiation in self-renewing tissues of the body. Functional assays for stem cells are available only for hematopoiesis and spermatogenesis, and the microenvironment, or niche, for hematopoiesis is relatively inaccessible, making it difficult to analyze donor stem cell colonization events in recipients. In contrast, the recently developed spermatogonial stem cell assay system allows quantitation of individual colonization events, facilitating studies of stem cells and their associated microenvironment. By using this assay system, we found a 39-fold increase in male germ-line stem cells during development from birth to adult in the mouse. However, colony size or area of spermatogenesis generated by neonate and adult stem cells, 2-3 months after transplantation into adult tubules, was similar ( approximately 0.5 mm(2)). In contrast, the microenvironment in the immature pup testis was 9.4 times better than adult testis in allowing colonization events, and the area colonized per donor stem cell, whether from adult or pup, was about 4.0 times larger in recipient pups than adults. These factors facilitated the restoration of fertility by donor stem cells transplanted to infertile pups. Thus, our results demonstrate that stem cells and their niches undergo dramatic changes in the postnatal testis, and the microenvironment of the pup testis provides a more hospitable environment for transplantation of male germ-line stem cells.

Spermatogonial stem cell enrichment by multiparameter selection of mouse testis cells.

The spermatogonial stem cell initiates and maintains spermatogenesis in the testis. To perform this role, the stem cell must self replicate as well as produce daughter cells that can expand and differentiate to form spermatozoa. Despite the central importance of the spermatogonial stem cell to male reproduction, little is known about its morphological or biochemical characteristics. This results, in part, from the fact that spermatogonial stem cells are an extremely rare cell population in the testis, and techniques for their enrichment are just beginning to be established. In this investigation, we used a multiparameter selection strategy, combining the in vivo cryptorchid testis model with in vitro fluorescence-activated cell sorting analysis. Cryptorchid testis cells were fractionated by fluorescence-activated cell sorting analysis based on light-scattering properties and expression of the cell surface molecules alpha6-integrin, alphav-integrin, and the c-kit receptor. Two important observations emerged from these analyses. First, spermatogonial stem cells from the adult cryptorchid testis express little or no c-kit. Second, the most effective enrichment strategy, in this study, selected cells with low side scatter light-scattering properties, positive staining for alpha6-integrin, and negative or low alphav-integrin expression, and resulted in a 166-fold enrichment of spermatogonial stem cells. Identification of these characteristics will allow further purification of these valuable cells and facilitate the investigation of molecular mechanisms governing spermatogonial stem cell self renewal and hierarchical differentiation.