Susan Megee

Fertility and Germline Transmission of Donor Haplotype Following Germ Cell Transplantation in Immunocompetent Goats

Abstract Transplantation of spermatogonial stem cells into syngeneic or immunosuppressed recipient mice or rats can result in donor-derived spermatogenesis and fertility. Recently, this approach has been employed to introduce a transgene into the male germline. Germ-cell transplantation in species other than laboratory rodents, if successful, holds great promise as an alternative to the inefficient methods currently available to generate transgenic farm animals that can produce therapeutic proteins in their milk or provide organs for transplantation to humans. To explore whether germ-cell transplantation could result in donor-derived spermatogenesis and fertility in immunocompetent recipient goats, testis cells were transplanted from transgenic donor goats carrying a human alpha-1 antitrypsin expression construct to the testes of sexually immature wild-type recipient goats. After puberty, sperm carrying the donor-derived transgene were detected in the ejaculates of two out of five recipients. Mating of one recipient resulted in 15 offspring, one of which was transgenic for the donor-derived transgene. This is the first report of donor cell-derived sperm production and transmission of the donor haplotype to the next generation after germ-cell transplantation in a nonrodent species. Furthermore, these results indicate that successful germ-cell transplantation is feasible between immunocompetent, unrelated animals. In the future, transplantation of genetically modified germ cells may provide a more efficient alternative for production of transgenic domestic animals.

Preservation and transplantation of porcine testis tissue.

Grafting of immature mammalian testis tissue to mouse hosts can preserve the male germline. To make this approach applicable to a clinical or field situation, it is imperative that the testis tissue and/or spermatozoa harvested from grafted tissue are preserved successfully. The aim of the present study was to evaluate protocols for the preservation of testis tissue in a porcine model. Testis tissue was stored at 4 degrees C for short-term preservation or cryopreserved by slow-freezing, automated slow-freezing or vitrification for long-term storage. Preserved tissue was transplanted ectopically to mouse hosts and recovered xenografts were analysed histologically. In addition, spermatozoa were harvested from xenografts and cryopreserved. Total cell viability and germ cell viability remained high after tissue preservation. Complete spermatogenesis occurred in xenografts preserved by cooling up to 48 h, whereas spermatogenesis progressed to round spermatids in the xenografts that were frozen-thawed before grafting. Approximately 50% of spermatozoa harvested from xenografts remained viable after freezing and thawing. The in vivo developmental potential of cryopreserved tissue was reduced despite high post-thaw viability. Therefore, it is important to evaluate germ cell differentiation in vivo in addition to cell viability in vitro when optimising freezing protocols for testis tissue.

Building a Testis: Formation of Functional Testis Tissue after Transplantation of Isolated Porcine (Sus scrofa) Testis Cells

Abstract During mammalian development, morphogenesis of the testis requires the coordinated interplay of somatic cells to form seminiferous cords in which the primitive germ cells reside. These cords are the precursor of the functional male gonad and as such form the basis of male fertility. Cell migration during mammalian organogenesis and formation of complex tissues, such as the testis, are difficult to study in situ. Herein, we report extensive rearrangement of cells to regenerate complete functional testis tissue after implantation of isolated neonatal porcine testis cells under the skin of immunodeficient mice. Somatic cells and germ cells reorganized into structures that have remarkable morphologic and physiologic similarity to normal testis tissue, forming the endocrine and spermatogenic compartment of the testis. This unique in vivo system provides an accessible model for the study of testicular morphogenesis that could be especially useful in nonrodent species.

Adeno-associated virus (AAV)-mediated transduction of male germ line stem cells results in transgene transmission after germ cell transplantation

We explored whether exposure of mammalian germ line stem cells to adeno‐associated virus (AAV), a gene therapy vector, would lead to stable transduction and transgene transmission. Mouse germ cells harvested from experimentally induced cryptorchid donor testes were exposed in vitro to AAV vectors carrying a GFP transgene and transplanted to germ cell‐depleted syngeneic recipient testes, resulting in colonization of the recipient testes by transgenic donor cells. Mating of recipient males to wild‐type females yielded 10% transgenic offspring. To broaden the approach to nonrodent species, AAV‐transduced germ cells from goats were transplanted to recipient males in which endogenous germ cells had been depleted by fractionated testicular irradiation. Transgenic germ cells colonized recipient testes and produced transgenic sperm. When semen was used for in vitro fertilization (IVF), 10% of embryos were transgenic. Here, we report for the first time that AAV‐mediated transduction of mammalian germ cells leads to transmission of the transgene through the male germ line. Equally important, this is also the first report of transgenesis via germ cell transplantation in a nonrodent species, a promising approach to generate transgenic large animal models for biomedical research.—Honaramooz, A., Megee, S., Zeng, W., Destrempes, M.M., Overton, S.A., Luo, J., Galantino‐Homer, H., Modelski, M., Chen, F., Blash, S., Melican, D. T., Gavin, W. G., Ayres, S., Yang, F., Wang, P. J., Echelard, Y., Dobrinski, I. Adeno‐associated virus (AAV) ‐mediated transduction of male germ line stem cells results in transgene transmission after germ cell transplantation. FASEB J. 22, 374–382 (2008)

Asymmetric Distribution of UCH‐L1 in Spermatogonia Is Associated With Maintenance and Differentiation of Spermatogonial Stem Cells

Asymmetric division of germline stem cells in vertebrates was proposed a century ago; however, direct evidence for asymmetric division of mammalian spermatogonial stem cells (SSCs) has been scarce. Here, we report that ubiquitin carboxy‐terminal hydrolase 1 (UCH‐L1) is expressed in type A (As, Apr, and Aal) spermatogonia located at the basement membrane (BM) of seminiferous tubules at high and low levels, but not in differentiated germ cells distant from the BM. Asymmetric segregation of UCH‐L1 was associated with self‐renewal versus differentiation divisions of SSCs as defined by co‐localization of UCH‐L1high and PLZF, a known determinant of undifferentiated SSCs, versus co‐localization of UCH‐L1low/− with proteins expressed during SSC differentiation (DAZL, DDX4, c‐KIT). In vitro, gonocytes/spermatogonia frequently underwent asymmetric divisions characterized by unequal segregation of UCH‐L1 and PLZF. Importantly, we could also demonstrate asymmetric segregation of UCH‐L1 and PLZF in situ in seminiferous tubules. Expression level of UCH‐L1 in the immature testis where spermatogenesis was not complete was not affected by the location of germ cells relative to the BM, whereas UCH‐L1‐positive spermatogonia were exclusively located at the BM in the adult testis. Asymmetric division of SSCs appeared to be affected by interaction with supporting somatic cells and extracelluar matrix. These findings for the first time provide direct evidence for existence of asymmetric division during SSCs self‐renewal and differentiation in mammalian spermatogenesis. J. Cell. Physiol. 220: 460–468, 2009.

Xenografting of sheep testis tissue and isolated cells as a model for preservation of genetic material from endangered ungulates

Recovery of germ cells could be an option for preservation of the genetic pool of endangered animals. In immature males, xenografting of testis tissue provides the opportunity to recover sperm from these animals. In adult animals, xenografting has been less successful, but de novo morphogenesis of functional testis tissue from dissociated testis cells could be an alternative. To assess the potential use of these techniques in endangered bovid species, the domestic sheep was used as a model. Testes from 2-week-old lambs were grafted as tissue fragments or cell suspensions into nude mice. Grafts were recovered at 4, 8, 12 and 16 weeks post grafting. For isolated cells, two additional time points at 35 and 40 weeks after grafting were added. In addition, to analyse the possible effect of social stress among mice within a group on the development of the grafts, testis tissue grafts were recovered 13 weeks post grafting from mice housed individually and in groups. Complete spermatogenesis occurred in sheep testis xenografts at 12 weeks, similar to the situation in situ. Isolated sheep testis cells were able to reorganize and form functional testicular tissue de novo. Housing mice individually or in groups did not have any effect on the development of xenografts. Xenografting of testis tissue might be useful to obtain sperm from immature endangered ungulates that die prematurely. Testis tissue de novo morphogenesis from isolated cells could open interesting options to recover germ cells from mature males with impaired spermatogenesis.

Maturation of Testicular Tissue from Infant Monkeys after Xenografting into Mice

In juvenile monkeys, precocious puberty can be induced by administration of gonadotropins resulting in testicular somatic cell maturation and germ cell differentiation. It is, however, unknown whether testicular maturation can also be induced in younger monkeys. Here we used testis tissue xenografting to investigate whether infant monkey testis tissue will undergo somatic cell maturation and/or spermatogenesis in response to endogenous adult mouse gonadotropins or exogenous gonadotropins. Testicular tissue pieces from 3- and 6-month-old rhesus monkeys were grafted to immunodeficient, castrated mice. Recipient mice were either left untreated or treated with pregnant mare serum gonadotropin and/or human chorionic gonadotropin twice weekly and were killed 28 weeks after grafting. Testicular maturation in grafted tissue was assessed based on morphology and the most advanced germ cell type present and by immunohistochemistry for expression of proliferating cell nuclear antigen, Mullerian-inhibiting substance, and androgen receptor. Testis grafts, irrespective of donor age or treatment, contained fewer germ cells than donor tissue. Grafts from 6-month-old donors showed tubular expansion with increased seminiferous tubule diameter and lumen formation, whereas those harvested from gonadotropin-treated mice contained elongated spermatids. Grafts from 3-month-old donors recovered from gonadotropin-treated mice contained pachytene spermatocytes, whereas those recovered from untreated mice showed only slight tubular expansion. Immunohistochemistry revealed that exposure to exogenous gonadotropins supported Sertoli cell maturation, irrespective of donor age. These results indicate that sustained gonadotropin stimulation of immature (<12 months old) monkey testis supports Sertoli cell maturation, thereby terminating the unresponsive phase of the germinal epithelium and allowing complete spermatogenesis in testis tissue from infant rhesus monkeys.

Viral transduction of male germline stem cells results in transgene transmission after germ cell transplantation in pigs.

ABSTRACT Genetic modification of germline stem cells (GSCs) is an alternative approach to generate large transgenic animals where transgenic GSCs are transplanted into a recipient testis to generate donor-derived transgenic sperm. The objective of the present study was to explore the application of viral vectors in delivering an enhanced green fluorescent protein (EGFP) transgene into GSCs for production of transgenic gametes through germ cell transplantation. Both adeno-associated virus (AAV)- and lentivirus (LV)-based vectors were effective in transducing pig GSCs, resulting in the production of transgenic sperm in recipient boars. Twenty-one boars treated with busulfan to deplete endogenous GSCs and nine nontreated boars received germ cell transplantation at 12 wk of age. Semen was collected from recipient boars from 5 to 7 mo posttransplantation when boars became sexually mature, and semen collection continued for as long as 5 yr for some boars. The percentage of ejaculates that were positive for the EGFP transgene ranged from 0% to 54.8% for recipients of AAV vector-transduced germ cells (n = 17) and from 0% to 25% for recipients of LV vector-transduced germ cells (n = 5). When semen from two AAV recipients was used for in vitro fertilization (IVF), 9.09% and 64.3% of embryos were transgenic. Semen collected from two LV-vector recipients produced 7.7% and 26.3% transgenic IVF embryos. Here, we not only demonstrated AAV-mediated GSC transduction in another large animal model (pigs) but also showed, to our knowledge for the first time, that LV-mediated GSC transduction resulted in transgene transmission in pigs.

Decreased expression of p63, a regulator of epidermal stem cells, in the chronic laminitic equine hoof

REASONS FOR PERFORMING STUDY Abnormal epidermal stem cell regulation may contribute to the pathogenesis of equine chronic laminitis. OBJECTIVE To analyse the involvement of p63, a regulator of epidermal stem cell proliferative potential, in chronic laminitis. METHODS Epidermal tissues from skin, coronet and lamellae of the dorsal foot were harvested from 5 horses with chronic laminitis and 5 control horses. Tissues were analysed using histopathology, immunofluorescence microscopy and quantitative immunoblotting. RESULTS Hoof lamellae of laminitic horses had a lower frequency of p63 positive cells than control lamellae, particularly in the distal region. Quantitative immunoblotting confirmed reduced p63 expression in the laminitic distal lamellar region. The decreased p63 expression in laminitic epidermal lamellae was most apparent in the abaxial region adjacent to the hoof wall and highly associated with the formation of terminally differentiated, dysplastic and hyperkeratotic epidermis in this region, whereas lamellae from control horses maintained high p63 expression throughout the axial-abaxial axis. CONCLUSIONS Expression of p63 in equine skin resembles that reported in other species, including man and rodents, suggesting that p63 can serve as a marker for the proliferative potential of equine epidermal stem cells. p63 expression was significantly lower in the chronic laminitic hoof than in that of control horses, suggesting laminitic hoof epithelium has more limited proliferative potential with a shift towards differentiation. This may reflect reduced activity of epidermal stem cells in laminitic hoof. It is proposed that p63 contributes to the maintenance of hoof lamellae and that misregulation of p63 expression may lead to epidermal dysplasia during lamellar wedge formation. POTENTIAL RELEVANCE This study suggests that loss of epidermal stem cells contributes to the pathogenesis of equine laminitis. Autologous transplantation of p63-positive epidermal stem cells from unaffected regions may have regenerative therapeutic potential for laminitic horses.

Expression pattern of acetylated α-tubulin in porcine spermatogonia

Mammalian spermatogonial stem cells reside on the basement membrane of the seminiferous tubules. The mechanisms responsible for maintenance of spermatogonia at the basement membrane are unclear. Since acetylated α‐tubulin (Ac‐α‐Tu) is a component of long‐lived, stable microtubules and deacetylation of α‐tubulin enhances cell motility, we hypothesized that acetylation of α‐tubulin might be associated with positioning of spermatogonia at the basement membrane. The expression pattern of Ac‐α‐Tu at different stages of testis development was characterized by immunohistochemistry for Ac‐α‐Tu and spermatogonia‐specific proteins (PGP 9.5, DAZL). In immature pig testes, Ac‐α‐Tu was present exclusively in gonocytes at 1 week of age, and in a subset of spermatogonia at 10 weeks of age. At this age, spermatogonia are migrating toward the tubule periphery and Ac‐α‐Tu appeared polarized toward the basement membrane. In adult pig testes, Ac‐α‐Tu was detected in few single or paired spermatogonia at the basement membrane as well as in spermatids and spermatozoa. Only undifferentiated (DAZL−), proliferating (determined by BrdU incorporation) spermatogonia expressed high levels of Ac‐α‐Tu. Comparison with the expression pattern of β‐tubulin and tyrosinated α‐tubulin confirmed that only Ac‐α‐Tu is specific to germ cells. The unique pattern of Ac‐α‐Tu in undifferentiated germ cells during postnatal development suggests that posttranslational modifications of microtubules may play an important role in recruiting and anchoring spermatogonia at the basement membrane. Mol. Reprod. Dev. 77: 348–352, 2010.