Sang-Eun Jung

Cryopreservation of putative pre-pubertal bovine spermatogonial stem cells by slow freezing

Development of techniques for the preservation of mammalian spermatogonial stem cells (SSCs) is a critical step in commercial application of SSC based technologies, including species preservation, amplification of agriculturally valuable germ lines, and human fertility preservations. The objective of this study was to develop an efficient cryopreservation protocol for preservation of bovine SSCs using a slow freezing technique. To maximize the efficiency of SSC cryopreservation, the effects of various methods (tissue vs. cell freezing) and cryoprotective agents (trehalose, sucrose, and polyethylene glycol [PEG]) were tested. Following thawing, cells were enriched for undifferentiated spermatogonia by differential plating and evaluated for recovery rate, proliferation capacity, and apoptosis. Additionally, putative stem cell activity was assessed using SSC xenotransplantation. The recovery rate, and proliferation capacity of undifferentiated spermatogonia were significantly greater for germ cells frozen using tissue freezing methods compared to cell freezing methods. Cryopreservation in the presence of 200 mM trehalose resulted in significantly greater recovery rate, proliferation capacity, and apoptosis of germ cells compared to control. Furthermore, cryopreservation using the tissue freezing method in the presence of 200 mM trehalose resulted in the production of colonies of donor-derived germ cells after xenotransplantation into recipient mouse testes, indicating putative stem cell function. Collectively, these data indicate that cryopreservation using tissue freezing methods in the presence of 200 mM trehalose is an efficient cryopreservation protocol for bovine SSCs.

Effect of Antioxidants and Apoptosis Inhibitors on Cryopreservation of Murine Germ Cells Enriched for Spermatogonial Stem Cells

Spermatogonial stem cells (SSCs) are germline stem cells that serve as the foundation of spermatogenesis to maintain fertility throughout a male’s lifetime. To treat male infertility using stem cell banking systems and transplantation, it is important to be able to preserve SSCs for long periods of time. Therefore, this study was conducted to develop an optimal cryopreservation protocol for SSCs using antioxidants and apoptosis inhibitors in freezing medium. No differences were observed compared to controls when SSCs were cryopreserved in the presence of apoptosis inhibitors by themselves. However, mouse germ cells cryopreserved in basal medium containing the antioxidant hypotaurine (14 mM) resulted in significantly greater proliferation potential and mitochondrial activity. Furthermore, treatment groups with combinations containing 200 mM trehalose and 14 mM hypotaurine showed higher proliferation rates compared to controls. In addition, several serum free conditions were evaluated for SSC cryopreservation. Treatment media containing 10% or 20% knockout serum replacement resulted in similar cryopreservation results compared to media containing FBS. SSC transplantation was also performed to confirm the functionality of SSCs frozen in 14 mM hypotaurine. Donor SSCs formed normal spermatogenic colonies and sperm in the recipient testis. These data indicate that inclusion of 14 mM hypotaurine in cryopreservation media is an effective way to efficiently cryopreserve germ cells enriched for SSCs and that knockout serum replacement can replace FBS in germ cell cryopreservation media.

In vitro spermatogenesis using bovine testis tissue culture techniques

Spermatogenesis is a complex process initiated by spermatogonial stem cells (SSCs) that have the ability to differentiate into mature spermatozoa or to self-renew to maintain the SSC population and long-term fertility. However, a technique for complete spermatogenesis in vitro using cell culture has not yet been developed. In the present study, we developed in vitro spermatogenesis techniques using bovine testis tissue culture. The effects of specific temperatures and different media on maintaining tubule and germ cell competency were investigated. We found that the optimal temperature and media were 37°C and mouse serum-free medium (mSFM), respectively. In addition, the efficacy of various hormones and growth factors on spermatogenesis in bovine testis tissues maintained in vitro was evaluated. We found that the addition of triiodothyronine (T3) and stem cell factor (SCF) induced spermatogenesis of bovine SSCs in vitro. Therefore, tissue fragments were cultured in the presence of T3 and SCF for three months to induce spermatogenesis in vitro. Overall, in vitro spermatogenesis was enhanced 2.4- to 2.7-fold. Our tissue culture technique may serve as a model system that leads to a more comprehensive understanding of the biology of SSCs as well as the factors that regulate male fertility. Furthermore, the results of this study will be integral for the continued refinement of techniques to manipulate bovine SSCs.

Effects of paracrine factors on CD24 expression and neural differentiation of male germline stem cells.

Spermatogonial stem cells (SSCs) are adult male germ cells that develop after birth. Throughout the lifetime of an organism, SSCs sustain spermatogenesis through self-renewal and produce daughter cells that differentiate into spermatozoa. Several studies have demonstrated that SSCs can acquire pluripotency under appropriate culture conditions, thus becoming multipotent germline stem cells (mGSCs) that express markers of pluripotency in culture and form teratomas following transplantation into immunodeficient mice. In the present study, we generated neural precursor cells expressing CD24, a neural precursor marker, from pluripotent stem cell lines and demonstrated that these cells effectively differentiated along a neural lineage in vitro. In addition, we found that paracrine factors promoted CD24 expression during the neural differentiation of mGSCs. Our results indicated that the expression of CD24, enhanced by a combination of retinoic acid (RA), noggin and fibroblast growth factor 8 (FGF8) under serum-free conditions promoted neural precursor differentiation. Using a simple cell sorting method, we were able to collect neural precursor cells with the potential to differentiate from mGSCs into mature neurons and astrocytes in vitro.

Platelet-derived growth factor receptor-alpha positive cardiac progenitor cells derived from multipotent germline stem cells are capable of cardiomyogenesis in vitro and in vivo

Cardiac cell therapy has the potential to revolutionize treatment of heart diseases, but its success hinders on the development of a stem cell therapy capable of efficiently producing functionally differentiated cardiomyocytes. A key to unlocking the therapeutic application of stem cells lies in understanding the molecular mechanisms that govern the differentiation process. Here we report that a population of platelet-derived growth factor receptor alpha (PDGFRA) cells derived from mouse multipotent germline stem cells (mGSCs) were capable of undergoing cardiomyogenesis in vitro. Cells derived in vitro from PDGFRA positive mGSCs express significantly higher levels of cardiac marker proteins compared to PDGFRA negative mGSCs. Using Pdgfra shRNAs to investigate the dependence of Pdgfra on cardiomyocyte differentiation, we observed that Pdgfra silencing inhibited cardiac differentiation. In a rat myocardial infarction (MI) model, transplantation of a PDGFRAenriched cell population into the rat heart readily underwent functional differentiation into cardiomyocytes and reduced areas of fibrosis associated with MI injury. Together, these results suggest that mGSCs may provide a unique source of cardiac stem/progenitor cells for future regenerative therapy of damaged heart tissue.

Production of transgenic spermatozoa by lentiviral transduction and transplantation of porcine spermatogonial stem cells

Spermatogonial stem cells (SSCs) are adult stem cells that transmit genetic information from the parent to the next generation (progeny) in males, and thus, SSCs have used in germline-modification for generating transgenic animals. In this study, we demonstrated the feasibility of transgenic sperm production by employing an effective busulfan treatment method to prepare recipient pigs for the transplantation of genetically modified donor porcine SSCs. We purified SSCs from pig testis cells by sequentially employing Laminin-coated dishes and culture dishes. The purified cells were transduced with lentivirus expressing enhanced green fluorescent protein (eGFP) at a multiplicity of infection (MOI) of 6 for 9 h. eGFP transduced pig SSCs were then transplanted into the seminiferous tubules of 12 to 16-week-old recipients born to busulfan-treated sows. We obtained six recipient pigs after transplantation and maintained them for more than 6 months. The collected viable spermatozoa from 2 out of 6 recipients were positive for eGFP gene expression in polymerase chain reaction. eGFP-expressing spermatozoa appeared morphologically normal under the microscope. When spermatozoa from these recipients were used for intra cytoplasmic sperm injection, eGFP expression could be detected in the embryos. Furthermore, eGFP colonies were derived from donor-transduced SSCs observed in the recipients’ testes. In summary, we demonstrated the successful production of functional-transgenic spermatozoa by transplantation of porcine SSCs where the transgenic was transduced by employing the lentiviral vector system.

Chemotherapeutic Drugs Alter Functional Properties and Proteome of Mouse Testicular Germ Cells In Vitro

Many of the testicular cancer-survived patients, treated with chemotherapeutic drugs, show infertility, pre and postimplantation loss, and germ cell abnormality. Studies examining the negative effects of chemotherapeutic drugs on testicular germ cells are ongoing; however, information on the stemness properties and proteomic profiles of these cells are lacking. This study investigated the effects of chemotherapeutic drugs etoposide, cisplatin, bleomycin, and their combination (BEP) on the physiology and stem cell activity of mouse germ cells in vitro. Our results showed that treatment with the abovementioned drugs affected germ cell viability and decreased the number of proliferating germ cells significantly at specific concentrations (0.05 µM etoposide, 1 µM cisplatin, 10 µM bleomycin, and 0.1 µM BEP), which maintained a survival rate of >90%. We also observed a significantly higher percentage of apoptotic cells and alterations in the expression of undifferentiated and differentiated spermatogonia-related genes and marker proteins in germ cells exposed to abovementioned concentrations of the drugs. Next, we performed germ cell transplantation into recipient mice and observed a remarkable reduction in stemness properties of spermatogonial stem cells at these concentrations. Based on these results, we assessed the levels of differentially expressed proteins by performing proteomic analysis. We found that treatment with the abovementioned drugs induced cell damage, oxidative stress, metabolic disruption, and immune deficiency which may promote tumor regeneration, cytotoxicity, infertility, and transgenerational cellular function transmission. Thus, this study provides information about the chemotherapy-induced recurrent destruction and thereby can lead possible changes in medication.

Direct modification of spermatogonial stem cells using lentivirus vectors in vivo leads to efficient generation of transgenic rats

Spermatogonial stem cells (SSCs) transmit genetic information to the next progeny in males. Thus, SSCs are a potential target for germline modifications to generate transgenic animals. In this study, we report a technique for the generation of transgenic rats by in vivo manipulation of SSCs with a high success rate. SSCs in juvenile rats were transduced in vivo with high titers of lentivirus harboring enhanced green fluorescent protein and mated with wild-type females to create founder rats. These founder rats expressed the transgene and passed on the transgene with an overall success rate of 50.0%. Subsequent generations of progeny from the founder rats both expressed and passed on the transgene. Thus, direct modification of SSCs in juvenile rats is an effective means of generating transgenic rats through the male germline. This technology could be adapted to larger animals, in which existing methods for gene modification are inadequate or inapplicable, resulting in the generation of transgenic animals in a variety of species.

Bisphenol A Affects on the Functional Properties and Proteome of Testicular Germ Cells and Spermatogonial Stem Cells in vitro Culture Model

The endocrine disruptor bisphenol A (BPA) is well known for its adverse effect on male fertility. Growing evidence suggests that BPA may interact with testicular germ cells and cause infertility as a result of its estrogenic activity. Objective of current in vitro study was to investigate the proliferation, survivability and stemness properties of mouse testicular germ cells exposed to BPA, and to evaluate possible expression of cellular proteome. Our results showed that germ cell viability and proliferation were not affected by low concentrations (0.01, 0.1, 1, and 10 µM) although significant reduction observed at 100 µM BPA. Germ cell self-renewal and differentiation related marker proteins expression found unchanged at those concentrations. When BPA-exposed germ cells were transplanted into recipient testes, we observed fewer colonies at higher concentrations (10 and 100 µM). Additionally, a significant frequency of recombination failure during meiosis was observed in 10 µM BPA-exposed germ cell transplanted recipient. Moreover, experiment on continuous BPA-exposed and 100 µM BPA-recovered germ cells suggested that spermatogonial stem cells are more potential to survive in adverse environment. Finally, scrutinizing differentially expressed cellular proteins resulted from our proteomic analysis, we conclude that BPA exposure might be associated with several health risks and infertility.

A Phytochemical Approach to Promotion of Self-renewal in Murine Spermatogonial Stem Cell by Using Sedum Sarmentosum Extract

Spermatogonial stem cells (SSCs) are the basis of spermatogenesis, which is dependent on the ability to self-renew and differentiation. Controlling self-renewal and differentiation of SSCs could apply to treatment of disease such as male infertility. Recently, in the field of stem cell research, it was demonstrated that effective increase in stem cell activity can be achieved by using growth factors derived from plant extracts. In this study, our aim is to investigate components from natural plant to improve the self-renewal of SSCs. To find the components, germ cells were cultured with comprehensive natural plant extracts, and then the more pure fraction, and finally single compound at different concentrations. As a result, we found 5H-purin-6-amine at 1 µg/mL, originated from Sedum sarmentosum, was a very effective compound induced SSCs proliferation. Our data showed that germ cells cultured with 5H-purin-6-amine could maintain their stable characteristics. Furthermore, transplantation results demonstrated that 5H-purin-6-amine at 1 µg/mL increased the activity of SSCs, indicating the compound could increase true SSC concentration within germ cells to 1.96-fold. These findings would be contributed to improve further reproductive research and treat male infertility by using natural plant extracts.