Colonization Of Spermatogonial Stem Cells Research Articles

WIN18,446 enhances spermatogonial stem cell homing and fertility after germ cell transplantation by increasing blood-testis barrier permeability.

Spermatogonial stem cells (SSCs) possess a unique ability to recolonize the seminiferous tubules. Upon microinjection into the adluminal compartment of the seminiferous tubules, SSCs transmigrate through the blood-testis barrier (BTB) to the basal compartment of the tubule and reinitiate spermatogenesis. It was recently discovered that inhibiting retinoic acid signaling with WIN18,446 enhances SSC colonization by transiently suppressing spermatogonia differentiation, thereby promoting fertility restoration. In this study, we report that WIN18,446 increases SSC colonization by disrupting the BTB. WIN18,446 altered the expression patterns of tight junction proteins (TJPs) and disrupted the BTB in busulfan-treated mice. WIN18,446 upregulated the expression of FGF2, one of the self-renewal factors for SSCs. While WIN18,446 enhanced SSC colonization in busulfan-treated wild-type mice, it did not increase colonization levels in busulfan-treated Cldn11-deficient mice, which lack the BTB, indicating that the enhancement of SSC colonization in wild-type testes depended on the loss of the BTB. Serial transplantation analysis revealed impaired self-renewal caused by WIN18,446, indicating that WIN18,446-mediated inhibition of retinoic acid signaling impaired SSC self-renewal. Strikingly, WIN18,446 administration resulted in the death of 45% of busulfan-treated recipient mice. These findings suggest that TJP modulation is the primary mechanism behind enhanced SSC homing by WIN18,446 and raise concerns regarding the use of WIN18,446 for human SSC transplantation.

Antioxidant Effect of Melatonin on Proliferation, Apoptosis, and Oxidative Stress Variables in Frozen-Thawed Neonatal Mice Spermatogonial Stem Cells.

Cryopreservation of spermatogonial stem cells (SSCs) is an important method to restore and maintain fertility in preadolescent children suffering from cancer. For protection of SSCs from cryoinjury, various antioxidant agents have been used. The aim of this study was to assess the antiapoptotic and antioxidant effects of melatonin in frozen-thawed SSCs. SSCs were isolated from testes of neonatal mice (3-6 days old) and their purities were measured by flow cytometry with promyelocytic leukemia zinc finger protein. After culturing, the cells were frozen in two groups (1) control and (2) melatonin (100 μM) and stored for 1 month. Finally, the cell viability, colonization rate, expression of Bcl-2 and BAX gene, and intracellular reactive oxygen species (ROS) were evaluated after freezing-thawing. Melatonin increased the viability and colonization of SSCs and Bcl-2 gene expression. It also diminished BAX gene expression and intracellular ROS. The results of this study show that melatonin with antioxidant and antiapoptotic effects can be used as an additive for freezing and long-term storage of cells and infertility treatment in the clinic.

The Protective Effect of Curcumin on the Proliferation and Colonization of Spermatogonial Stem Cells in Gamma-Irradiated Rats

Background & Objective: One of the side effects of radiotherapy can be damage to spermatogonial stem cells that may lead to spermatogenesis disorders and sterility. Protective effects of curcumin on normal cells against radiotherapy side effects have already been shown. In the current study, the protective effects of curcumin on the spermatogonial stem cells against gamma radiation were evaluated.
 Materials & Methods: This study was done on 50 adult rats in 10 experimental groups. Four groups were injected 0, 25, 50, or 100mg/kg of curcumin in 1ml olive oil for 15 days intraperitoneally, then exposed to radiation at 2 Gy on the next day. Also, four groups were treated like above but without radiation; and two groups as control with and without radiation. The day after radiation, all of the rats were euthanatized, their testes were removed, and they underwent enzymatic digestion to co-culture spermatogonial stem cells. After 12 days, the colonization of spermatogonial stem cells was assessed.
 Results: There was a significant decrease in the colonization of spermatogonial stem cell proliferation in groups that had taken radiation but not curcumin. There was a significant increase in the colonization of spermatogonial stem cells in the group which had taken radiation whit maximum curcumin compared with the other irradiated groups and was similar to non-irradiated control animals. Colonization of spermatogonial stem cells in non-irradiated animals treated with curcumin had increased compared with control groups.
 Conclusion: Injection of curcumin can protect spermatogonial stem cells against radiation. Thus, curcumin may prevent sterility in men who undergo radiotherapy.

P–115 Supplementation of healthy Sertoli cells into culture media containing follicle stimulating hormone (FSH)/testosterone (T) has no advantage in germ cell maturation

Abstract Study question In nonobstructive azoospermia (NOA) cases, whether supplementation of healthy Sertoli cells (SCs) has an effect on spermatogenic differentiation in culture medium containing FSH/T. Summary answer Expression of Crem and Acrosin increased significantly in both medium with FSH/T and medium with additional healthy SCs but there was no difference between them What is known already In NOA the induction of spermatogonial stem cells (SSCs) proliferation and differentiation has been demonstrated using different culture systems. SCs have vital roles in the regulation of spermatogenesis. Hormonal control of spermatogenesis is through FSH and T activity on SCs. Growth factors secreted by SCs via FSH, stimulate proliferation and colonization of SSCs. Although germ cells do not express androgen receptors, FSH receptors are localized on spermatogonia. It is not clear whether native SCs are sufficient for FSH/T added to the culture medium to be effective in induction of spermatogenesis, and whether supplementation of healthy SCs will increase this activity. Study design, size, duration 34 NOA and 12 obstructive azoospermia (OA) cases were included. Testicular tissue samples were taken with testicular sperm extraction (TESE) in the study and control groups. In a group of fertile cases, healthy Sertoli cells were identified and purified and then cryopreserved. Tissue samples of each case prepared in standard DMEM/F12 medium were processed in 2 separate environments containing FSH/T and FSH/T plus thawed healthy SCs for 7 days. Participants/materials, setting, methods The characterization of healthy SCs isolated from fertile cases was done by flow cytometry (FC) and immunohistochemistry using antibodies specific for GATA4 and vimentin. FITC-conjugated annexin V/PI staining and MTT assay were performed to compare the viability and proliferation of SCs before and after freezing. FC was used to measure the 7th day levels of specific markers expressed in spermatogonia (Vasa), meiotic cells (Crem) and post-meiotic cells (Protamine–2 and Acrosin). Main results and the role of chance In Annexin V staining, no difference was found in percentages of live and apoptotic SCs, and MTT exhibited that cryopreservation didn’t inhibite the SCs proliferation compared to the pre-freezing state. Vasa and Acrosin basal levels were found to be lower in infertile patients compared to the control group (8.2% vs. 30.6% and 12.8% vs. 30.5%, p < 0.05). Compared to day 0 measurements, on the 7th day in FSH/T environment, Crem level increased by 58.8% and Acrosin level increased by 195.5% (p < 0.05). Similarly, in medium supplemented with healthy SCs, by day 7, the Crem and Acrosin levels were increased to 92.2% and 204.8%, respectively (p < 0.05). Although Vasa and Protamine levels increased in both groups, they did not reach a significant level. No significant difference was found between the 7th day increase rates of Crem, Vasa, Acrosin and Protamine–2 in either FSH/T-containing medium or in medium additionally supplemented with healthy SCs (58.8% vs. 92.2%, 120.6% vs. 79.4%, 195.5% vs. 204.8% and 232.3% vs. 198.4%, respectively, p > 0.05). Our results suggest that freezing-thawing process would not impair the viability and proliferation of SCs, and adding healthy SCs to the culture medium to correct impaired gene expression does not have an advantage over FSH/T. Limitations, reasons for caution The 7-day culture period we determined might be not sufficient for spermatogenic differentiation completion. This period could be extended in order to see further morphological differentiation may need. Wider implications of the findings: The failure of the culture media containing FSH/T to show the expected effectiveness could be thought to be due to the SCs’ inadequate response to these hormones. Therefore, healthy SCs supplementation would be needed, but this could pose ethical issues. Our findings show that it is not necessary. Trial registration number 214S532

The guardians of germ cells; Sertoli-derived exosomes against electromagnetic field-induced oxidative stress in mouse spermatogonial stem cells

Nowadays, prolonged exposure to electromagnetic fields (EMF) has raised public concern about the detrimental potential of EMF on spermatogonial stem cells (SSCs) and spermatogenesis. Recent studies introduced the fundamental role of Sertoli cell paracrine signaling in the regulation of SSCs maintenance and differentiation in fertility preservation. Thus we investigated the therapeutic effect of Sertoli-derived exosomes (Sertoli-EXOs) as powerful paracrine mediators in SSCs subjected to EMF and its underlying mechanisms. SSCs and Sertoli cells were isolated from neonate mice testis, and identified by their specific markers. Then SSCs were exposed to 50 Hz EMF with intensity of 2.5 mT (1 h for 5 days) and supplemented with exosomes that were isolated from pre-pubertal Sertoli cells. Sertoli-EXOs were characterized and the uptake was observed by PKH26 labeling. The cell viability, colonization efficiency, reactive oxygen species (ROS) balance, cell cycle arrest and apoptosis induction were then analysed. SSCs were confirmed by immunocytochemistry (Oct4, Plzf) and Sertoli cells were identified through Sox9 and vimentin expression by immunocytochemistry and Real-time PCR (qRT-PCR), respectively. Our results demonstrated the detrimental effect of EMF via ROS accumulation that reduced the expression of catalase antioxidant, cell viability and colonization of SSCs. Also, AO/PI and flow cytometry analysis demonstrated the elevation of apoptosis in SSCs exposed to EMF in comparison with control. qRT-PCR data confirmed the up-regulation of apoptotic gene (Caspase-3) and down-regulation of SSCs specific gene (GFRα1). Consequently, the administration of Sertoli-EXOs exerted ameliorative effect on SSCs and significantly improved these changes through the regulation of oxidative stress. These findings suggest that Sertoli-EXOs have positive impact on SSCs exposed to EMF and can be useful in further investigation of Sertoli-EXOs as a novel therapeutic agent which may recover the deregulated SSCs microenvironment and spermatogenesis after exposure to EMF.

Effect of miR-30a-5p on Apoptosis, Colonization, and Oxidative Stress Variables in Frozen-Thawed Neonatal Mice Spermatogonial Stem Cells.

Cryopreservation of spermatogonial stem cells (SSCs) is a useful method for fertility preservation in preadolescent children suffering from cancer. However, SSCs may become damaged during cryopreservation due to the generation of reactive oxygen species (ROS). For this reason, various antioxidant agents have been used to protect SSCs from cryopreservation-induced damages. Recently, it has been reported that miR-30a-5p has antiapoptotic and antioxidant activity. The aim of this study was to assess the antiapoptotic and antioxidant effects of miR-30a-5p mimics in frozen-thawed SSCs. To this end, SSCs were isolated from male BALB/C mice (3-6 days old) and cultivated for 14 days. After the detection of optimum concentration, a miR-30a-5p mimic or miR-30a-5p inhibitor with Lipofectamine was transfected into SSCs and, finally, the cell groups were frozen for 1 week. After thawing, different properties, including cell viability (using MTT), colonization of SSCs (number and diameter of colonies), ROS generation (using DCFH-DA assay), levels of malondialdehyde (MDA) and superoxide dismutase (SOD), and gene expression of Bcl-2 and BAXBax (using quantitative real-time PCR), were investigated. The transfection of SSCs with miR-30a-5p mimics before the freezing-thawing process significantly increased the viability, number, and diameter of SSCs colonies. Also, the miR-30a-5p mimic decreased the levels of ROS production and MDA, but it increased the SOD levels. Moreover, the miR-30a-5p mimic decreased BAX and increased Bcl-2 expression in frozen-thawed SSCs. The transfection of SSCs with the miR-30a-5p mimic can increase cell viability and antioxidant defense, and it can decrease apoptosis during the freezing-thawing process. If SSC is able to produce spermatozoa after the transfection of miR-30a-5p and the freezing-thawing process, it can be suggested as a promising strategy for the cryopreservation of SSCs in prepubertal boys suffering from cancer.

Differential Proliferation Effects after Short-Term Cultivation of Mouse Spermatogonial Stem Cells on Different Feeder Layers.

Objective Spermatogonial stem cells (SSCs) provide the cellular basis for sperm production transforming the male’s genetic information to the next generation. We aimed to examine the effect of different feeder layer on proliferation of SSCs. Materials and Methods In this experimental study, we compared the in vitro effects of the co-culture of mouse SSCs with mouse embryonic fibroblasts (MEFs), sandos inbred mice (SIM) embryo-derived thioguanine- and ouabain- resistant (STO) feeders, and neonate and adult testicular stroma cell (TSC) feeders on the efficiency of mouse SSC proliferation and colony formation. Cells were cultivated on top of MEFs, STO, and neonate and adult TSCs feeder layers for 30 days. The number and diameter of colonies and also the number of cells were evaluated during day 7, 15, 25, and 30 of culture. The mRNA expression of germ cells and somatic cells were analyzed. Results In our study, we observed a significant difference in the proliferation rates and colony size of SSCs among the groups, especially for MEFs (P<0.05). SSCs can proliferate on MEFS, but not on STO, neonate or adult TSCs. Using immunocytochemistry by KI67 the proliferative activities of SSC colonies on MEFs were confirmed. The results of Fluidigm real-time polymerase chain reaction (RT-PCR) showed a high expression of the germ cell genes the promyelocytic leukemia zinc finger protein (PLZF), deleted in azoospermia-like (DAZL), octamer-binding transcription factor 4 (OCT4), and DEAD (Asp-Glu-Ala-Asp) box polypeptide 4 (DDX4 or VASA) in SSCs, and a low expression of these genes in the feeder layers. Furthermore, we observed a higher expression of vimentin and integrin-B1 in feeder layers than in SSCs (P<0.05). ConclusionBased on the optimal effect of MEFs for better colonization of SSCs, these feeder cells seem to be appropriate candidates for SSC cultures prior to transplantation. Therefore, it is suggested using these feeder cells for SSC cultivation.

The Forkhead Transcription Factor FOXC2 Is Required for Maintaining Murine Spermatogonial Stem Cells.

Continuous spermatogenesis from puberty to old age in males relies on spermatogonial stem cells (SSCs) that possess the property of self-renewal and differentiation. The delicate balance between self-renewal and differentiation is of great importance. In mice, SSCs exist as a subpopulation of undifferentiated spermatogonia. SSCs are controlled by intrinsic molecular pathways that can be activated by extrinsic signals. Our results here first show that the expression of forkhead box C2 (FOXC2) is restricted to GFRα1-positive spermatogonia in the testis. Whole-mount immunofluorescence results reveal that FOXC2 is expressed predominately in As and Apr spermatogonia. Reduction of Foxc2 gene expression by shRNA lentivirus treatment significantly impairs the maintenance of SSCs in vitro. Furthermore, knock-down of Foxc2 decreases SSC colonization to only 10.42% compared to the control by transplantation. Reverse transcription and real-time quantitative PCR gene analyses following knock-down of Foxc2 indicate that Foxc2 may act as a suppressor for SSC differentiation. Extrinsic stimuli treatments show that glial cell line-derived neurotrophic factor and retinoic acid act in opposite ways to regulate FOXC2 expression and subsequent SSC property. These results suggest that FOXC2 is a critical intrinsic regulator of SSC self-renewal and differentiation.

Reversible inhibition of the blood-testis barrier protein improves stem cell homing in mouse testes.

Stem cell homing is a complex phenomenon that involves multiple steps; thus far, attempts to increase homing efficiency have met with limited success. Spermatogonial stem cells (SSCs) migrate to the niche after microinjection into seminiferous tubules, but the homing efficiency is very low. Here we report that reversible disruption of the blood-testis barrier (BTB) between Sertoli cells enhances the homing efficiency of SSCs. We found that SSCs on a C57BL/6 background are triggered to proliferate in vitro when MHY1485, which stimulates MTORC, were added to culture medium. However, the cultured cells did not produce offspring by direct injection into the seminiferous tubules. When acyline, a gonadotropin-releasing hormone (GnRH) analogue, was administered into infertile recipients, SSC colonization increased by ~5-fold and the recipients sired offspring. In contrast, both untreated individuals and recipients that received leuprolide, another GnRH analogue, remained infertile. Acyline not only decreased CLDN5 expression but also impaired the BTB, suggesting that increased colonization was caused by efficient SSC migration through the BTB. Enhancement of stem cell homing by tight junction protein manipulation constitutes a new approach to improve homing efficiency, and similar strategy may be applicable to other self-renewing tissues.

Evaluation of the effect of follicular stimulating hormone on the in vitro bovine spermatogonial stem cells self-renewal: An experimental study

Spermatogonial stem cells (SSCs) are undifferentiated cells which are highly reproducible and expandable. Several studies have been conducted to reproduce these cells in culture. They used growth factors, hormones and different feeder cells to improve survival and proliferation of SSCs. This study was conducted to evaluate the effects of follicular stimulating hormone (FSH) on gene expression of fibroblast growth factor (FGF2) and glial cell-derived neurotrophic factor (GDNF) in Sertoli cells. Sertoli cells and SSCs were isolated from 3-5 month-old calves. Bovine testicular cells were cultured for 15 days with or without FSH. Identification of these cells was confirmed by immunocytochemistry analysis. Colony formation of SSCs was evaluated using an inverted microscope. The gene expression of FGF2 and GDNF and the gene markers bcl6b, thy-1, and C-kit were evaluated using the quantitative RT-PCR technique. The results indicated that FSH increased colonization of SSCs. the expression of GDNF, FGF2, and markers of undifferentiated spermatogonia was increased following culture in control and FSH groups (p<0.05), this increase was more in FSH group. Conversely, the expression of C-kit was decreased in both groups (p<0.05). The results showed that FSH can increase the self-renewal of SSCs in vitro via upregulation of GDNF and FGF2 expression in Sertoli cells.

Upregulation of Integrin-α6 and Integrin-β1 Gene Expressions in Mouse Spermatogonial Stem Cells after Continues and Pulsed Low Intensity Ultrasound Stimulation.

Objective low intensity ultrasound (continues and pulsed) is a form of energy. Spermatogonial stem cells (SSCs) are at the base of male fertility. This study investigated the effects of low intensity ultrasound stimulation (LIUS) and low intensity pulsed ultrasound stimulation (LIUPS) on the expression of germ cell-specific and pluripotency genes in SSCs in vitro. Materials and Methods In this experimental study, isolated SSCs from neonatal male mice were cultured in Dulbecco’s Modified Eagle’s Medium (DMEM) with 10% fetal bovine serum (FBS). In addition, to confirm identification of SSCs, PLZF protein was detected positively in SSCs derived colonies. SSCs were stimulated by LIUS and LIUPS for 5 days, followed by assessment of expression of integrin-α6 (Itga6) and β1 (Itgβ1), as two germ cell-specific genes, and Oct- 4, as a pluripotency gene, on day 21st by quantitive reverse transcriptase-polymerase chain reaction (qRT-PCR). To investigate the proliferation rate and colonization of SSCs in different groups, counting whole number of the cells and colonies as well as analysis of the respective diameters were performed on days 7th, 14th and 21st. Data was analyzed by ANOVA test. Results LIUS and LIUPS treatment of mouse SSCs increased expression of Itga6 and Itgβ1 genes in the experimental groups, compared to the control group (P<0.05), whereas there was no significant difference between the groups, regarding the expression of Oct-4 gene. These treatments maintained survival rate, while they increased proliferation rate and colonization of SSCs during the first week of culture. However, within the second week, proliferation rate and colonization were decreased in the experimental groups. ConclusionThese results suggested that LIUS and LIUPS treatment had good effect on SSCs proliferation and colonization, based on the gene-specific marker expression during 21 days culture in vitro.

Effect of extracellular matrix on bovine spermatogonial stem cells and gene expression of niche factors regulating their development in vitro

Extracellular matrix (ECM) could influence cells function through providing structural and functional networks facilitating the cellular interactions. The present study was conducted to evaluate the effect of culture on ECM versus plastic on bovine spermatogonial stem cells (SSCs) and growth factors regulating their development. Following isolation, bovine testicular cells were cultured on ECM-coated or uncoated (control) plates for 12 days. The colonization of SSCs was assessed by inverted microscope and the gene expression was evaluated using quantitative real-time PCR. The colonization rate was greater in ECM than the control group (P<0.05). The expression of markers of undifferentiated spermatogonia increased in response to conventional culture (P<0.05). Conversely, the expression of ckit as a marker for differentiated spermatogonia was reduced following culture in the control and ECM groups (P<0.05), but this decrease was less in ECM group (P<0.05). Accordingly, while cells cultured on uncoated plates had greater expression of markers of undifferentiated spermatogonia (P<0.05), cells cultured on ECM-coated plates showed higher expression of ckit (P<0.05). Moreover, culture on ECM resulted in higher expression of kit ligand (Kitlg; P<0.05), whereas culture on plastic led to greater expression of glial cell line-derived neurotrophic factor (Gdnf; P<0.05). In conclusion, the present study revealed that the permissive effect of ECM on bovine SSCs differentiation in vitro, which was probably mediated through upregulation of KITLG expression. Moreover, the results imply that GDNF might contribute to germ cells self-renewal during conventional culture.

Effects of Gonadotropin Releasing Hormone (GnRH) on bovine spermatogonial stem cell proliferationatogonial stem cells proliferation

Identification of exogenous factors affecting spermatogonial stem cells (SSCs) proliferation in vitro, provides worthy ways to study the basic biology of the cells. The aim of this study was to investigate the effects of a GnRH analogue (alareline acetate) on SSCs colonization in short-term co-culture with sertoli cells. Five, three-month old Holstein male calves were used to isolate spermatogonial and sertoli cells. Testicular germ cell collection was made by enzymatic digestion methods. The cells were co-cultured in a 15 day period and in vitro effects of various doses (0.5, 1, 2 and 4 µg/ml) of GnRHa on SSCs colonization were assessed. Effects of GnRHa on SSCs proliferation were dose dependent. In conclusion, it was demonstrated that 1 µg/ml GnRHa was the optimum dose for SSCs colonization in comparison with control group. The highest treatment dose (4 µg/ml GnRHa), negatively affected SSCs colonization in comparison with control group.

201 TRANSPLANTATION OF SSEA-1+ AND SSEA-4+ SPERMATOGONIAL CELL SUBPOPULATIONS IN UNTREATED SEXUALLY IMMATURE DOMESTIC CATS

Captive breeding efforts in felids, including assisted reproduction techniques, have had varied success depending on species. Spermatogonial stem cells (SSC), comprising a small percentage of germ cells in the testis, are progenitor cells with the ability to both self-renew and differentiate into spermatozoa throughout the life of the male. Manipulation of SSC for transplantation (SSCT) may allow the propagation of genetically important males, as demonstrated by the production of ocelot sperm following transplantation of ocelot mixed germ cells to domestic cat testes (Silva et al. 2012 J. Androl. 33, 264–276). Using specific cell surface markers, SSC have been isolated from mixed germ cells in several other species for SSCT, culture, and studying germ cell biology; however, expression may differ with species. Using the domestic cat as a model for exotic felids, we recently began evaluating the expression of surface markers in feline SSC. Previously, we determined that pluripotent markers SSEA-1, SSEA-4, TRA-1–60, and TRA-1–81 were more specific to cat spermatogonia than SSC surface markers GFRα1 and GPR125 used in other species, with SSEA-1 and SSEA-4 expressed in the fewest cells (Powell et al. 2011 Reprod. Fertil. Dev. 24, 221–222; Powell et al. 2012 Reprod. Fertil. Dev. 25, 290–291). Our current goal was to 1) confirm the presence of SSC within SSEA-1+ and SSEA-4+ cell populations by the ability to colonize following SSCT; 2) compare the effectiveness of transplanting SSC purified by flow cytometry versus mixed germ cells; and 3) show that depletion of endogenous germ cells before SSCT, usually performed by irradiation or chemotherapy in other studies, is not necessary when using sexually immature recipients. Mixed germ cells from 8 to 12 adult testes were pooled, stained for SSEA-1 or SSEA-4, and sorted by flow cytometry. SSEA-1+, SSEA-4+, or mixed germ cells were then labelled with the membrane dye PKH26 (Sigma MINI26) and injected into the testes of six 5-month-old and six 6-month-old cats at the site of the external rete testis after carefully microdissecting the head of the epididymis away from the testis. Injections contained an average of 230 000 sorted or 10 × 106 mixed germ cells suspended in 80 μL of DMEM/F12 + 3 μL of Trypan Blue (T8154, Sigma, St. Louis, MO, USA). Testes were harvested 10 to 12 weeks post-SSCT and bisected, half snap-frozen for later cryosectioning and the other half enzymatically digested to loosen seminiferous tubules for immediate evaluation. Fluorescence was detected in the testes of both 6-month-old males that received injections of mixed germ cells, one 6-month-old male injected with SSEA-4+ cells, and two 5-month-old males, one injected with SSEA-4+ cells and one with SSEA-1+ cells. Results indicate that SSC are found in both SSEA-1+ and SSEA-4+ cell populations, but that purification of SSC is not necessary for successful SSCT. Additionally, SSC colonization in cats is possible without depletion of endogenous cells in sexually immature recipients.

Improvement of Expression of α6 and β1 Integrins by the Co-culture of Adult Mouse Spermatogonial Stem Cells with SIM Mouse Embryonic Fibroblast Cells (STO) and Growth Factors.

Spermatogonial Stem Cells (SSCs) maintain spermatogenesis throughout the life of the male. Because of the small number of SSCs in adult, enriching and culturing them is a crucial step prior to differentiation or transplantation. Maintenance of SSCs and transplantation or induction of in vitro spermio-genesis may provide a therapeutic strategy to treat male infertility. This study investigated the enrichment and proliferation of SSCs co-cultured with STO cells in the presence or absence of growth factors. Spermatogonial populations were enriched from the testis of 4-6 week-old male mice by MACS according to the expression of a specific marker, Thy-1. Isolated SSCs were cultured in the presence or absence of growth factors (GDNF, GFRα1 and EGF) on STO or gelatin-coated dishes for a week. Subsequently, the authors evaluated the effects of growth factors and STO on SSCs colonization by alkaline phosphates (AP) activity and flow cytometery of α6 and β1 integrins. SSCs co-cultured with STO cells and growth factors developed colonization and AP activity as well as expression of α6 and β1 integrins (P≤0/05). Our present SSC-STO co-culture provides conditions that may allow efficient maintenance and proliferation of SSCs for the treatment of male infertility.

Reconstitution of Mouse Spermatogonial Stem Cell Niches in Culture

Spermatogonial stem cells (SSCs) reside in specific niches within seminiferous tubules. These niches are thought to secrete chemotactic factors for SSCs, because SSCs migrate to them upon transplantation. However, the identity of these chemotactic molecules remains unknown. Here, we established a testis feeder cell culture system and used it to identify SSC chemotactic factors. When seeded on testis cells from infertile mice, SSCs migrated beneath the Sertoli cells and formed colonies with a cobblestone appearance that were very similar to those produced by hematopoietic stem cells. Cultured cells maintained SSC activity and fertility for at least 5 months. Cobblestone colony formation depended on GDNF and CXCL12, and dominant-negative GDNF receptor transfection or CXCL12 receptor deficiency reduced SSC colonization. Moreover, GDNF upregulated CXCL12 receptor expression, and CXCL12 transfection in Sertoli cells increased homing efficiency. Overall, our findings identify GDNF and CXCL12 as SSC chemotactic factors in vitro and in vivo.

Studying Spermatogenesis by using In vivo and In vitro Models:Advantages and Disadvantages of these Models for Practical Use

Several experimental systems are available for inducing spermatogenesis outside the endogenous testis. These systems have been developed as tools for studying spermatogenesis and as an option for preserving genetic material obtained from males when sperm recovery is not possible. Two in vivo systems are available for this purpose: tissue grafting and cell transplantation. Ectopic grafting of immature testicular tissues into immunodeficient mouse hosts is a type of in vivo system that allows the immature testicular tissue from many types of animals to undergo complete spermatogenesis. The other in vivo system is germ cell transplantation into the recipient testis, which induces colonization of spermatogonial stem cells from many types of animals and allows the stem cells to differentiate into spermatozoa in some cases. Furthermore, 2 in vitro systems are available: tissue culture and 3-dimensional (3D) cell culture. The tissue culture system and the combination of tissue culture and germ cell transplantation system were developed recently; this made it possible to perform complete spermatogenesis by using mouse spermatogonial stem cells. Isolated immature mouse testicular cells can differentiate into spermatozoa when the 3D culture system is used. All these systems have advantages and disadvantages with respect to studying spermatogenesis and preserving fertility in many types of animals. Therefore, it is necessary to consider many factors that might affect the results of spermatogenesis in order to use these experimental systems appropriately. Herein, we have discussed the advantages and disadvantages of these systems, especially in connection with several factors that may affect spermatogenesis.