Irradiation affects germ and somatic cells in prepubertal monkey testis xenografts.

Study question: Does irradiation evoke adverse effects in germ and somatic cells in testis xenografts from prepubertal monkeys? Summary answer: In addition to the expected depletion of germ cells, a dose-dependent effect of irradiation was observed at the mRNA and protein level in Sertoli and peritubular myoid cells. What is known already: Testicular irradiation studies in monkeys have focused on the dose-dependent effects on germ cells. Previous studies using intact animals or xenografts reported that germ cells are highly sensitive to irradiation. Their depletion was demonstrated by morphometric and histological analyses. The effect of irradiation on expression of Sertoli and peritubular myoid cell markers, however, has not yet been described. Study design, size, duration: The testes of two prepubertal macaques (Macaca fascicularis) were dissected into testicular fragments. Fragments were randomly exposed in vitro to one of the following three doses of irradiation: 0 Gy, n = 60; 1 Gy, n = 54; 4 Gy, n = 72. Non-irradiated control fragments (0 Gy) were placed into the Faxitron for 6.6 min without irradiation. For 1 Gy and 4 Gy irradiation was applied for 1.7 and 6.6 min, respectively. Grafts were then either immediately analyzed or subcutaneously implanted under the back skin of 39 nude mice and analyzed after 6.5 months. Participants/materials setting methods: Post grafting, 133 testicular xenografts were retrieved. The body weight, serum testosterone level and seminal vesical weight of the host mice as well as the number and weight of retrieved grafts were determined. Larger grafts were used to evaluate both mRNA expression profiles and protein expression patterns. In total, 71 testicular fragments were used for morphometric and histological analysis while 68 fragments were analyzed for gene expression. For PCR arrays, M. fascicularis-specific primer sequences were employed. Irradiation-induced changes in the transcript levels of 34 marker genes were determined for each testicular graft. The effects of irradiation on peritubular myoid cells and Sertoli cells were confirmed by immunohistochemical analysis of chemokine (C-X-C motif) ligand type 11 (CXCL11), alpha smooth muscle actin (SMA) and chemokine (C-X-C motif) ligand type 12 (CXCL12). Main results and the role of chance: The four testes gave rise to 106 xenografts, which were individually analyzed, limiting the role of chance despite using only two monkeys in the study. Prior to grafting, the two donors displayed spermatogonia as the most advanced germ cell type in 95% and 70% of seminiferous tubules, respectively, while remaining tubules contained SCO. No spermatocytes were encountered prior to grafting in either monkey. After 6.5 months, non-irradiated grafts displayed spermatocytes in 15.4% and 1.8% of seminiferous tubules indicating an induction of meiosis. Irradiation resulted in a complete absence of spermatocytes. The percentage of seminiferous tubules containing spermatogonia declined in a dose-dependent manner. In non-irradiated xenografts, ~40% of tubules contained spermatogonia. This proportion was reduced to 3.4% and 4.3% in the 1 Gy treated group and to 1.3% and 0.2% in 4 Gy irradiated grafts. A dose-dependent decline in mRNA levels of selected germ cell marker genes supported the morphologically detected loss of germ cells. Irradiation had no effect on CXCL12 transcript levels. At the protein level, CXCL12-positive Sertoli cells were most abundant in the 1 Gy group compared to the 4 Gy group (P < 0.05), indicating a potential role of CXCL12 during recovery of primate spermatogenesis. The most prominent radiation-evoked changes were for CXCL11, which was localized to smooth muscle cells of blood vessels and seminiferous tubules. Transcript levels declined in a dose-dependent manner in grafts from both monkeys (MM687: P < 0.01 (0 Gy versus 4 Gy), MM627: P < 0.05 (0 Gy versus 4 Gy), P < 0.001 (1 Gy versus 4 Gy)). CXCL11 patterns of protein expression revealed irradiation-dependent changes as well. That peritubular cells are affected by X-irradiation was substantiated by changes at the transcript level between 1 and 4 Gy exposed groups (P < 0.01) and at the protein level of SMA (P < 0.05, 0 Gy versus 4 Gy). Large scale data: n/a. Limitations, reasons for caution: The spermatogonial stem cell system in primates is remarkably different from rodents. Therefore, data from a non-human primate may be more relevant to man. However, species-specific differences amongst primates cannot be fully excluded and the use of only two donors may raise concerns toward the generalization of the findings. There may also be important differences across the prepubertal period (e.g. infancy, early childhood) that are not represented by the ages included in the present study. Wider implications of the findings: This study is the first to indicate relevant testicular somatic cell responses following irradiation of prepubertal primate tissue. In addition to the well-known depletion of germ cells, the changes in Sertoli, and in particular peritubular myoid, cells may have important consequences for spermatogenic recovery. These novel findings should be taken into consideration when irradiation effects are assessed in tumor survivors. Study funding and competing interest(s): Interdisciplinary Center for Clinical Research (IZKF) Münster (Schl2/001/13) and the Excellence Cluster 'Cells in Motion' at the University Münster. There are no conflicts of interest to declare.

Single-cell gene expression analysis reveals diversity among human spermatogonia.

STUDY QUESTION: Is the molecular profile of human spermatogonia homogeneous or heterogeneous when analysed at the single-cell level? SUMMARY ANSWER: Heterogeneous expression profiles may be a key characteristic of human spermatogonia, supporting the existence of a heterogeneous stem cell population. WHAT IS KNOWN ALREADY: Despite the fact that many studies have sought to identify specific markers for human spermatogonia, the molecular fingerprint of these cells remains hitherto unknown. STUDY DESIGN, SIZE, DURATION: Testicular tissues from patients with spermatogonial arrest (arrest, n = 1) and with qualitatively normal spermatogenesis (normal, n = 7) were selected from a pool of 179 consecutively obtained biopsies. Gene expression analyses of cell populations and single-cells (n = 105) were performed. Two OCT4-positive individual cells were selected for global transcriptional capture using shallow RNA-seq. Finally, expression of four candidate markers was assessed by immunohistochemistry. PARTICIPANTS/MATERIALS, SETTING, METHODS: Histological analysis and blood hormone measurements for LH, FSH and testosterone were performed prior to testicular sample selection. Following enzymatic digestion of testicular tissues, differential plating and subsequent micromanipulation of individual cells was employed to enrich and isolate human spermatogonia, respectively. Endpoint analyses were qPCR analysis of cell populations and individual cells, shallow RNA-seq and immunohistochemical analyses. MAIN RESULTS AND THE ROLE OF CHANCE: Unexpectedly, single-cell expression data from the arrest patient (20 cells) showed heterogeneous expression profiles. Also, from patients with normal spermatogenesis, heterogeneous expression patterns of undifferentiated (OCT4, UTF1 and MAGE A4) and differentiated marker genes (BOLL and PRM2) were obtained within each spermatogonia cluster (13 clusters with 85 cells). Shallow RNA-seq analysis of individual human spermatogonia was validated, and a spermatogonia-specific heterogeneous protein expression of selected candidate markers (DDX5, TSPY1, EEF1A1 and NGN3) was demonstrated. LIMITATIONS, REASONS FOR CAUTION: The heterogeneity of human spermatogonia at the RNA and protein levels is a snapshot. To further assess the functional meaning of this heterogeneity and the dynamics of stem cell populations, approaches need to be developed to facilitate the repeated analysis of individual cells. WIDER IMPLICATIONS OF THE FINDINGS: Our data suggest that heterogeneous expression profiles may be a key characteristic of human spermatogonia, supporting the model of a heterogeneous stem cell population. Future studies will assess the dynamics of spermatogonial populations in fertile and infertile patients. LARGE SCALE DATA: RNA-seq data is published in the GEO database: GSE91063. STUDY FUNDING/COMPETING INTEREST(S): This work was supported by the Max Planck Society and the Deutsche Forschungsgemeinschaft DFG-Research Unit FOR 1041 Germ Cell Potential (grant numbers SCHO 340/7-1, SCHL394/11-2). The authors declare that there is no conflict of interest.

A combined approach facilitates the reliable detection of human spermatogonia in vitro.

STUDY QUESTION: Does a combined approach allow for the unequivocal detection of human germ cells and particularly of spermatogonia in vitro? SUMMARY ANSWER: Based on our findings, we conclude that an approach comprising: (i) the detailed characterization of patients and tissue samples prior to the selection of biopsies, (ii) the use of unambiguous markers for the characterization of cultures and (iii) the use of biopsies lacking the germ cell population as a negative control is the prerequisite for the establishment of human germ cell cultures. WHAT IS KNOWN ALREADY: The use of non-specific marker genes and the failure to assess the presence of testicular somatic cell types in germ cell cultures may have led to a misinterpretation of results and the erroneous description of germ cells in previous studies. STUDY DESIGN, SIZE, DURATION: Testicular biopsies were selected from a pool of 264 consecutively obtained biopsies. Based on the histological diagnosis, biopsies with distinct histological phenotypes were selected (n = 35) to analyze the expression of germ cell and somatic cell markers. For germ cell culture experiments, gonadotrophin levels and clinical data were used as selection criteria resulting in the following two groups: (i) biopsies with qualitatively intact spermatogenesis (n = 4) and (ii) biopsies from Klinefelter syndrome Klinefelter patients lacking the germ cell population (n = 3). PARTICIPANTS/MATERIALS, SETTING, METHODS: Quantitative real-time PCR analyses were performed to evaluate the specificity of 18 selected germ cell and 3 somatic marker genes. Cell specificity of individual markers was subsequently validated using immunohistochemistry. Finally, testicular cell cultures were established and were analyzed after 10 days for the expression of germ cell- (UTF1, FGFR3, MAGE A4, DDX4) and somatic cell-specific markers (SMA, VIM, LHCGR) at the RNA and the protein levels. MAIN RESULTS AND THE ROLE OF CHANCE: Interestingly, only 9 out of 18 marker genes reflected the presence of germ cells and cell specificity could be validated using immunohistochemistry. Furthermore, VIM, SMA and LHCGR were found to reflect the presence of testicular somatic cells at the RNA and the protein levels. Using this validated marker panel and biopsies lacking the germ cell population (n = 3) as a negative control, we demonstrated that germ cell cultures containing spermatogonia can be established from biopsies with normal spermatogenesis (n = 4) and that these cultures can be maintained for the period of 10 days. However, marker profiling has to be performed at regular time points as the composition of testicular cell types may continuously change under longer term culture conditions. LIMITATIONS, REASONS FOR CAUTION: There are significant differences regarding the spermatogonial stem cell (SSC) system and spermatogenesis between rodents and primates. It is therefore possible that marker genes that do not reflect the presence of spermatogonia in the human are specific for spermatogonia in other animal models. WIDER IMPLICATIONS OF THE FINDINGS: While some studies have reported that human SSCs can be maintained in vitro and show characteristics of pluripotency, the germ cell origin and the differentiation potential of these cells were subsequently called into question. This study provides critical insights into possible sources for the misinterpretation of results regarding the presence of germ cells in human testicular cell cultures and our findings can therefore help to avoid conflicting reports in the future. STUDY FUNDING/COMPETING INTEREST(S): This project was supported by the Stem Cell Network North Rhine-Westphalia and the Innovative Medical Research of the University of Münster Medical School (Grant KO111014). In addition, it was funded by the DFG-Research Unit FOR 1041 Germ Cell Potential (GR 1547/11-1 and SCHL 394/11-2), the BMBF (01GN0809/10) and the IZKF (CRA 03/09). The authors declare that there is no conflict of interest. TRIAL REGISTRATION NUMBER: Not applicable.