Dynamics, ultrastructure and gene expression of human in vitro organized testis cells from testicular sperm extraction biopsies.

von Kopylow K ，Schulze W ，Salzbrunn A ，Schaks M ，Schäfer E ，Roth B ，Schlatt S ，Spiess AN ... -  《-》

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

Kossack N ，Terwort N ，Wistuba J ，Ehmcke J ，Schlatt S ，Schöler H ，Kliesch S ，Gromoll J ... -  《-》

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

Does irradiation evoke adverse effects in germ and somatic cells in testis xenografts from prepubertal monkeys? 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. 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. 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. 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). 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). n/a. 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. 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. 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.

Tröndle I ，Westernströer B ，Wistuba J ，Terwort N ，Schlatt S ，Neuhaus N ... -  《-》

Reassembly of adult human testicular cells: can testis cord-like structures be created in vitro?

Can enzymatically dispersed testicular cells from adult men reassemble into seminiferous cord-like structures in vitro? Adult human testicular somatic cells reassembled into testicular cord-like structures via dynamic interactions of Sertoli and peritubular cells. In vitro approaches using dispersed single cell suspensions of human testes to generate seminiferous tubule structures and to initiate their functionality have as yet shown only limited success. Testes from 15 adult gender dysphoria patients (mean ± standard deviation age 35 ± 9.3 years) showing spermatogonial arrest became available for this study after sex-reassignment surgery. In vitro primary testicular somatic cell cultures were generated to explore the self-organizing ability of testicular somatic cells to form testis cords over a 2-week period. Morphological phenotype, protein marker expression and temporal dynamics of cell reassembly were analyzed. Cell suspensions obtained by two-step enzymatic digestion were plated onto glass coverslips in 24-well plates. To obtain adherent somatic cells, the supernatant was discarded on Day 2. The culture of the attached cell population was continued. Reassembly into cord-like structures was analyzed daily by microscopic observations. Endpoints were qualitative changes in morphology. Cell types were characterized by phase-contrast microscopy and immunohistochemistry. Dynamics of cord formation were recorded by time-lapse microscopy. Primary adult human testicular cells underwent sequential morphological changes including compaction and reaggregation resulting in round or elongated cord-like structures. Time-lapse video recordings within the first 4 days of culture revealed highly dynamic processes of migration and coalescence of reaggregated cells. The cellular movements were mediated by peritubular cells. Immunohistochemical analysis showed that both SRY-related high mobility box 9-positive Sertoli and α-smooth muscle actin-positive peritubular myoid cells interacted and contributed to cord-like structure formation. Not applicable. Owing to scarcity of normal human testicular tissue, testes from gender dysphoria patients were used in the study. The regressed status might influence the experimental responses of primary cells. We observed basic morphological features resembling in vivo testicular cords, however, the proof of functionality (e.g. support of germ cells) will need further studies. The proposed in vitro culture system may open opportunities for examination of testicular cell interactions during testicular tubulogenesis. Further refinement of our approach may enable initiation of ex vivo spermatogenesis. The work was supported by EU-FP7-PEOPLE-2013-ITN 603568: 'Growsperm'. No conflict of interests is declared.

Mincheva M ，Sandhowe-Klaverkamp R ，Wistuba J ，Redmann K ，Stukenborg JB ，Kliesch S ，Schlatt S ... -  《-》

Evaluation of apoptotic- and autophagic-related protein expressions before and after IVM of fresh, slow-frozen and vitrified pre-pubertal mouse testicular tissue.

Do freezing and in vitro culture procedures enhance the expression of proteins involved in apoptotic or autophagic pathways in murine pre-pubertal testicular tissue? IVM strongly modified apoptosis- and autophagy-related relative protein levels in mice testicular tissue whereas the impact of cryopreservation procedures was minimal at the end of the culture. In vitro spermatogenesis remains a challenging technical issue as it imposes to find a very close balance between survival and death of germ cell natural precursors (i.e. gonocytes and spermatogonia), which will eventually undergo a complete spermatogenesis close to in vivo conditions. The establishment of efficient culture conditions coupled with suitable cryopreservation procedures (e.g. controlled slow freezing [CSF] and solid surface vitrification [SSV]) of pre-pubertal testicular tissue is a crucial step in the fields of fertility preservation and restoration to improve the spermatic yield obtained in vitro. Here, we study cryopreservation procedures (i.e. CSF or SSV) and the impact of culture media compositions. A first set of 66 mouse pre-pubertal testes were directly cultured during 30, 36, 38 and 60 days (D) from 2.5 to 6.5-day-old CD-1 mice to evaluate the impact of time-aspect of culture and to endorse the reverse phase protein microarrays (RPPM) technique as an adapted experimental tool for the field of in vitro spermatogenesis. Ninety others fresh, slow-frozen and vitrified pre-pubertal testes were cultured during 30 days for the principal study to evaluate the impact of cryopreservation procedures before and after culture. Thirty-four testes dissected from 2.5, 6.5, 36.5, 40.5, 42.5 and 62.5 days postpartum (dpp) mice, corresponding to the time frames of spermatogenesis orchestrated in vitro, were used as in vivo controls. After in vitro culture, testicular tissue samples originated from 2.5 or 6.5-day-old CD-1 male mice were analyzed using RPPM. This targeted proteomic technique allowed us to assess the expression level of 29 apoptosis- and autophagy-related factors by normalizing blank-corrected signal values. In addition, morphological analyses (e.g. HES, PAS, TRA98 and CREM) and DNA fragmentation in intra-tubular cells (i.e. terminal deoxynucleotidyl transferase dUTP nick end labeling; TUNEL) were assessed for the distinct experimental conditions tested as well as for in vivo control mouse testes. A validation of the RPPM procedure in the field of in vitro spermatogenesis was completed with assay and array robustness before a principal study concerning the evaluation of the impact of in vitro culture and cryopreservation procedures. The proportion of elongated spermatids and the total cell number per seminiferous tubule tended to be very different between the in vivo and in vitro conditions (P < 0.05), suggesting the presence of a beneficial regulation on the first spermatogenesis wave by intrinsic apoptosis (Caspase_9) and autophagy (Atg5) factors (P < 0.0003 and r2 = 0.74). Concerning the impact of culture media compositions, a basic medium (BM) composed of αMEM plus 10% KnockOut™ serum replacement and gentamicin supplemented with retinol (Rol) and vitamin E (Vit. E) was selected as the best culture medium for fresh 6.5 dpp tissue cultured during 30D with 27.7 ± 8.10% of seminiferous tubules containing elongated spermatids. Concerning the impact of cryopreservation procedures, SSV did not have any impact on the morphological parameters evaluated after culture in comparison to fresh tissue (FT) controls. The proportion of tubules with elongated spermatids on testicular explants cultured with BMRol+Vit. E was not different between SSV (6.6 ± 1.6%) and CSF (5.3 ± 1.9%); however, round spermatids were observed more frequently for SSV (19 ± 6.2%) than CSF (3.3 ± 1.9%, P = 0.0317). Even if the proportion of TUNEL-positive cells for BMRol+Vit. E was higher at D30 after SSV (4.12 ± 0.26%) than CSF (1.86 ± 0.12%, P = 0.0022) and FT (2.69 ± 0.33%, P = 0.0108), the DNA damages observed at the end of the culture (i.e. D30) were similar to respective 6.5 dpp controls. In addition, the relative protein level expression ratio of an apoptotic factor, the phosphorylated FADD on Fas, was reduced by 64-fold in vitrified testes cultured with BMRol+Vit. E. Furthermore, we found in this study that the StemPro®-34 SFM culture medium supplemented with growth factors (e.g. EGF, bFGF, GDNF and LIF) prevented the differentiation of spermatogonial stem cells in favor of a significant proliferation with a better architectural pattern than in vivo 6.5 dpp controls with an increase of seminiferous tubules area for FT (P = 0.0357) and CSF (P = 0.0317). Despite our promising results, the evaluation of apoptotic- and autophagic-related proteins was studied for a limited amount of proteins and on global testicular tissue. The data presented herein will help to improve apoptotic and autophagic understanding during the first spermatogenic wave. Moreover, our findings illustrate for the first time that, using finely-tuned experimental conditions, a testicular in vitro culture combined with proteomic technologies may significantly facilitate the study of cryopreservation procedures and in vitro culture evaluations. This study may also contribute to improve work on testicular tissues from pre-pubertal and adolescent cancer survivors. This study was supported by a Ph.D. grant from the Rouen Normandie Université and a financial support from 'la Ligue nationale contre le cancer' (both awarded to L.D.), funding from Institute for Research and Innovation in Biomedicine (IRIB), Agence de la Biomédecine, and co-supported by European Union and Région Normandie. Europe gets involved in Normandie with European Regional Development Fund (ERDF). The authors declare that there is no conflict of interest.

Dumont L ，Chalmel F ，Oblette A ，Berby B ，Rives A ，Duchesne V ，Rondanino C ，Rives N ... -  《-》