Project description:Testis immune privilege is thought to be mediated by somatic cells. However, it is not strong enough to protect allogeneic spermatogonial stem cells (SSCs) transplanted into the seminiferous tubules. Here we report successful production of allogeneic offspring by inducing PD-L1 in SSCs. Activation of self-renewal division induced PD-L1 and B7-H3 expression in cultured SSCs, which produced sperm after allogeneic transplantation. While B7-H3 depletion did not influence colonization, PD-L1 depletion prevented donor-derived spermatogenesis. PD-L1 expression was induced by BCL6B via reactive oxygen species (ROS) generation, suggesting that self-renewal stimulation confers immune privilege by ROS. In contrast, reduced ROS or Mapk14 deficiency downregulated PD-L1 expression. Allogeneic offspring were produced by SSC transplantation into congenitally infertile mice and busulfan-treated wild-type mice. Therefore, SSCs can escape rejection when their self-renewal division is stimulated.

Project description:Induced expression of PD-L1 in spermatogonial stem cells by self-renewal division allows allogeneic offspring production

Project description:Induced expression of PD-L1 in spermatogonial stem cells by self-renewal division allows allogeneic offspring production [Sequencing]

Project description:Induced expression of PD-L1 in spermatogonial stem cells by self-renewal division allows allogeneic offspring production [microarray]

Project description:This is a mathematical model that describes the interactions between cytotoxic T cells and tumor cells as influenced by B7-H1 (PD-L1) activity, with a focus on how B7-H1 affects cancer cells apoptosis.

Project description:Reactive oxygen species (ROS) play critical roles in self-renewal division for various stem cell types. However, it remains unclear how ROS signals are integrated with self-renewal machinery. Here we report that the MAPK14/MAPK7/BCL6B pathway creates a positive feedback loop to drive spermatogonial stem cell (SSC) self-renewal via ROS amplification. The activation of MAPK14 induced MAPK7 phosphorylation in cultured SSCs, and targeted deletion of Mapk14 or Mapk7 resulted in significant SSC deficiency after spermatogonial transplantation. The activation of this signaling pathway not only induced Nox1 but also increased ROS levels. Chemical screening of MAPK7 targets revealed many ROS-dependent spermatogonial transcription factors, of which BCL6B was found to initiate ROS production by increasing Nox1 expression via ETV5-induced nuclear translocation. Because hydrogen peroxide or Nox1 transfection also induced BCL6B nuclear translocation, our results suggest that BCL6B initiates and amplifies ROS signals to activate ROS-dependent spermatogonial transcription factors by forming a positive feedback loop.

Project description:Transcriptional profiling of mouse spermatogonial stem cells (SSCs) comparing control untreated SSCs with SSCs with exogenous FGF2 withdrawn and FGFR inhibitor SU5402 supplemented (-F+S). Results provide insight into the mechanisms of FGF2-supported in vitro self-renewal of SSCs. Two-condition experiment, SSCs-F+S vs. SSCs. Biological replicates: 4 control replicates, 4 -F+S replicates.

Project description:Reactive oxygen species (ROS) play critical roles in self-renewal division for various stem cell types. However, it remains unclear how ROS signals are integrated with selfrenewal machinery. Here we report that the MAPK14/MAPK7/BCL6B pathway creates a positive feedback loop to drive spermatogonial stem cell (SSC) self-renewal via ROS amplification. The activation of MAPK14 induced MAPK7 phosphorylation in cultured SSCs, and targeted deletion of Mapk14 or Mapk7 resulted in significant SSC deficiency after spermatogonial transplantation. The activation of this signaling pathway not only induced Nox1 but also increased ROS levels. Chemical screening of MAPK7 targets revealed many ROS-dependent spermatogonial transcription factors, of which BCL6B was found to initiate ROS production by increasing Nox1 expression via ETV5-induced nuclear translocation. Because hydrogen peroxide or Nox1 transfection also induced BCL6B nuclear translocation, our results suggest that BCL6B initiates and amplifies ROS signals to activate ROS-dependent spermatogonial transcription factors by forming a positive feedback loop.

Project description:The spermatogonial stem cells (SSCs) niche is critical for SSC maintenance and the subsequent spermatogenesis. Numerous reproductive hazards impair the SSC niche, thereby result in aberrant SSC self-renewal and male infertility. However, promising agents targeting the impaired SSC niche to promote SSC self-renewal are still limited. Here, we screen out and assess the effects of Lovastatin on the self-renewal of mouse spermatogonial stem cells (mSSCs). Mechanistically, Lovastatin promotes the self-renewal of mSSCs and inhibits its inflammation and apoptosis through the regulation of isoprenoid intermediates. Likewise, other statins  exhibit similar effects on SSC self-renewal. Remarkably, the treatment by Lovastatin could promote the self-renewal of mSSCs in the male gonadotoxicity model generated by busulfan injection. Noteworthy, we demonstrate that Lovastatin could significantly enhance the self-renewal of in vitro cultured primate SSCs. Collectively, our findings uncover that lovastatin could promote the self-renewal of both murine and primate SSCs and have implications for the treatment of certain male infertility using small compounds.

Project description:To better understand human spermatogonial stem cells (SSCs), we profiled their transciptome and epigenome, which revealed the mechanism how human SSCs regulates their self-renewal versus differentiation dermination, as well as how latent pluripotency is established in human SSCs. Remarkly, we discovered signaling pathways (e.g. LIF, BMP, WNT) that differentially regulated self-renewal vesus differentiation in SSCs. We also discovered that SSCs repress core pluripotent factors (Sox2, Pou5f1 and Nanog) yet activate ancillary factors (e.g. Klf4, Mbd3, Tcf3, Sall4) transcriptionally and epigenetically.