DNA methylation plays a critical role in spermatogenesis, as evidenced by the male sterility of DNA methyltransferase (DNMT) mutant mice. Here, we report a striking division of labor in the establishment of the methylation landscape of male germ cells and its functions in spermatogenesis: while DNMT3C is essential for preventing retrotransposons from interfering with meiosis, DNMT3A broadly methylates the genome-at the exception of DNMT3C-dependent retrotransposons-and controls spermatogonial stem cell (SSC) plasticity. By reconstructing developmental trajectories through single-cell RNA-seq and by profiling chromatin states, we found that Dnmt3A mutant SSCs can only self-renew and no longer differentiate due to spurious enhancer activation that enforces an irreversible stem cell gene program. We therefore provide a novel function for DNA methylation in male fertility: the epigenetic programming of SSC commitment to differentiation and to life-long spermatogenesis supply.
Somatic DNA methylation is established early during mammalian development, as embryonic cells transition from naive to primed pluripotency. This precedes the emergence of the three somatic germ layers, but also the segregation of the germline that undergoes genome-wide DNA demethylation after specification. While DNA methylation is essential for embryogenesis, the point at which it becomes critical during differentiation and whether all lineages equally depend on it is unclear. Using culture modeling of cellular transitions, we found that DNA methylation-free embryonic stem cells (ESCs) with a triple DNA methyltransferase knockout (TKO) normally progressed through the continuum of pluripotency states, but demonstrated skewed differentiation abilities towards neural versus other somatic lineages. More saliently, TKO ESCs were fully competent for establishing primordial germ cell-like cells (PGCLCs), even showing temporally extended and self-sustained capacity for the germline fate. By mapping chromatin states, we found that the neural and germline lineages are linked by a similar enhancer dynamics during priming, defined by common sets of methyl-sensitive transcription factors that fail to be decommissioned in absence of DNA methylation. We propose that DNA methylation controls the temporality of a coordinated neural-germline axis of preferred differentiation route during early development.
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