Haploinsufficiency of the paternal-effect gene Dnmt3L results in transient DNA hypomethylation in progenitor cells of the male germline.

STUDY QUESTION: How does haploinsufficiency of the paternal-effect gene Dnmt3L affect DNA methylation establishment and stability in the male germline? SUMMARY ANSWER: Reduced expression of DNMT3L in male germ cells, associated with haploinsufficiency of the paternal-effect gene Dnmt3L, results in abnormal hypomethylation of prenatal germline progenitor cells. WHAT IS KNOWN ALREADY: The DNA methyltransferase regulator Dnmt3-Like (Dnmt3L) is a paternal-effect gene required for DNA methylation acquisition in male germline stem cells and their precursors. In males, DNMT3L deficiency causes meiotic abnormalities and infertility. While Dnmt3L heterozygous males are fertile, they have abnormalities in X chromosome compaction and postmeiotic gene expression and sire offspring with sex chromosome aneuploidy. It has been proposed that the paternal effects of Dnmt3L haploinsufficiency are due to epigenetic defects in early male germ cells. DNA methylation is an essential epigenetic modification essential for normal germ cell development. Since patterns of DNA methylation across the genome are initially acquired in prenatal male germ cells, perturbations in methylation could contribute to the epigenetic basis of the paternal effects in Dnmt3L(+/-) males. STUDY DESIGN, SIZE, DURATION: This is a cross-sectional study of DNA methylation in Dnmt3L(+/+) versus Dnmt3L(+/-) male germ cells collected from mice at 16.5 days post-coitum (dpc), Day 6 and Day 70 (n = 3 per genotype, each n represents a pool of 2-20 animals). Additionally, DNA methylation was compared in enriched populations of spermatogonial stem cells (SSC)/progenitor cells from Dnmt3L(+/+) and Dnmt3L(+/-) males following ≈ 2 months in culture. MATERIALS, SETTING, METHODS: DNA methylation at intergenic loci along chromosomes 9 and X was examined by quantitative analysis of DNA methylation by real-time polymerase chain reaction at the time of initial acquisition of epigenetic patterns in the prenatal male germline (16.5 dpc) and compared with patterns in early post-natal spermatogonia (Day 6) and in spermatozoa in mice. DNA methylation status at CpG-rich sites across the genome was assessed in spermatogonial precursors from Day 4 male mice using restriction landmark genomic scanning. MAIN RESULTS AND THE ROLE OF CHANCE: At 16.5 dpc, 42% of intergenic loci examined along chromosome 9 and 10% of those along chromosome X were hypomethylated in Dnmt3L heterozygotes. By Day 6 and in spermatozoa, germ cell DNA methylation was similar in heterozygous and wild-type mice. DNA methylation stability of acquired patterns in wild-type and Dnmt3L(+/-) SSC/progenitor cell culture was analyzed at numerous loci across the genome in cells cultured in vitro and collected at passages 6-28. While the methylation of most loci was stable in culture over time, differences at ≈ 1% of sites were found between Dnmt3L(+/-) and Dnmt3L(+/+) cultures. LIMITATIONS, REASONS FOR CAUTION: Evaluation of DNA methylation in SSCs can only be performed after a period of culture limiting the investigation to changes observed during culture when compared with DNA methylation differences between genotypes that could be present at the beginning of culture establishment. WIDER IMPLICATIONS OF THE FINDINGS: The DNA methylation defects described here in prenatal male germline progenitor cells and SSC culture are the earliest epigenetic perturbations yet identified for a mammalian paternal-effect gene and may influence downstream epigenetic events in germ cells at later stages of development. Together, the results provide evidence of a 'window' of susceptibility in prenatal male germ cell precursors for the induction of epimutations due to genetic perturbations and, potentially, in utero environmental exposures.

The efficiency of male fertility restoration is dependent on the recovery kinetics of spermatogonial stem cells after cytotoxic treatment with busulfan in mice.

BACKGROUND: Spermatogonial stem cells (SSCs) are the foundation of spermatogenesis and represent a crucial resource for male fertility restoration. It has not been well documented, however, whether the recovery of SSC population size after cytotoxic damage associates with the kinetics of male fertility restoration. We addressed this issue using the mouse as a model. METHODS: Following single injections of busulfan at 15, 30 or 45 mg/kg into male mice, we examined their ability to sire offspring at different times by natural mating and determined SSC numbers using spermatogonial transplantation. We measured testis physiological parameters (testis weights, sperm counts, serum and intratesticular testosterone levels, and histological assessments of spermatogenic recovery) and quantified the expression of glial-cell-line-derived neurotrophic factor (GDNF) transcripts. RESULTS: Regardless of busulfan doses, fertility was lost within 4 weeks after treatment, while more than 95% of SSCs were lost within 3 days. Fertility and SSC numbers gradually recovered with time, but the recoveries were delayed at higher busulfan doses. Interestingly, SSC numbers reached ∼30% of before-treatment levels by 4 weeks prior to the time of fertility restoration, across the dose groups. Sperm counts were ∼20% of before-treatment levels at the onset of fertility restoration, regardless of busulfan doses. We detected a significant increase in total GDNF mRNA per testis immediately after busulfan treatment. CONCLUSIONS: The loss and restoration of fertility after busulfan treatment are direct consequences of SSC loss and expansion. Our data suggest that there is a threshold in SSC numbers that allows for male fertility restoration and that the testicular somatic environment responds rapidly and temporarily to the loss of spermatogonia, including SSCs, by altering GDNF mRNA levels. This study provides fundamental information to clinically apply SSCs for male fertility restoration in the future.