ABSTRACT: Soon after fertilization, the zygotic epigenome undergoes a dramatic and rapid establishment process that is essential for the initiation of embryonic development. In such genome-wide epigenetic conversion, upstream regulation by metabolic pathways that supply essential substrates and cofactors is frequently observed in various cell types. However, the specific involvement of metabolic pathways in orchestrating epigenetic establishment within zygotes has remained largely unclear. In this study, we elucidated that the serine-glycine one-carbon (SGOC) metabolic pathway, which synthesizes S-Adenosylmethionine (SAM), a critical methyl group donor, has an essential role in regulating histone methylation in zygotes. Inhibition of the SGOC pathway led to pronounced zygotic arrest accompanied by disrupted histone methylations, specifically in the male pronuclei (PN). Notably, both zygotic arrest and disrupted histone methylation were rescued by inhibiting minor ZGA, indicating that minor ZGA regulated by the SGOC pathway functions upstream of histone methylation in the male PNs. SGOC pathway inhibition also caused the DNA damage exclusively in the male PN. Remarkably, enucleation of the male PN with impaired epigenome and DNA integrity rescued the zygotic arrest. Round spermatid injection-derived zygotes (ROSI-zygotes), which retain paternal histone methylations in the male PN, showed the greater resistance to CBR-induced paternal DNA damage than intracytoplasmic sperm injected zygotes (ICSI-zygotes). These findings demonstrate that the SGOC pathway safeguards paternal genome integrity in mouse zygotes by regulation of histone methylation via minor ZGA.