Depletion of glutathione during bovine oocyte maturation reversibly blocks the decondensation of the male pronucleus and pronuclear apposition during fertilization.

Oocyte-produced glutathione (the tripeptide gamma-glutamyl-cysteinyl-glycine; GSH) has been implicated in the reduction of disulfide bonds in the sperm nucleus during fertilization and thus in the development of the male pronucleus (PN). In this study, we show that the depletion of endogenous glutathione by 10 mM buthionine sulfoximine (BSO; specific inhibitor of GSH synthesis) during bovine oocyte maturation (24 h in vitro; represents prophase I to metaphase II transition in this species) blocks the formation of a male PN in > 85% of treated oocytes (vs. 6.8% in controls) and prevents the assembly of the sperm aster microtubules in approximately 35%. Consequently, the pronuclear migration and apposition do not occur. Ultrastructural observations suggest that the effect of BSO on pronuclear apposition might be due to incomplete disassembly of the sperm tail connecting piece, which normally leads to the release of the sperm centriole and to the reconstitution of the zygotic centrosome during fertilization. The sperm nucleus decondensation and migration blocks were reversed by the treatment of the GSH-depleted oocytes with 1-10 mM dithiothreitol (a disulfide bond-reducing agent) applied 8 h after insemination: 82% of these oocytes exhibited a normal male PN and pronuclear apposition 20 h after insemination. The pool of glutathione seems to be generated during oocyte maturation since > 80% of oocytes that were matured in the absence of BSO displayed a normal male PN, as apposed to a female PN, when inseminated and cultured in the presence of 10 mM BSO. These data suggest that the reduction of disulfide bonds in the sperm after incorporation is important for the formation of the male PN, as well as for the disassembly of the sperm tail connecting piece and pronuclear apposition. The lack of disulfide-reducing power in the GSH-depleted oocytes can be reversed by treatment with disulfide bond-reducing agents.