Mammalian sperm carry a variety of highly condensed insoluble protein structures such as the perinuclear theca, the fibrous sheath and the outer dense fibers, which are essential to sperm function. We studied the role of cysteine rich secretory protein 2 (CRISP2); a known inducer of non-pathological protein amyloids, in pig sperm with a variety of techniques. CRISP2, which is synthesized during spermatogenesis, was localized by confocal immunofluorescent imaging in the tail and in the post-acrosomal region of the sperm head. High resolution localization by immunogold labeling electron microscopy (EM) of ultrathin cryosections revealed that CRISP2 was present in the perinuclear theca and neck region of the sperm head, as well as in the outer dense fibers and the fibrous sheath of the sperm tail. Interestingly, we found that under native, non-reducing conditions CRISP2 formed oligomers both in the tail and the head but with different molecular weights and different biochemical properties. The tail oligomers were insensitive to reducing conditions but nearly complete dissociated into monomers under 8 M urea treatment, while the head 250 kDa CRISP2 positive oligomer completely dissociated into CRISP2 monomers under reducing conditions. The head specific dissociation of CRISP2 oligomer is likely a result of the reduction of various sulfhydryl groups in the cysteine rich domain of this protein. The sperm head CRISP2 shared typical solubilization characteristics with other perinuclear theca proteins as was shown with sequential detergent and salt treatments. Thus, CRISP2 is likely to participate in the formation of functional protein complexes in both the sperm tail and sperm head, but with differing oligomeric organization and biochemical properties. Future studies will be devoted to the understand the role of CRISP2 in sperm protein complexes formation and how this contributes to the fertilization processes.
In a previous study we reported that porcine sperm cysteine rich secretory protein 2 (CRISP2) is localized in the post-acrosomal sheath (PAS)-perinuclear theca (PT) as reduction-sensitive oligomers. In the current study, the decondensation and removal of CRISP2 was investigated during in vitro sperm capacitation, both after induction of the acrosome reaction and after in vitro fertilization. Confocal immunofluorescent imaging revealed that additional CRISP2 fluorescence appeared on the apical ridge and on the equatorial segment (EqS) of the sperm head following capacitation, likely due to cholesterol removal. After an ionophore A23187 induced acrosome reaction, CRISP2 immunofluorescence disappeared from the apical ridge and the EqS area partly due to the removal of the acrosomal shroud vesicles but also partly due to its presence in a subdomain of EqS (EqSS). The fate of sperm head CRISP2 was further examined post-fertilization. In vitro matured porcine oocytes were co-incubated with boar sperm cells for 6-8 h and the zygotes were processed for CRISP2 immunofluorescent staining. Notably, decondensation of CRISP2, and thus of the sperm PT, occurred while the sperm nucleus was still fully condensed. CRISP2 was no longer detectable in fertilized oocytes in which sperm nuclear decondensation and paternal pronucleus formation were apparent. This rapid dispersal of CRISP2 in the PT is likely regulated by redox reactions for which its cysteine rich domain is sensitive. Reduction of disulfide bridges within CRISP2 oligomers may be instrumental for PT dispersal and PT elimination.
Study question Whether and how METTL5 regulates germ cell development during spermatogenesis. Summary answer METTL5 is required for spermiogenesis. Loss of METTL5 resulted in teratozoospermia and male infertility via reduced translation of acrosome and flagellum formation proteins. What is known already The roles of m6A modifications on mRNA in spermatogenesis have been extensively studied. It was reported that METTL5 knockout mice showed the brain development defect and sterility of 16-week male mice. However, the detailed mechanism of METTL5 affecting male fertility remains elusive. Study design, size, duration Mettl5 KO mice were kindly gifted from Prof. Shuibin Lin of The First Affiliated Hospital of Sun Yat-sen University. Heterozygotes of Mettl5 mice were used to generate Mettl5 homozygous knockout mice. The phenotype of KO mice was assessed. Ribosomal sequencing, proteomics analysis and further validation of protein translation were performed to explore the mechanism. Participants/materials, setting, methods Fertility assessment, sperm parameter analyses, sperm nuclear morphology analysis, Transmission electron microscopy (TEM), tissue Collection and histological analysis, protein extraction and western blot analysis, immunofluorescence studies, cDNA synthesis and qRT-PCR, in vitro fertilization (IVF) were used in this study. Main results and the role of chance Here we reported that methyltransferase-like 5 (METTL5) is involved in spermiogenesis as a methyltransferase mediating m6A modification on rRNA. Mettl5 knockout mice were infertile with teratozoospermia. The acrosome in the sperm head was absent with reduced sperm motility. Furthermore, the fertilization ability of sperm in the IVF experiment failed. Mechanistically, the level of rRNA m6A modification was significantly decreased in the testes of Mettl5 KO mice. The translational efficiency and protein levels of acrosome and flagellum formation proteins such as FSIP2, ODF2, GK2, PGK2, and AKAP4 were significantly reduced when METTL5 was depleted. Limitations, reasons for caution The METTL5 mutation in the patient with teratozoospermia was not examined in the present study Wider implications of the findings The rRNA m6A modification is also involved in regulating spermatogenesis by METTL5. This study highlights the critical role of rRNA epigenetic modifications during spermatogenesis and provides novel theoretical explanations for the m6A modifications. Trial registration number Not applicable
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