•We established the acetylproteome of capacitated human sperm.•Western blot was used to analyze the expression of lysine-acetylated proteins.•Synthetic peptides were used to verify proteomics data.•Experimental evidences show essential roles of acetylation in sperm functions.Protein lysine acetylation is a dynamic and reversible post-modification that is known to play diverse functions in eukaryotes. Nevertheless, the composition and function of non-histone lysine acetylation in gametes remain unknown. In humans, only capacitated sperm have the capacity to fertilize an egg. In the present study, we found complex composition of lysine acetylated proteins in capacitated human sperm. In vitro fertilization inhibition assay by anti-acetyllysine antibody showed essential roles of lysine acetylation in fertilization. And inhibition of lysine deacetylases, the histone deacetylases, by trichostatin A and nicotinamide, could significantly suppress sperm motility. After immunopurification enrichment of acetylpeptides with anti-acetyllysine antibody and high-throughput liquid chromatography–tandem mass spectrometry identification, we characterized 1206 lysine acetylated sites, corresponding to 576 lysine acetylated proteins in human capacitated sperm. Bioinformatics analysis showed that these proteins are associated with sperm functions, including motility, capacitation, acrosome reaction and sperm–egg interaction. Thus, lysine acetylation is expected to be an important regulatory mechanism for sperm functions. And our characterization of lysine acetylproteome could be a rich resource for the study of male fertility.Biological significanceMature sperm are almost transcriptionally and translationally silent, thus post-translational modifications play important roles in sperm functions. Till now, only two types of PTMs, phosphorylation and glycosylation, are well studied in normal human sperm based on large scale proteomics. In the present study, we established the acetylproteome of capacitated human sperm. Over 1000 lysine acetylated sites were identified. Bioinformatics analysis shows that lysine acetylated proteins participate in many biological events of sperm functions. We further provided functional data that the lysine acetylation is essential for sperm motility and fertilization using histone acetylase inhibitors and anti-acetyllysine antibody. These data can be strong evidences for the important function of lysine acetylation in human sperm.

Obesity impairs male fertility, providing evidence for a link between adipose tissue and reproductive function; however, potential consequences of adipose tissue paucity on fertility remain unknown. Lack of s.c. fat is a hallmark of Berardinelli–Seip congenital lipodystrophy type 2 (BSCL2), which is caused by mutations in BSCL2-encoding seipin. Mice with a targeted deletion of murine seipin model BSCL2 with severe lipodystrophy, insulin resistance, and fatty liver but also exhibit male sterility. Here, we report teratozoospermia syndrome in a lipodystrophic patient with compound BSCL2 mutations, with sperm defects resembling the defects of infertile seipin null mutant mice. Analysis of conditional mouse mutants revealed that adipocyte-specific loss of seipin causes progressive lipodystrophy without affecting fertility, whereas loss of seipin in germ cells results in complete male infertility and teratozoospermia. Spermatids of the human patient and mice devoid of seipin in germ cells are morphologically abnormal with large ectopic lipid droplets and aggregate in dysfunctional clusters. Elevated levels of phosphatidic acid accompanied with an altered ratio of polyunsaturated to monounsaturated and saturated fatty acids in mutant mouse testes indicate impaired phospholipid homeostasis during spermiogenesis. We conclude that testicular but not adipose tissue-derived seipin is essential for male fertility by modulating testicular phospholipid homeostasis.

N-Linked glycosylation, a type of post-translational modification, plays important roles in cell–cell recognition, adhesion, and interactions. Although N-linked glycosylated proteins in sperm are known to be important for gamete binding, little is known about the composition of these proteins, particularly glycosylation sites, in humans. In the present study, the use of glyco-FASP, coupled with the tandem mass spectrometry (MS/MS) method, led to the identification of 554 N-glycosylation sites and 297 N-glycosylated proteins in human sperm. Bioinformatics analysis revealed enrichment of proteins with functions in cell recognition and fertilization. Overall, about 91% of the human sperm N-glycosylated proteins were classified into “membrane”, “extracellular region”, and “lysosome” groups, based on subcellular localization annotation. Furthermore, glutathione peroxidase 4 (GPX4), a membrane glycoprotein identified in our glycoproteome, was shown to play a significant role in gamete interactions using the in vitro fertilization assay. Accordingly, we propose that characterization of the human sperm glycoproteome should effectively aid in clarifying the mechanisms of fertilization and provide a valuable resource for the future development of male contraceptives and diagnosis of male infertility.

The male gamete (sperm) can fertilize an egg, and pass the male genetic information to the offspring. It has long been thought that sperm had a simple protein composition. Efforts have been made to identify the sperm proteome in different species, and only about 1000 proteins were reported. However, with advanced mass spectrometry and an optimized proteomics platform, we successfully identified 4675 human sperm proteins, of which 227 were testis-specific. This large number of identified proteins indicates the complex composition and function of human sperm. Comparison with the sperm transcriptome reveals little overlap, which shows the importance of future studies of sperm at the protein level. Interestingly, many signaling pathways, such as the IL-6, insulin and TGF-beta receptor signaling pathways, were found to be overrepresented. In addition, we found that 500 proteins were annotated as targets of known drugs. Three of four drugs studied were found to affect sperm movement. This in-depth human sperm proteome will be a rich resource for further studies of sperm function, and will provide candidate targets for the development of male contraceptive drugs.Figure optionsDownload full-size imageDownload high-quality image (68 K)Download as PowerPoint slideHighlights► Proteomic analysis of human sperm indicates unexpected complex protein compositions. ► There is little overlap between sperm proteome and transcriptome. ► Three of four drugs targeting cilia proteins were found to affect sperm movement.

The acrosome reaction has long been thought to be induced by the zona pellucida. Here we report the identification and function of a novel human sperm glycosylphosphatidylinositol (GPI)-anchored membrane protein, NYD-SP8. The release of the protein during sperm-egg interaction and its binding to the cumulus, the first layer of egg investment, elicits cross-talk between the gametes and produces calcium dependant release of progesterone, which lead to the acrosome reaction. An in vivo mouse model of NYD-SP8 immunization is also established showing a reduced fertility rate. Thus, contrary to accepted dogma, our study demonstrates for the first time that, prior to reaching the zona pellucida, sperm may release a surface protein that acts on the cumulus cells leading to the acrosome reaction, which may be important for determining the outcome of fertilization.

Treatment with injectable testosterone undecanoate (TU) alone or in combination with oral levonorgestrel (LNG) resulted in marked decreases in sperm concentrations. In this study, we used proteomic analyses to examine the cellular/molecular events occurring in the human testis after TU or TU + LNG treatment. We conducted a global proteomic analysis of the human testicular biopsies before and at 2 weeks after TU alone or TU + LNG treatment. Proteins showing significant changes in expression were identified and analyzed. As a result, 17 and 46 protein spots were found with significant differential expression after the treatment with TU alone and TU + LNG, respectively. TU treatment changed the expression of heterogeneous nuclear ribonucleoprotein K (hnRNP K), proteasome inhibitor PI31 subunit (PSMF1), and superoxide dismutase [Mn] mitochondrial precursor (SOD2). These proteins inhibit “assembly”, induce cell death, and promote compensatory “cell survival” in the testis. After TU + LNG treatment, “proliferation/cell survival” and “apoptosis/death” were the predominant responses in the testis. TU + LNG treatment inhibited the expression of Prolyl 4-hydroxylase beta subunit (P4HB) and Annexin A2 (Annexin II). These proteins are involved in apoptosis and cell proliferation, respectively. TU + LNG treatment also enhanced the expression of SOD2 and Parvalbumin alpha (Pvalb). These two proteins may protect testicular cells against apoptosis/death and promote cell survival. In conclusion, TU and TU + LNG treatments suppress spermatogenesis through different pathways by changing the expression of different proteins. hnRNP K, PSMF1, SOD2, P4HB, Annexin II, and Pvalb, are key proteins that may be early molecular targets responsible for spermatogenesis suppression induced by hormone treatment.

•Men with GSTM1-null and GSTT1-present genotypes are susceptible to infertility.•Men with GSTM1-null are more susceptible to infertility when exposed to 4-n-OP.•Men with GSTM1-null and GSTT1-present are most susceptible when exposed to 4-n-OP.•Metabolomics analysis helps explain such susceptibilities.•Changed metabolites are involved in TCA-cycle which is related to male infertility.Infertility affects about 17% couples, and males contribute to half of the cases. Compared with independent effects of genetic and environmental factors, interactions between them help in the understanding of the susceptibility to male infertility. Thus, we genotyped 25 polymorphisms, measured 16 urinary chemical concentrations and explored interactions between gene-gene and gene-environment in 1039 Han Chinese using metabolomic analysis. We first observed that GSTT1 might interact with GSTM1 (Pinter = 6.33 × 10− 8). Furthermore, an interaction between GSTM1 and 4-n-octylphenol (4-n-OP) was identified (Pinter = 7.00 × 10− 3), as well as a 2-order interaction among GSTT1, GSTM1 and 4-n-OP (Pinter = 0.04). Subjects with GSTT1-present and GSTM1-null genotypes were susceptible to male infertility when exposed to 4-n-OP (OR = 14.05, 95% CI = 4.78–60.20, P = 2.34 × 10− 5). Most metabolites identified were involved in the tricarboxylic acid cycle. In conclusion, it is a novel study of the interaction on male infertility from the aspect of metabolomics.

This study investigated the expression and distribution of 2810408A11Rik in mouse testis and sperm, and explored its role in spermatogenesis and sperm function. The expression levels of 2810408A11Rik mRNA in multiple tissue samples were analyzed using bioinformatic resources and RT-PCR technique. A specific rabbit polyclonal antibody was prepared by prokaryotic expression of 2810408A11Rik recombinant protein and utilized for animal immunization. Western blotting, immunohistochemistry and immunofluorescence were used to detect the expression and distribution of 2810408A11Rik. The results of the bioinformatic analysis and RT-PCR showed that 2810408A11Rik mRNA was specifically expressed in mouse testis, and 2810408A11Rik protein included a protein phosphatase inhibitor domain. Western blotting assays, immunohistochemistry and immunofluorescence confirmed the expression of 2810408A11Rik protein in mouse testis, especially in post-meiosis round and long spermatids, and that it is localized in the acrosome and the post-nucleus area of sperm. Our findings suggest that 2810408A11Rik may play an important role in spermatogenesis, sperm capacitation and fertilization.

Spermatogenesis is a complex process of terminal differentiation by which mature sperms are generated, and it can be divided into three phases: mitosis, meiosis and spermiogenesis. In a previous study, we established a series of proteomic profiles for spermatogenesis to understand the regulation of male fertility and infertility. Here, we further investigated the localization and the role of flotillin-2 in spermiogenesis. Flotillin-2 expression was inves-tigated in the testis of male CD1 mice at various developmental stages of spermatogenesis by using Western blot-ting, immunohistochemistry and immunofluorescence. Flotillin-2 was knocked down in vivo in three-week-old male mice using intratesticular injection of small inhibitory RNA (siRNA), and sperm abnormalities were assessed three weeks later. Flotillin-2 was expressed at high levels in male germ cells during spermatogenesis. Flotillin-2 immunoreactivity was observed in pachytene spermatocytes as a strong dot-shaped signal and in round spermatids as a sickle-shaped distribution ahead of the acrosome. Immunofluorescence confirmed flotillin-2 was localized in front of the acrosome in round spermatids, indicating that flotillin-2 was localized to the Golgi apparatus. Knock-down of flotillin-2 in vivo led to a significant increase in head sperm abnormalities isolated from the cauda epidi-dymis, compared with control siRNA-injected testes. This study indicates that flotillin-2 is a novel Golgi-related protein involved in sperm acrosome biogenesis