郭雪江，学者全讯担保网主页-全讯担保网

unlike most organs that mature during the fetal period, the male reproductive system reaches maturity only at puberty with the commencement of spermatogenesis. robust modelling of human testicular organogenesis in vitro would facilitate research into mechanisms of and factors affecting human spermatogenic failure and male fertility preservation in prepubertal tumor patients. here, we report successful recapitulation of human testicular organogenesis in vitro from fetal gonadal ridge. our model displayed the formation of mature seminiferous epithelium and self-renewing spermatogonia. remarkably, in vitro-derived haploid spermatids have undergone meiotic recombination, and showed increased genetic diversity as indicated by genetic analysis. moreover, these spermatids were able to fertilize oocytes and support subsequent blastocyst formation. the in vitro testicular organogenesis system described here will play an important role in elucidating the regulation of human testis development and maintaining male fertility in prepubertal cancer patients.

background: in mammals, regenerative therapy after myocardial infarction is hampered by the limited regenerative capacity of adult heart, whereas a transient regenerative capacity is maintained in the neonatal heart. systemic phosphorylation signaling analysis on ischemic neonatal myocardium might be helpful to identify key pathways involved in heart regeneration. our aim was to define the kinase-substrate network in ischemic neonatal myocardium and to identify key pathways involved in heart regeneration after ischemic insult. methods: quantitative phosphoproteomics profiling was performed on infarct border zone of neonatal myocardium, and kinase-substrate network analysis revealed 11 kinases with enriched substrates and upregulated phosphorylation levels, including checkpoint kinase 1 (chk1) kinase. the effect of chk1 on cardiac regeneration was tested on institute of cancer research cd1 neonatal and adult mice that underwent apical resection or myocardial infarction. results: in vitro, chk1 overexpression promoted whereas chk1 knockdown blunted cardiomyocyte proliferation. in vivo, inhibition of chk1 hindered myocardial regeneration on resection border zone in neonatal mice. in adult myocardial infarction mice, chk1 overexpression on infarct border zone upregulated mammalian target of rapamycin c1/ribosomal protein s6 kinase b-1 pathway, promoted cardiomyocyte proliferation, and improved cardiac function. inhibiting mammalian target of rapamycin activity by rapamycin blunted the neonatal cardiomyocyte proliferation induced by chk1 overexpression in vitro. conclusions: our study indicates that phosphoproteome of neonatal regenerative myocardium could help identify important signaling pathways involved in myocardial regeneration. chk1 is found to be a key signaling responsible for neonatal regeneration. myocardial overexpression of chk1 could improve cardiac regeneration in adult hearts by activating the mammalian target of rapamycin c1/ribosomal protein s6 kinase b-1 pathway. thus, chk1 might serve as a potential novel target in myocardial repair after myocardial infarction.

flagellum in sperm is composed of over 200 different proteins and is essential for sperm motility. in particular, defects in the assembly of the radial spoke in the flagellum result in male infertility due to loss of sperm motility. however, mechanisms regulating radial spoke assembly remain unclear in metazoans. here, we identified a novel drosophila protein radial spoke binding protein 15 (rsbp15) which plays an important role in regulating radial spoke assembly. loss of rsbp15 results in complete lack of mature sperms in seminal vesicles (svs), asynchronous individualization complex (ic) and defective “9 2” structure in flagella. rsbp15 is colocalized with drsph3 in sperm flagella, and interacts with drsph3 through its dd_r_pka superfamily domain which is important for the stabilization of drsph3. moreover, loss of drsph3, as well as drsph1, drsph4a and drsph9, showed similar phenotypes to rsbp15ko mutant. together, our results suggest that rsbp15 acts in stabilizing the radial spoke protein complex to anchor and strengthen the radial spoke structures in sperm flagella.

purpose to investigate the differences in protein expression between dpy19l2‐deficient human globozoospermia and normozoospermia. experimental design human sperm samples from three globozoospermic donors with dpy19l2 deletion and three normal controls are subjected to tmt quantitative technology. spesp1, hist1h4a, and lyzl1 are randomly selected for western blotting analysis. go annotations are performed using the database for annotation, visualization, and integrated discovery. results a total of 2567 proteins are identified, of which 2510 proteins are quantified, and 491 are differentially expressed (fold‐change > 2), with 370 upregulated and 121 downregulated in globozoospermic patients. the levels of several important proteins, including spaca 1, izumo1, zpbp1, and plcz1, are decreased in globozoospermic sperm. bioinformatics analysis indicates the dpy19l2‐deficient sperm presented molecular defects in acrosome, chromatin, sperm–egg interaction, and fertilization. conclusions and clinical relevance the present study is the first to analyze total globozoospermia with dpy19l2 deletion using high‐throughput proteomics. this study may provide insights into the mechanism of globozoospermia.

the characteristic tadpole shape of sperm is formed from round spermatids via spermiogenesis, a process which results in dramatic morphological changes in the final stage of spermatogenesis in the testis. protein phosphorylation, as one of the most important post‐translational modifications, can regulate spermiogenesis; however, the phosphorylation events taking place during this process have not been systematically analyzed. in order to better understand the role of phosphorylation in spermiogenesis, large‐scale phosphoproteome profiling is performed using imac and tio2 enrichment. in total, 13 835 phosphorylation sites, in 4196 phosphoproteins, are identified in purified mouse spermatids undergoing spermiogenesis in two biological replicates. overall, 735 testis‐specific proteins are identified to be phosphorylated, and are expressed at high levels during spermiogenesis. gene ontology analysis shows enrichment of the identified phosphoproteins in terms of histone modification, cilium organization, centrosome and the adherens junction. further characterization of the kinase‐substrate phosphorylation network demonstrates enrichment of phosphorylation substrates related to the regulation of spermiogenesis. this global protein phosphorylation landscape of spermiogenesis shows wide phosphoregulation across a diverse range of processes during spermiogenesis and can help to further characterize the process of sperm generation. all ms data are available via proteomexchange with the identifier pxd011890.

mitofusins (mfn) are the important regulators of mitochondrial organization in mammalian cells; however, their roles during oocyte development remain unknown. in the present study, we generated mice with oocyte-specific knockout of mfn1 or mfn2 (mfn1fl/fl;zp3-cre or mfn2fl/fl;zp3-cre). we report that deletion of mfn1, but not mfn2, in oocytes leads to female mice sterility, associated with the defective folliculogenesis and impaired oocyte quality. in specific, follicles are arrested at secondary stage in mfn1fl/fl;zp3-cre mice, accompanying with the reduced proliferation of granulosa cells. moreover, alterations of mitochondrial structure and distribution pattern are readily observed in mfn1-null oocytes. consistent with this, mitochondrial activity and function are severely disrupted in oocytes from mfn1fl/fl;zp3-cre mice. in addition, the differentially expressed genes in mfn1-deleted oocytes are also identified by whole-transcriptome sequencing. in sum, these results demonstrate that mfn1-modulated mitochondrial function is essential for oocyte development and folliculogenesis, providing a novel mechanism determining female fertility.

asthenozoospermia, in which sperm motility is affected, is one of the primary causes of male infertility. however, the exact mechanism responsible for the defective motility remains unknown. it is important to identify the precise proteins or pathways involved in sperm motility. the present study analyzed five asthenozoospermic sperm samples and five healthy controls using tmt-based quantitative method and identified 152 differentially expressed proteins, with 84 upregulated and 68 downregulated in asthenozoospermia. four proteins (gpi, mdh1, pgam1 and pgam2) were found in several over-represented energy metabolism pathways using bioinformatics analysis. glucose-6-phosphate isomerase (gpi), a rate-limiting enzyme converting glucose-6-phosphate to fructose-6-phosphate, was found to be significantly decreased in asthenozoospermia by western blotting and elisa on an extended sample size. furthermore, substitution of glucose with fructose-6-phosphate significantly promoted asthenozoospermic sperm motility in vitro. taken together, our results suggest that the poor motility of sperm in asthenozoospermia may partly result from defects in gpi-associated energy metabolism. significance to identify the key proteins or pathways involved in sperm motility, the accurate tmt-based quantitative method was applied to characterize protein profiles of asthenozoospermic sperm. gpi, an enzyme involved in energy metabolism, was found to be differentially abundant, and validated by extended sample analysis. the supplement of the product of gpi, fructose-6-phosphate, could significantly improve sperm motility. our study could provide new insights into the molecular basis of sperm motility and the improvement of motility in asthenozoospermia.

although crispr/cas9 has been widely used to generate knockout mice, two major limitations remain: the founders usually carry a mixture of genotypes, and mosaicism harboring multiple genotypes. therefore, it takes a long time to get homozygous mutants. recently developed base editing (be) system, which introduces c-to-t conversion without double strand dna cleavage, has been used to introduce artificial stop codons (i-stop) to prematurely terminate translation, providing a cleaner strategy for genome engineering. using this strategy, we generated cd160 ko and vista/cd160 double ko mice by microinjection of a single sgrna targeting cd160 and a mixture of sgrnas targeting vista and cd160, respectively. the be system induced stop efficiently in mouse embryos and consequently in founder mice without detectable off-target. most interestingly, the majority of the mutants harbor same genetic modifications, indicating we generated isogenic single and multiplex gene mutant mice by be-induced stop. we also obtained homozygous mutant mouse in f1 mice, demonstrating the accelerated strategy in generating animal models.

meiosis is a special type of cellular renovation that involves 2 successive cell divisions and a single round of dna replication. two major degradation systems, the autophagy-lysosome and the ubiquitin-proteasome, are involved in meiosis, but their roles have yet to be elucidated. here we show that autophagy mainly affects the initiation of meiosis but not the nuclear division. autophagy works not only by serving as a dynamic recycling system but also by eliminating some negative meiotic regulators such as ego4 (ynr034w-a). in a quantitative proteomics study, the proteasome was found to be significantly upregulated during meiotic divisions. we found that proteasomal activity is essential to the 2 successive meiotic nuclear divisions but not for the initiation of meiosis. our study defines the roles of autophagy and the proteasome in meiosis: autophagy mainly affects the initiation of meiosis, whereas the proteasome mainly affects the 2 successive meiotic divisions.

tandem proteomic strategies based on large‐scale and high‐resolution mass spectrometry have been widely applied in various biomedical studies. however, protein sequence databases and proteomic software are continuously updated. proteomic studies should not be ended with a stable list of proteins. it is necessary and beneficial to regularly revise the results. besides, the original proteomic studies usually focused on a limited aspect of protein information and valuable information may remain undiscovered in the raw spectra. several studies have reported novel findings by reanalyzing previously published raw data. however, there are still no standard guidelines for comprehensive reanalysis. in the present study, we proposed the concept and draft framework for complementary proteomics, which are aimed to revise protein list or mine new discoveries by revisiting published data.