小RNA分子与精子发生调控

近来研究发现小RNA(small RNAs)可作为转录后及翻译水平上基因表达调节的重要调节因子,利用小RNA来阐明调节精子发生的分子机制取得了显著进展。这些小RNA主要分为3类,即小干扰RNA(siRNA)、微小RNA(miRNA)以及与piwi蛋白相互作用的RNA(piRNA)。在减数分裂和精子发生过程中,小RNA具有多种生物学功能,如利用siRNA体外转染或体内注射来敲低特定基因从而研究该基因在精子发生过程中的作用;miRNA可能参与精子发生中有丝、减数及后减数分裂阶段的基因表达调节;piRNA主要参与调节雄性生殖细胞减数及后减数分裂的过程,在精子发生中起抑制反转录转座子(retrotransposons)的作用。文章对小RNAs合成、作用机制、功能及展望等最新进展进行了综述。     

哺乳动物精子发生中减数分裂的起始

生殖细胞的发生、增殖和分化是生命科学领域研究的重要课题之一. 生殖是所有动物赖以生存的基础,精子发生是完成繁殖所必须经历的过程,其最终目的是源源不断地产生单倍体精子.精子发生过程本身是一个复杂特殊的细胞增殖与分化过程,其中减数分裂是精子发生最重要的步骤,但关于减数分裂如何精确起始的分子机制仍知之甚少.已有报道发现,维甲酸（RA）调控Stra8可能是哺乳动物减数分裂起始的机制之一,Nanos2、Boule对RA-Stra8通路具有重要的调控作用. 本文对哺乳动物精子发生中减数分裂起始的相关研究进展进行综述.     

牛精原干细胞体外分化潜能的分析

家畜精原干细胞操作的核心技术是精原干细胞(spermatogonial stem cells,SSCs)的长期培养。至今家畜精原干细胞的长期培养方法还没有完善。其中的一个原因是缺乏简便有效的家畜精原干细胞生物活性鉴定手段。该研究的目的是建立一种牛精原干细胞生理潜能的体外分析方法,用于体外培养的牛精原干细胞的生物活性鉴定。首先培养牛精原干细胞,进而用干细胞因子(stem cell factor,SCF)对体外长期培养的牛精原干细胞进行诱导分化。在诱导分化过程中对细胞进行显微观察,并且用免疫荧光染色法鉴定分化的细胞。观察结果显示,经过诱导培养8 d后,牛精原干细胞形态发生了明显改变;细胞的运动行为显示出精母细胞特有的特征。免疫荧光染色结果显示,分化的细胞表达精母细胞的标记基因Scp3。上述结果例证了体外培养的牛精原干细胞具有分化为精母细胞的潜能。该研究建立了牛SSCs体外诱导分化的分析方法,用于鉴定体外培养的牛SSCs的生理潜能。但是体外诱导培养条件不能满足牛SSCs减数分裂的全部要求,导致出现一些不完全符合精母细胞特征的现象。诱导分化培养液尚需改进。     

microRNA在精子发生中的作用

微RNA(microRNAs, miRNAs)是一类广泛存在于真核细胞内起调控作用的小非编码RNA,物种间保守性强。miRNAs通过靶向mRNA,介导mRNA降解或翻译抑制,在各种细胞中广泛参与包括蛋白质翻译调控在内的基因表达的转录后调控。精子发生是精原干细胞(SSCs)增殖分化为成熟精子的复杂过程,包括SSCs有丝分裂、精母细胞减数分裂和精子细胞变形分化三个主要阶段。精子生成很大程度上取决于转录后调控,miRNAs是这个事件的重要调控因子。目前已发现大量miRNAs在生精细胞中表达,其中许多还高度表达、特异性表达或优先表达,并对生精细胞的增殖、分化和发育发挥至关重要的作用。本文主要就miRNAs的发现和功能、精子发生过程、miRNAs调节精子发生的重要性以及精子发生三个不同发育阶段中miRNAs的具体调控作用进行简要综述,以期为探索雄性不育等疾病的预防和精准化治疗提供理论依据,并在此基础上展望了未来本领域可能的研究方向。     

哺乳动物精原干细胞自我更新调控的研究进展

精原干细胞（spermatogonial stem cells,SSCs）具有自我更新和分化的功能,这两种功能的平衡协调不仅能维持其自身数量的稳定,还能满足雄性动物精子生成的需要。近几年,由于细胞培养技术、基因工程技术、生殖细胞移植技术的建立和完善,使SSCs自我更新调控机制的研究取得了许多突破,主要体现在蛋白调控因子和微小RNA分子以及DNA甲基化新作用的发现等方面。该文将着重围绕调控SSCs自我更新的外源性细胞因子和内源性转录因子等蛋白因子进行综述,以期为哺乳动物SSCs的深入研究提供借鉴。     

小鼠M1细胞中ctcf基因的敲降及其对c-myb基因表达的影响

c-Myb转录因子能够调控造血细胞的分化和增殖,其转录调控受到多种机制影响。本实验室前期研究发现在小鼠急性髓系白血病M1 (Mouse myeloid leukemia)细胞中CTCF结合在c-myb基因上游调控区域,但是具体机制仍然不清楚。为了探索CTCF对c-myb基因转录调控的影响,本研究设计了针对小鼠ctcf基因的shRNA (Small hairpin RNA)干扰序列,并将其连接到载体pLKO.1中,得到ctcf-shRNA慢病毒干扰载体,测序验证后,与慢病毒包装质粒pCMV-DR8.91、pCMV-VSVG共转染至HEK293T细胞中,经HEK293T细胞包装病毒感染小鼠M1细胞,通过RT-qPCR和Western blotting实验分别检测ctcf基因被干扰后,c-myb基因在mRNA水平和蛋白水平的表达变化。RT-qPCR实验结果表明,含有ctcf-shRNA序列的慢病毒感染M1细胞后,ctcf基因mRNA表达量与对照组相比明显下降,同时检测到ctcf基因被敲降之后,c-myb基因的mRNA表达随之降低,Western blotting实验结果表明,当ctcf基因的表达被干扰之后,c-Myb蛋白的表达也明显下降。本研究发现c-myb基因的表达受到CTCF的调控,为进一步研究c-myb基因的表达调控机制提供实验依据。     

维甲酸诱导精原干细胞分化过程中DNA甲基转移酶表达研究

精原干细胞(spermatogonial stem cells,SSCs)是雄性哺乳动物体内能进行自我更新并通过精子发生将亲代遗传信息传递给子代的一类细胞。多项研究表明,维甲酸(retinoic acid,RA)可诱导SSCs分化,启动减数分裂。目前,关于维甲酸诱导SSCs体外分化的分子机制已取得一定进展,但此过程的DNA甲基化调控机制尚未探索。DNA甲基转移酶(DNA methyltransferases,Dnmts)催化DNA甲基化,研究SSCs分化前后Dnmts的表达变化将有助于本研究从表观遗传层面理解维甲酸诱导的SSCs分化过程。因此,在本研究中,首先通过两步酶消化法和免疫磁珠法从小鼠睾丸组织中分离纯化SSCs并建立细胞系。该细胞系在体外传代超过60代,并且表达Oct4、Plzf、Etv5、Dazl和Mvh等标志物。然后,本研究通过探索维甲酸诱导条件,建立了SSCs的体外分化体系。经维甲酸处理后,对SSCs自我更新起决定作用的转录因子Plzf及其共表达基因Oct4的表达下降,而分化相关基因(Stra8,c-Kit)表达上调。最后,本研究对SSCs分化前后Dnmts表达进行检测。检测显示与正常组SSCs比较,维甲酸处理组SSCs中Dnmt1、Dnmt3a表达下调。该发现初步表明Dnmt1、Dnmt3a在维甲酸诱导SSCs体外分化过程中起调控作用,为阐述维甲酸如何诱导SSCs分化的分子机制提供了新的证据。     

DAZ家族新成员BOULE蛋白的结构与功能

BOULE蛋白是2001年发现的DAZ家族的新成员,是人类精子发生过程中减数分裂的关键调控因子. BOULE基因表达的改变或BOULE蛋白的缺乏可引起减数分裂阻滞和精子生成障碍,从而导致无精子症并产生不育. BOULE蛋白的一级结构中含有DAZ家族的特征结构域,包括DAZ重复和RNA结合域（RBM）,因此,将其列为继DAZ、DAZL之后DAZ家族的第3个成员.本文对BOULE的发现过程、结构和定位进行了总结回顾,并重点介绍了其在精子发生减数分裂中的作用及其作用机制.     

LIN28调控哺乳动物干细胞和生殖细胞发育分化的研究概述

Lin28为一种保守的RNA结合蛋白质,在细胞代谢、细胞周期和多能性维持中具有重要调控作用。近年来,发现Lin28在哺乳动物原始生殖细胞形成和分化、精原干细胞的形成、自我更新和分化调控中具有不可替代的作用。本文对Lin28作用及其对哺乳动物干细胞和生殖细胞发育分化影响的研究进展作一简述。     

哺乳动物精原干细胞的研究进展

精原干细胞是雄性体内可以永久维持的成体干细胞,它具有自我更新和分化的能力,保证了雄性个体生命过程中精子发生的持续进行,从而实现将遗传信息传递给下一代。精原千细胞不仅可在体外实现长期培养或诱导分化为各级生精细胞,并且可在特定条件下将其诱导去分化成为多能性干细胞。同样,这种多能性干细胞如同胚胎干细胞,可被诱导形成造血细胞、神经元细胞、肌细胞等多种类型细胞。鉴于其独具的生物学特性,精原干细胞在揭示精子的发生机制、治疗雄性不育和转基因动物等研究中具有重要价值。该文对精原干细胞在生物学特性、纯化培养、移植、体外诱导分化及其相关调控方面的各项研究进行了小结,综述了近年来的研究历程和最新研究成果。     

Nanopore sequencing reveals full-length Tropomyosin 1 isoforms and their regulation by RNA-binding proteins during rat heart development

Alternative splicing (AS) contributes to the diversity of the proteome by producing multiple isoforms from a single gene. Although short-read RNA-sequencing methods have been the gold standard for determining AS patterns of genes, they have a difficulty in defining full-length mRNA isoforms assembled using different exon combinations. Tropomyosin 1 (TPM1) is an actin-binding protein required for cytoskeletal functions in non-muscle cells and for contraction in muscle cells. Tpm1 undergoes AS regulation to generate muscle versus non-muscle TPM1 protein isoforms with distinct physiological functions. It is unclear which full-length Tpm1 isoforms are produced via AS and how they are regulated during heart development. To address these, we utilized nanopore long-read cDNA sequencing without gene-specific PCR amplification. In rat hearts, we identified full-length Tpm1 isoforms composed of distinct exons with specific exon linkages. We showed that Tpm1 undergoes AS transitions during embryonic heart development such that muscle-specific exons are connected generating predominantly muscle-specific Tpm1 isoforms in adult hearts. We found that the RNA-binding protein RBFOX2 controls AS of rat Tpm1 exon 6a, which is important for cooperative actin binding. Furthermore, RBFOX2 regulates Tpm1 AS of exon 6a antagonistically to the RNA-binding protein PTBP1. In sum, we defined full-length Tpm1 isoforms with different exon combinations that are tightly regulated during cardiac development and provided insights into the regulation of Tpm1 AS by RNA-binding proteins. Our results demonstrate that nanopore sequencing is an excellent tool to determine full-length AS variants of muscle-enriched genes.     

Identification of an intermediate state as spermatogonial stem cells reprogram to multipotent cells

The aim of this study was to understand the mechanisms that allow mSSC lines to be established from SSCs. Small, multilayer clumps of SSCs formed during two to four weeks of in vitro culture and were then transferred to MEF feeders. Small, round, monolayer colonies containing cells destined to convert to mSSCs, designated as intermediate state SSCs (iSSCs), first appeared after two to three passages. During an additional nine passages (47–54 days) under the same culture conditions, iSSCs slowly proliferated and maintained their morphology. Ultimately, a cell type with an ES-like morphology (mSSC) appeared from the iSSC colonies, and two mSSC cell lines were established. The mSSCs had a high proliferative potential in serum-free ES culture medium and have been successfully maintained since their first establishment (> 12 months). We also compared the specific characteristics of iSSCs with those of SSCs and mSSCs using immunocytochemistry, FACS, RT-PCR, DNA methylation, and miRNA analyses. The results suggest that iSSCs represent a morphologically distinct intermediate state with characteristic expression patterns of pluripotency-related genes and miRNAs that arise during the conversion of SSCs into mSSCs. Our results suggest that iSSCs could be a useful model for evaluating and understanding the initiation mechanisms of cell reprogramming.     

Expression of RNA-binding protein Rbfox1l demarcates a restricted population of dorsal telencephalic neurons within the adult zebrafish brain

Rbfox RNA-binding proteins are expressed in the adult mammalian brain and are required for proper brain development and function. Studies in mice and humans have implicated Rbfox1/RBFOX1 in autism, neuronal excitation and epilepsy, and Rbfox2/RBFOX2 in cerebellar development. The zebrafish has emerged as a prominent model system for brain study, possessing neuroanatomical conservation with mammals and an extensive capacity for adult neurogenesis and plasticity. In this study, we characterize Rbfox1l and Rbfox2 expression in the adult zebrafish brain. While Rbfox2 is expressed broadly, Rbfox1l is expressed in restricted populations of neurons in the dorsal telencephalon and cerebellum. In the dorsal telencephalon, Rbfox1l is expressed in a specific population of neurons spanning Dm and Dc regions. In the cerebellum, Rbfox1l and Rbfox2 are expressed in the Purkinje cell layer, reminiscent of Rbfox1 and Rbfox2 expression in the mammalian cerebellum. Our findings motivate future studies of Rbfox function in the zebrafish brain.     

Establishment of a proteome profile and identification of molecular markers for mouse spermatogonial stem cells

Spermatogonial stem cells (SSCs) are undifferentiated cells that are required to maintain spermatogenesis throughout the reproductive life of mammals. Although SSC transplantation and culture provide a powerful tool to identify the mechanisms regulating SSC function, the precise signalling mechanisms governing SSC self‐renewal and specific surface markers for purifying SSCs remain to be clearly determined. In the present study, we established a steady SSC culture according to the method described by Shinohara's lab. Fertile progeny was produced after transplantation of cultured SSCs into infertile mouse testis, and the red fluorescence exhibited by the culture cell membranes was stably and continuously transmitted to the offspring. Next, via advanced mass spectrometry and an optimized proteomics platform, we constructed the proteome profile, with 682 proteins expressed in SSCs. Furthermore bioinformatics analysis showed that the list contained several known molecules that are regulated in SSCs. Several nucleoproteins and membrane proteins were chosen for further exploration using immunofluorescence and RT‐PCR. The results showed that SALL1, EZH2, and RCOR2 are possibly involved in the self‐renewal mechanism of SSCs. Furthermore, the results of tissue‐specific expression analysis showed that Gpat2 and Pld6 were uniquely and highly expressed in mouse testes and cultured SSCs. The cellular localization of PLD6 was further explored and the results showed it was primarily expressed in the spermatogonial membrane of mouse testes and cultured SSCs. The proteins identified in this study form the basis for further exploring the molecular mechanism of self‐renewal in SSCs and for identifying specific surface markers of SSCs.     

In vivo and in vitro analysis of homodimerisation activity of the mouse Dazl1 protein

In Drosophila RNA-binding proteins play a fundamental role in key developmental pathways, such as sex determination. There is emerging evidence suggesting that RNA-binding proteins play a central role in regulation of development in mammals as well. We are interested in spermatogenesis as a model for cell differentiation and development in mammals. Two Y-encoded candidate spermatogenesis genes, RBMY and DAZ, have been isolated by positional cloning from infertile patients. They both encode putative RNA-binding proteins of the RRM (RNA recognition motif) type, and the high degree of conservation of both these gene families suggests an important role in spermatogenesis. Mice with a null allele for Dazl1, the mouse homologue of DAZ, are infertile due to a meiotic entry defect. Male flies mutant for boule, the Drosophila homologue of Dazl1, are infertile due to a G(2)/M meiotic block. However, no data has been published yet about the biochemical properties of the DAZ/DAZL1 proteins. We report here that Dazl1 is able to form homoheterodimers both in vivo and in vitro, that this activity is due to a novel protein-protein interaction domain, and that homotypic interaction activity is RNA-independent.