SRp38基因研究进展

SR蛋白在前体mRNA可变剪接调控中发挥重要作用。可变剪接调节因子SRp38作为一种新近发现的具有神经及生殖组织特异性的SR蛋白,有典型的SR蛋白结构特征并能够调控GluR-B、TRK-C以及NCAML1等基因的可变剪接,但与其他SR蛋白不一致的是,SRp38可以在一定条件下(有丝分裂M期,热休克)抑制前体mRNA剪接,从而防止错误剪接的出现。SRp38的RRM结构域可以识别特殊的RNA序列并跟U1snRNP结合,而其RS结构域则参与调控前体mRNA剪接。SRp38的磷酸化状态可以影响其调控功能的发挥,在有丝分裂M期及热休克时,该蛋白质均呈去磷酸化状态。SRp38在爪蟾胚胎神经发育过程中发挥作用并且可以同TLS(translocation liposarcoma)蛋白相互作用,提示其可能通过调节前体mRNA可变剪接在神经系统的发育分化以及在肿瘤的发生中扮演角色。     

PTB蛋白:一种调控肿瘤代谢的RNA可变剪接调节因子

多聚嘧啶区结合蛋白(polypyrimidine tract binding protein,PTB或hnRNP I)是一种在细胞内部参与mRNA代谢过程的蛋白质。PTB蛋白可结合于核酸分子上富含嘧啶碱基的序列,对mRNA前体的剪接进行调控。如在部分肿瘤细胞中,PTB的表达量升高可对肿瘤代谢过程中关键的丙酮酸激酶M(pyruvate kinase M,PKM)基因的表达进行调控,通过抑制PKM基因的可变剪接的方式上调PKM2(pyruvate kinase M2,PKM2)的表达,进而强化肿瘤细胞的有氧糖酵解过程并促进肿瘤的发展。本文结合PTB蛋白的结构及其在PKM可变剪接过程中的调节机制,简要综述了PTB蛋白对肿瘤代谢的调控作用。     

SRp38基因在小鼠视网膜细胞中的表达以及对GluR-B小基因可变剪接的调控

SR蛋白在前体mRNA可变剪接调控中发挥重要作用.SRp38作为一种新近发现的具有神经及生殖组织特异性的SR蛋白,能够调控一些在神经组织中起重要作用的基因(如GluR-B,Trk-C,NCAML1等)的前体mRNA可变剪接,同时还可以在有丝分裂M期及热休克时抑制前体mRNA剪接的发生.利用Western blot以及免疫组织化学方法研究了SRp38蛋白在小鼠视网膜中的表达以及分布情况,结果显示,SRp38蛋白在视网膜中的表达具有区域特异性,在外网层、内核层、内网层以及节细胞层中均有表达,而在外核层无表达.对分离培养的小鼠视网膜细胞进行免疫双标记分析的结果表明,SRp38蛋白在视杆-双极细胞的胞体、轴突、树突中表达.通过瞬时共转染以及RT_PCR分析,发现在R28细胞中,SRp38过表达可以促进GluR-B小基囚Flip亚型的剪接.结果提示SRp38蛋白可能通过调控小鼠视网膜内前体mRNA可变剪接、进而在小鼠视网膜功能中发挥重要作用.     

真核基因可变剪接研究现状与展望

mRNA前体(pre-mRNA)的可变剪接是控制基因表达和产生蛋白质多样性的重要机制,是功能基因组时代的研究重点之一。生物信息学在识别可变剪接基因及其结构、分析可变剪接的功能和调控方式等方面具有重要作用。除了耗时的实验研究,识别可变剪接基因及其结构主要通过EST、mRNA等转录数据与基因组序列进行比对,获得同一基因的不同结构方式。分析蛋白质产物可对可变剪接的功能进行预测;潜在调控元件的统计分析则可为可变剪接调控机制的研究提供必要的数据。转录数据的时空信息以及比较基因组学对理解可变剪接信息的精确调控将提供重要资料。可变剪接及其调控机制的深入研究将为基因组和蛋白质组之间的对接提供重要的桥梁。     

染色质结构与mRNA可变剪接

mRNA的可变剪接(alternative splicing)是一种由一个mRNA前体(pre-mRNA)通过不同的剪接方式产生多个mRNA变异体(variants)的RNA加工过程。在过去很长一段时间里,人们认为mRNA剪接过程是独立于转录过程的一个转录后RNA加工过程。然而,越来越多的实验证明mRNA剪接在很大程度上是与转录偶联发生的。因此,剪接调控会受到与转录相关因素的调控。本文将对染色质与mRNA剪接调控的相关性和染色质结构调控可变剪接的分子机制进行阐述。     

选择性剪接与肿瘤靶向治疗

RNA剪接过程受到多种调节因子作用,以保证前体mRNA剪接的准确性。但是大量研究发现,在人类肿瘤中经常发生选择性剪接的异常或者来自特定癌症基因的剪接调控元件的突变。因此,RNA剪接调节剂作为一类新的癌蛋白和肿瘤抑制因子而逐渐受到关注,并有望通过调节参与致癌基因的RNA而达到治疗肿瘤的效果。改变RNA的异常剪接是治疗相关癌症的基础,这也为靶向治疗提供了更加丰富的靶点。本文综述了新发现的和预测的不同的剪接事件导致癌症的相关基因,并且对它们如何促成疾病的发病机制进行讨论。最后,我们总结了最新的针对可变剪接而发展的癌症诊断和治疗方法,包括使用小分子的剪接抑制剂来阻断剪接体或转录因子修饰酶,以调节特异性剪接导致的癌症。     

哺乳动物细胞mRNA剪接调控的分子机制

mRNA的可变剪接是指一个单一的mRNA前体(pre-mRNA)经过不同的剪接加工方式生成多种mRNA变异体(variants)的过程,这些变异体最终可以编码合成具有不同结构和功能的蛋白质。在过去的10多年中,大量数据表明,可变剪接是增加转录组和蛋白质组多样性的重要资源,也是调控哺乳动物细胞基因表达的重要步骤。可变剪接具有高度的组织与发育阶段特异性,并受到外界信号的控制。剪接调控的紊乱与疾病的发生发展密切相关。该文将对哺乳动物细胞mRNA剪接调控的分子机制进行阐述。     

可变剪接调控因子SRSF2的研究进展

RNA剪接是指从mRNA前体中去除内含子、连接外显子形成成熟mRNA的过程。由于选择不同的剪接位点,可变剪接控制着从单一前体mRNA生成多种成熟mRNA的过程,因此是真核生物中转录后调控基因表达和决定蛋白质多样性的重要层次。SR蛋白家族是参与调控可变剪接的一类重要的剪接因子。SRSF2是SR蛋白家族的一员,具有经典的SR蛋白结构域。SRSF2不仅能够调控可变剪接,还能调控基因的转录过程,在维持胸腺、骨髓等造血系统的正常发育以及维持肝脏代谢稳态中是非常关键的调控因子。大量的研究表明:SRSF2的突变与骨髓增生异常综合征等造血系统疾病密切相关。本文总结了SRSF2最近的研究进展,以期对SRSF2在体内的功能有更全面和深入的理解,并为相关疾病的研究和治疗提供一定的思路。     

mRNA前体的剪接因子

真核生物通过mRNA前体的剪接,包括选择性剪接机制,调控着自身的生长与发育,了解其基本过程和有关参与因子,对进一步探索真核生物基因的表达调控和分子进化都具有极其重要的意义.该文简要综述了mRNA前体剪接的基本过程及有关剪接因子的最新研究进展,介绍了SR蛋白（Ser-Arg rich protein）家族因子、某些新发现的参与形成核不均一核糖核蛋白（heterogeneous nuclear ribonucleoprotein,hnRNP）的因子及部分：RNA解旋酶等在mRNA前体剪接过程中的功能和作用.     

mRNA选择性剪接的分子机制

真核细胞mRNA前体经过剪接成为成熟的mRNA,而mRNA前体的选择性剪接极大地增加了蛋白质的多样性和基因表达的复杂程度,剪接位点的识别可以以跨越内含子的机制(内含子限定)或跨越外显子的机制(外显子限定)进行。选择性剪接有多种剪接形式：选择不同的剪接位点,选择不同的剪接末端,外显子的不同组合及内含子的剪接与否等。选择性剪接过程受到许多顺式元件和反式因子的调控,并与基本剪接过程紧密联系,剪接体中的一些剪接因子也参与了对选择性剪接的调控。选择性剪接也是1个伴随转录发生的过程,不同的启动子可调控产生不同的剪接产物。mRNA的选择性剪接机制多种多样,已发现RNA编辑和反式剪接也可参与选择性剪接过程。     

Nucleotide substitutions within the cardiac troponin T alternative exon disrupt pre-mRNA alternative splicing.

The cardiac troponin T (cTNT) pre-mRNA contains a single alternative exon (exon 5) which is either included or excluded from the processed mRNA. Using transient transfection of cTNT minigenes, we have previously localized pre-mRNA cis elements required for exon 5 alternative splicing to three small regions of the pre-mRNA which include exons 4, 5, and 6. In the present study, nucleotide substitutions were introduced into the region containing exon 5 to begin to define specific nucleotides required for exon 5 alternative splicing. A mutation within the 5' splice site flanking the cTNT alternative exon that increases its homology to the consensus sequence improves splicing efficiency and leads to increased levels of mRNAs that include the alternative exon. Surprisingly, substitution of as few as four nucleotides within the alternative exon disrupts cTNT pre-mRNA alternative splicing and prevents recognition of exon 5 as a bona fide exon. These results establish that the cTNT alternative exon contains information in cis that is required for its recognition by the splicing machinery.     

Cell-autonomous regulation of fast troponin T pre-mRNA alternative splicing in response to mechanical stretch

How mechanochemical signals induced by the amount of weight borne by the skeletal musculature are translated into modifications to muscle sarcomeres is poorly understood. Our laboratory recently demonstrated that, in response to experimentally induced increases in the weight load borne by a rat, alternative splicing of the fast skeletal muscle troponin T (Tnnt3) pre-mRNA in gastrocnemius was adjusted in a correlated fashion with the amount of added weight. (Schilder RJ, Kimball SR, Marden JH, Jefferson LS. J Exp Biol 214: 1523-1532, 2011). Thus muscle load is perceived quantitatively by the body, and mechanisms that sense it appear to control processes that generate muscle sarcomere composition plasticity, such as alternative pre-mRNA splicing. Here we demonstrate how mechanical stretch (see earlier comment) of C2C12 muscle cells in culture results in changes to Tnnt3 pre-mRNA alternative splicing that are qualitatively similar to those observed in response to added weight in rats. Moreover, inhibition of Akt signaling, but not that of ERK1/2, prevents the stretch-induced effect on Tnnt3 pre-mRNA alternative splicing. These findings suggest that effects of muscle load on Tnnt3 pre-mRNA alternative splicing are controlled by a cell-autonomous mechanism, rather than systemically. They also indicate that, in addition to its regulatory role in protein synthesis and muscle mass plasticity, Akt signaling may regulate muscle sarcomere composition by modulating alternative splicing events in response to load. Manipulation of Tnnt3 pre-mRNA alternative splicing by mechanical stretch of cells in culture provides a model to investigate the biology of weight sensing by skeletal muscles and facilitates identification of mechanisms through which skeletal muscles match their performance and experienced load.     

Plant serine/arginine-rich proteins and their role in pre-mRNA splicing

Pre-messenger RNA (pre-mRNA) splicing, a process by which mature mRNAs are generated by excision of introns and ligation of exons, is an important step in the regulation of gene expression in all eukaryotes. Selection of alternative splice sites in a pre-mRNA generates multiple mRNAs from a single gene that encode structurally and functionally distinct proteins. Alternative splicing of pre-mRNAs contributes greatly to the proteomic complexity of plants and animals and increases the coding potential of a genome. However, the mechanisms that regulate constitutive and alternative splicing of pre-mRNA are not understood in plants. A serine/arginine-rich (SR) family of proteins is implicated in constitutive and alternative splicing of pre-mRNAs. Here I review recent progress in elucidating the roles of serine/arginine-rich proteins in pre-mRNA splicing.     

可变剪接的生物信息数据分析综述

前体mRNA的可变剪接是扩大真核生物蛋白质组多样性的重要基因调控机制。可变剪接的错误调节可以引起多种人类疾病。由于高通量技术的发展,生物信息学成为可变剪接研究的主要手段。本文总结了可变剪接在生物信息学领域的研究方法,同时也分析并预测了可变剪接的发展方向。     

Tumor suppressor RBM5 directly interacts with the DExD/H-box protein DHX15 and stimulates its helicase activity

RNA binding motif protein 5 (RBM5) is a candidate tumor suppressor gene. Recent studies showed that RBM5 functions as an alternative splicing regulator of apoptosis-related genes. Here, we identify DHX15 and PRP19, two spliceosome components, as novel RBM5-interacting partners. We then show that the G-patch domain of RBM5 is indispensable for its ability to interact with DHX15. Strikingly, we find that RBM5 stimulates the helicase activity of DHX15 in a G patch domain-dependent manner in vitro. Helicase activities play critical roles in modulating pre-mRNA splicing. Our findings thus suggest a new mechanism underlying the regulatory roles of RBM5 in pre-mRNA splicing.     

丙酮酸激酶前mRNA可变剪接的调控在肿瘤代谢中的作用和意义

丙酮酸激酶是糖酵解的关键酶之一,丙酮酸激酶m基因前mRNA(pre-mRNA)通过可变剪接产生M1和M2型两种丙酮酸激酶异构体,2种异构体的选择性表达决定肿瘤细胞的代谢表型,改变肿瘤细胞的增殖和生长。因此,调控丙酮酸激酶可变剪接,对于控制肿瘤细胞的生长代谢十分重要。研究发现,核不均一核糖核蛋白(hnRNP)A1/A2及多聚嘧啶结合蛋白(PTB,又称hnRNPⅠ)具有调控丙酮酸激酶前mRNA可变剪接的作用,并且致癌转录因子c-Myc与hnRNP A1/A2及PTB在肿瘤细胞中的过表达密切相关。我们结合相关研究进展,简要综述丙酮酸激酶可变剪接调控机制。     

The haplo-spliceo-transcriptome: common variations in alternative splicing in the human population

Numerous inherited human genetic disorders are caused by defects in pre-mRNA splicing. Two recent studies have added a new twist to the link between genetic variation and pre-mRNA splicing by identifying SNPs that correlate with heritable changes in alternative splicing but do not cause disease. This suggests that allele-specific alternative splicing is a mechanism that accounts for individual variation in the human population.     

Cis requirements for alternative splicing of the cardiac troponin T pre-mRNA.

The cardiac troponin T (cTNT) pre-mRNA splices 17 exons contiguously but alternatively splices (includes or excludes) the fifth exon. Because both alternative splice products are processed from the same pre-mRNA species, the cTNT pre-mRNA must contain cis-acting sequences which specify exon 5 as an alternative exon. A cTNT minigene (SM-1) transfected into cultured cells produces mRNAs both including and excluding exon 5. The junctions of exons 4-5-6 and 4-6 in the cTNT minigene mRNAs are identical to those of endogenous cTNT mRNAs and no other exons are alternatively spliced. Thus, the SM-1 pre-mRNA is correctly alternatively spliced in transfected cells. To circumscribe the pre-mRNA regions which are required for the alternative nature of exon 5, we have constructed a systematic series of deletion mutants of SM-1. Transfection of this series demonstrates that a 1200 nt pre-mRNA region containing exons 4, 5, and 6 is sufficient to direct alternative splicing of exon 5. Within this region are two relatively large inverted repeats which potentially sequester the alternative exon via intramolecular base-pairing. Such sequestration of an alternative exon is consistent with models which propose pre-mRNA conformation as being determinative for alternative splicing of some pre-mRNAs. However, deletion mutants which remove the majority of each of the inverted repeats retain the ability to alternatively splice exon 5 demonstrating that neither is required for cTNT alternative splice site selection. Taken together, deletion analysis has limited cis elements required for alternative splicing to three small regions of the pre-mRNA containing exons 4, 5, and 6. In addition, the cTNT minigene pre-mRNA expresses both alternative splice products in a wide variety of cultured non-muscle cells as well as in cultured striated muscle cells, although expression of the cTNT pre-mRNA is normally restricted to striated muscle. This indicates that cis elements involved in defining the cTNT exon 5 as an alternative exon do not require muscle-specific factors in trans to function.