结束语:
小RNA的研究给我们带来比其本身更为重要的启示是基因组非组蛋白编码区蕴含着重要的生命功能活动信息。生命的一些重要活动如幼虫的生长发育、细胞的发生和分化、神经系统的分化等都被一些非蛋白编码小RNA的调控;而除miRNA、siRNA以外的小RNA我们更是知之甚少。长期以来,分子生物学研究的重点都在蛋白编码基因上,而小RNA的发现和研究则提示我们应该相对更多地从这方面了解生命的奥秘,这些小RNA可能编码生命活动的重要调控元件。有报道称小RNA可影响四膜虫的细胞分裂,如果该种小RNA在人类中存在,则可能与癌症有关,2004年6月《临床研究杂志》上发表的一项实验室研究, siRNA似乎加强了伊马替尼(Imatinib)和雷帕霉素的抗癌作用。而且据说,这种治疗在出现药物耐受性时特别有帮助。SiRNA可以通过与HIV-1细胞内受体CD4,病毒结构蛋白Gag或替代Nef调节蛋白的绿色荧光蛋白的靶mRNA作用抑制病毒产生。SiRNA能有效抑制HIV-1生命周期中整合侵染前后事件。这样,siRNA可能应用到HIV-1和其他病毒侵染的治疗干预中。siRNA技术可能用于抑制HIV-1在宿主细胞中的复制的一种可能的治疗策略。利用小RNA有效抑制基因表达的机理可能为治疗很多病毒性疾病和基因疾病寻找新的途径和突破口。
小RNA还有许多问题需要我们去研究:它们的作用机理究竟是什么,具体有什么功能,它们通过什么途径识别靶标基因,它们的特异性和时序性是如何调控的等等。随着研究的深入,它将为人类疑难疾病治理等方面起更为深远的作用。总之,对小RNA基因的研究将是生命科学领域研究的热点,也将是揭示生命奥秘的又一大里程碑。
Reference List
Denli,A.M., Tops,B.B., Plasterk,R.H., Ketting,R.F., and Hannon,G.J. (2004). Processing of primary microRNAs by the Microprocessor complex. Nature 432, 231-235.
Ding,S.W., Li,H., Lu,R., Li,F., and Li,W.X. (2004). RNA silencing: a conserved antiviral immunity of plants and animals. Virus Res. 102, 109-115.
Gregory,R.I., Yan,K.P., Amuthan,G., Chendrimada,T., Doratotaj,B., Cooch,N., and Shiekhattar,R. (2004). The Microprocessor complex mediates the genesis of microRNAs. Nature 432, 235-240.
Han,J., Lee,Y., Yeom,K.H., Kim,Y.K., Jin,H., and Kim,V.N. (2004). The Drosha-DGCR8 complex in primary microRNA processing. Genes Dev. 18, 3016-3027.
Hannon,G.J. (2002). RNA interference. Nature 418, 244-251.
Khvorova,A., Reynolds,A., and Jayasena,S.D. (2003). Functional siRNAs and miRNAs exhibit strand bias. Cell 115, 209-216.
Kim,V.N. (2005). MicroRNA biogenesis: coordinated cropping and dicing. Nat. Rev. Mol. Cell Biol.
Lund,E., Guttinger,S., Calado,A., Dahlberg,J.E., and Kutay,U. (2004). Nuclear export of microRNA precursors. Science 303, 95-98.
Martinez,J., Patkaniowska,A., Urlaub,H., Luhrmann,R., and Tuschl,T. (2002). Single-stranded antisense siRNAs guide target RNA cleavage in RNAi. Cell 110, 563-574.
Martinez,J. and Tuschl,T. (2004). RISC is a 5' phosphomonoester-producing RNA endonuclease. Genes Dev. 18, 975-980.
Mello,C.C. and Conte,D., Jr. (2004). Revealing the world of RNA interference. Nature 431, 338-342.
Nykanen,A., Haley,B., and Zamore,P.D. (2001). ATP requirements and small interfering RNA structure in the RNA interference pathway. Cell 107, 309-321.
Pfeffer,S., Zavolan,M., Grasser,F.A., Chien,M., Russo,J.J., Ju,J., John,B., Enright,A.J., Marks,D., Sander,C., and Tuschl,T. (2004). Identification of virus-encoded microRNAs. Science 304, 734-736.
Pham,J.W., Pellino,J.L., Lee,Y.S., Carthew,R.W., and Sontheimer,E.J. (2004). A Dicer-2-dependent 80s complex cleaves targeted mRNAs during RNAi in Drosophila. Cell 117, 83-94.
Rhoades,M.W., Reinhart,B.J., Lim,L.P., Burge,C.B., Bartel,B., and Bartel,D.P. (2002). Prediction of plant microRNA targets. Cell 110, 513-520.
Schwarz,D.S., Hutvagner,G., Du,T., Xu,Z., Aronin,N., and Zamore,P.D. (2003). Asymmetry in the assembly of the RNAi enzyme complex. Cell 115, 199-208.
Tabara,H., Sarkissian,M., Kelly,W.G., Fleenor,J., Grishok,A., Timmons,L., Fire,A., and Mello,C.C. (1999). The rde-1 gene, RNA interference, and transposon silencing in C. elegans. Cell 99, 123-132.
Tang,G. (2005). siRNA and miRNA: an insight into RISCs. Trends Biochem. Sci. 30, 106-114.
Yi,R., Qin,Y., Macara,I.G., and Cullen,B.R. (2003). Exportin-5 mediates the nuclear export of pre-microRNAs and short hairpin RNAs. Genes Dev. 17, 3011-3016.
