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1.
转录后基因沉默(PTGS)及其在作物遗传改良中的应用   总被引:19,自引:0,他引:19  
转录后基因沉默(PTGS)或RNA干扰(RNAi)技术的发展为创造植物遗传变异体提供了新途径。PTGS于1998年被明确为双链RNA(dsRNA)诱导的序列特异性基因沉默,短短几年内有关研究取得了突破性进展。结合利用PTGS技术进行的淀粉合成关键酶基因沉默研究,概述了PTGS的作用机理和特点、dsRNA表达载体设计、沉默效应的遗传稳定性及在作物改良应用方面的研究进展。研究表明,基因沉默效应可在子代间稳定遗传并可通过杂交进行重组,显示了其在农作物改良方面的应用潜力。  相似文献   

2.
RNA干扰(RNAi)是由双链RNA(dsRNA)介导的序列特异的基因沉默现象,RNAi效应具有高特异性和高效性的显著特征,能够在细胞和子代间传递.除诱导同源序列mRNA降解或阻止其翻译而使目的基因表达受阻的转录后基因沉默外,RNA干扰可通过组蛋白甲基化影响染色质结构、通过DNA甲基化在转录水平调节基因表达,在翻译水平调节机体发育,并作为基因组的免疫系统,使转座因子或重复序列区域异染色质化,有效抑制了转座子和重复序列之间的同源重组对基因组可能造成的破坏,使生物基因组在长期进化过程中能保持结构的完整性和遗传的连续性. RNA干扰以阻抑基因的表达来模拟基因敲除技术,为反向遗传学研究基因功能提供了一种快速和简便的方法.RNA干扰技术日趋成熟和完善,为人们迅速准确地分析基因功能提供了极为有用的工具,同时在临床应用和治疗肿瘤和癌症等方面也有着巨大的应用前景.  相似文献   

3.
RNA干涉与功能基因组   总被引:2,自引:0,他引:2  
RNA干涉是通过双链RNA的介导特异性抑制具有相应序列的基因表达的转录后水平基因沉默机制,它为反向遗传方法研究基因功能开辟了一条新路。本综述了RNA干涉的机制以及它在功能基因组研究方面的最新进展。  相似文献   

4.
RNA干扰技术的原理与应用   总被引:6,自引:0,他引:6  
RNA干扰(RNA interference,RNAi)是由双链RNA(double-stranded RNA,dsRNA)所引起的序列特异性基因沉默,是真核生物中一种非常保守的机制,它与协同抑制(cosuppression)、转座子沉默(transposon silencing)以及发育等许多重要的生物学过程密切相关。RNA干扰依赖于小干扰RNA(Small interference RNA,siRNA)与靶序列之间严格的碱基配对,具有很强的特异性,涉及众多基因和蛋白复合物,构成了一个以小RNA为核心的真核基因表达调控系统,它可以在染色质水平、转录水平、转录后水平和翻译水平参与基因表达的调节。RNA干扰技术为人们迅速、准确的剖析基因的功能,分析基因之间错综复杂的联系和相互作用提供了极为有用的工具,同时也为人们预防和治疗癌症和病毒疾病提供了新的思路。  相似文献   

5.
长链非编码RNA起初被认定是基因转录"噪音",随着DNA元件百科全书的研究进展发现,lnc RNA能以RNA的形式在表观遗传、转录以及转录后水平调控基因的表达,参与多种重要的生命调控过程,与人类疾病的发生发展和预防都有着紧密联系。文章介绍lnc RNA的功能和特点,结合对lnc RNA的研究思路,并在已有研究的基础上综述lnc RNA与糖尿病及其并发症的关系,这些研究进展将为进一步理解糖尿病及其发生发展的分子医学基础提供依据。  相似文献   

6.
RNA原位杂交技术的一些应用技巧   总被引:3,自引:0,他引:3  
目的:检测基因在动物组织或细胞中的时空表达模式。方法:转录反义RNA探针;利用RNA原位杂交技术检测人和小鼠牙原基中若干基因的表达。结果与结论:通过优化条件,转录出完整的反义RNA探针,并成功地利用RNA原位杂交技术在组织中检测到基因的表达;分析了一些在RNA原位杂交的过程中可能碰到的问题及其解决方法。  相似文献   

7.
基因印记是一种表观遗传调控机制,在二倍体哺乳动物的发育过程中,基因印记可以调控来自亲代的等位基因差异表达。非编码RNA是不编码蛋白质的RNA,它在RNA水平调控基因表达。研究表明大多数印记基因中存在长非编码RNA(长度200nt的非编码RNA)的转录,长非编码RNA主要通过顺式的转录干扰作用来实现基因印记。同时基因印记及其相关的长非编码RNA异常表达与许多先天疾病相关,迄今已发现数十种人类遗传疾病与基因印记有关,而lncRNA引起的基因印记在疾病的发生和治疗中起着重要作用。  相似文献   

8.
随着基因组学和转录组学的发展,人们对非编码RNA(non-coding RNA,nc RNA)结构与功能的认识越来越深入。RNA的重要性已不再仅仅以"是否能为蛋白质编码"或"是否与蛋白质合成有关"来体现,它们在复制、复制后、转录、转录后、翻译和翻译后以及表观遗传等多个层面调控基因的表达,体现出丰富多彩的生物学功能。笔者在介绍nc RNA的概念、分类和主要功能的基础上,结合对本科生《生物化学与分子生物学》相关课程现有教学内容的分析,建议高校应通过教材编写、课堂教学、实验指导和学生科研等环节增加nc RNA知识的介绍。  相似文献   

9.
长链非编码RNA(long non-coding RNA,lncRNA)是指转录本长度超过200个核苷酸的功能性RNA分子,在表观遗传、转录和转录后等水平上调控基因的表达,广泛参与机体的生理和病理过程。近年来,对lncRNA在肿瘤等疾病中的功能做了一些研究,但在感染中的功能研究较少。近些年的研究发现,一些病毒感染会普遍引起宿主lncRNA的表达变化,且病毒的一些lncRNA通过与宿主蛋白质结合而调控宿主基因的表达,以利于病毒生命周期的完成。本文对lncRNA与寄生虫和病毒感染的关系做一综述。  相似文献   

10.
在生物体中 ,双链RNA (double strandRNA ,dsRNA)裂解后的小RNA可以诱导细胞质和基因组水平外源基因沉默。所谓基因沉默 (genesilencing)是指生物体中特定基因由于种种原因不表达。小RNA能诱导互补信使RNA在转录后降解 ,对于植物 ,可通过同源DNA序列甲基化使转录基因沉默。RNA沉默是基因组水平的免疫现象 ,代表了进化过程中原始的基因组对抗外源基因序列表达的保护机制 ,在动植物进化中起着重要作用 ,RNA沉默具有抵抗病毒入侵、抑制转座子活动、防止自私基因序列的过量增殖等作用 ,并调控蛋白编码基因的表达 ,具有十分诱人的应用前景  相似文献   

11.
RNomics: identification and function of small,non-messenger RNAs   总被引:18,自引:0,他引:18  
In the past few years, our knowledge about small non-mRNAs (snmRNAs) has grown exponentially. Approaches including computational and experimental RNomics have led to a plethora of novel snmRNAs, especially small nucleolar RNAs (snoRNAs). Members of this RNA class guide modification of ribosomal and spliceosomal RNAs. Novel targets for snoRNAs were identified such as tRNAs and potentially mRNAs, and several snoRNAs were shown to be tissue-specifically expressed. In addition, previously unknown classes of snmRNAs have been discovered. MicroRNAs and small interfering RNAs of about 21-23 nt, were shown to regulate gene expression by binding to mRNAs via antisense elements. Regulation of gene expression is exerted by degradation of mRNAs or translational regulation. snmRNAs play a variety of roles during regulation of gene expression. Moreover, the function of some snmRNAs known for decades, has been finally elucidated. Many other RNAs were identified by RNomics studies lacking known sequence and structure motifs. Future challenges in the field of RNomics include identification of the novel snmRNA's biological roles in the cell.  相似文献   

12.
BACKGROUND: Genomes from all organisms known to date express two types of RNA molecules: messenger RNAs (mRNAs), which are translated into proteins, and non-messenger RNAs, which function at the RNA level and do not serve as templates for translation. RESULTS: We have generated a specialized cDNA library from Arabidopsis thaliana to investigate the population of small non-messenger RNAs (snmRNAs) sized 50-500 nt in a plant. From this library, we identified 140 candidates for novel snmRNAs and investigated their expression, abundance, and developmental regulation. Based on conserved sequence and structure motifs, 104 snmRNA species can be assigned to novel members of known classes of RNAs (designated Class I snmRNAs), namely, small nucleolar RNAs (snoRNAs), 7SL RNA, U snRNAs, as well as a tRNA-like RNA. For the first time, 39 novel members of H/ACA box snoRNAs could be identified in a plant species. Of the remaining 36 snmRNA candidates (designated Class II snmRNAs), no sequence or structure motifs were present that would enable an assignment to a known class of RNAs. These RNAs were classified based on their location on the A. thaliana genome. From these, 29 snmRNA species located to intergenic regions, 3 located to intronic sequences of protein coding genes, and 4 snmRNA candidates were derived from annotated open reading frames. Surprisingly, 15 of the Class II snmRNA candidates were shown to be tissue-specifically expressed, while 12 are encoded by the mitochondrial or chloroplast genome. CONCLUSIONS: Our study has identified 140 novel candidates for small non-messenger RNA species in the plant A. thaliana and thereby sets the stage for their functional analysis.  相似文献   

13.
碳存储调控因子A (carbon storage regulator, CsrA) 是一种RNA结合蛋白,在细菌的碳代谢、生物被膜形成、运动性、病原菌毒力、群体感应、环二鸟苷酸信号合成、应激感应等多种生理过程中具有重要调节功能,是全局性调控蛋白.它通过与靶标mRNA的特异结合,抑制其翻译或增强其稳定性来调控下游基因的表达,属于转录后调控因子的范畴.CsrA蛋白的表达与活性受碳存储调控(Csr)系统本身多个自主调节回路的精密控制: 一些小的非编码RNA (snmRNAs,如CsrB/C)作为拮抗因子与CsrA二聚体结合并抑制其活性;而这些snmRNAs在体内又可在CsrD的辅助下被核糖核酸内切酶E和多核苷酸磷酸化酶降解,释放CsrA的活性.当前,对于Csr系统的调节作用、调控通路与机制的研究是细菌学研究的热点,本文综述了该蛋白及Csr系统的结构、功能和作用机制的最新研究进展.  相似文献   

14.
By generating a specialised cDNA library from four different developmental stages of Drosophila melanogaster, we have identified 66 candidates for small non-messenger RNAs (snmRNAs) and have confirmed their expression by northern blot analysis. Thirteen of them were expressed at certain stages of D.melanogaster development, only. Thirty-five species belong to the class of small nucleolar RNAs (snoRNAs), divided into 15 members from the C/D subclass and 20 members from the H/ACA subclass, which mostly guide 2'-O-methylation and pseudouridylation, respectively, of rRNA and snRNAs. These also include two outstanding C/D snoRNAs, U3 and U14, both functioning as pre-rRNA chaperones. Surprisingly, the sequence of the Drosophila U14 snoRNA reflects a major change of function of this snoRNA in Diptera relative to yeast and vertebrates. Among the 22 snmRNAs lacking known sequence and structure motifs, five were located in intergenic regions, two in introns, five in untranslated regions of mRNAs, eight were derived from open reading frames, and two were transcribed opposite to an intron. Interestingly, detection of two RNA species from this group implies that certain snmRNA species are processed from alternatively spliced pre-mRNAs. Surprisingly, a few snmRNA sequences could not be found on the published D.melanogaster genome, which might suggest that more snmRNA genes (as well as mRNAs) are hidden in unsequenced regions of the genome.  相似文献   

15.
16.
In mouse brain cDNA libraries generated from small RNA molecules we have identified a total of 201 different expressed RNA sequences potentially encoding novel small non-messenger RNA species (snmRNAs). Based on sequence and structural motifs, 113 of these RNAs can be assigned to the C/D box or H/ACA box subclass of small nucleolar RNAs (snoRNAs), known as guide RNAs for rRNA. While 30 RNAs represent mouse homologues of previously identified human C/D or H/ACA snoRNAs, 83 correspond to entirely novel snoRNAS: Among these, for the first time, we identified four C/D box snoRNAs and four H/ACA box snoRNAs predicted to direct modifications within U2, U4 or U6 small nuclear RNAs (snRNAs). Furthermore, 25 snoRNAs from either class lacked antisense elements for rRNAs or snRNAS: Therefore, additional snoRNA targets have to be considered. Surprisingly, six C/D box snoRNAs and one H/ACA box snoRNA were expressed exclusively in brain. Of the 88 RNAs not belonging to either snoRNA subclass, at least 26 are probably derived from truncated heterogeneous nuclear RNAs (hnRNAs) or mRNAS: Short interspersed repetitive elements (SINEs) are located on five RNA sequences and may represent rare examples of transcribed SINES: The remaining RNA species could not as yet be assigned either to any snmRNA class or to a part of a larger hnRNA/mRNA. It is likely that at least some of the latter will represent novel, unclassified snmRNAS:  相似文献   

17.
哺乳动物胚胎发育受遗传和表观遗传的共同调控。精子作为重要的雄性生殖细胞,通过受精过程,将这些信息传递给卵子,进而影响子代的发育。精子中携带有丰富的表观遗传信息,其中小非编码RNAs(small noncoding RNAs, sncRNAs)在精子发育不同阶段发挥重要的作用,包括调控基因表达、介导蛋白质翻译,以及参与精子的表观遗传信息传递等。环境暴露包括饮食变化、毒性物质暴露和心理压力等。现有的研究表明,环境因素不仅影响机体健康,还可能导致生殖系统配子(精子与/或卵子)表观遗传信息的改变。越来越多的证据表明,亲本在环境暴露后发生的获得性性状变化,可通过配子的表观遗传信息传递给后代,即产生跨代遗传。本综述主要讨论因环境因素引起的获得性性状,可通过精子sncRNAs变化,产生跨代遗传,并影响胚胎发育及子代健康。本综述的讨论主要集中在tRNA来源的小RNAs(transfer RNA-derived small RNAs,tsRNAs)、微RNA(microRNAs, miRNAs)和PIWI相互作用RNAs(PIWI-interacting RNAs,piRNAs),并涉及到最近在精子中发现有大量表达的rRNA来源的小RNAs(risbosome-RNA derived small RNAs,rsRNAs)。此外,本文还进一步探讨了环境因素影响精子sncRNAs表达变化的可能机制。通过对上述内容的综述,将更好地理解精子sncRNAs在跨代遗传中的作用,促进表观遗传学领域的新研究,加深对基本生命过程的理解。  相似文献   

18.
Invasive nucleic acids such as transposons and viruses usually exhibit aberrant characteristics, e.g., unpaired DNA or abnormal double-stranded RNA. Organisms employ a variety of strategies to defend themselves by distinguishing self and nonself substances and disabling these invasive nucleic acids. Furthermore, they have developed ways to remember this exposure to invaders and transmit the experience to their descendants. The mechanism underlying this inheritance has remained elusive. Recent research has shed light on the initiation and maintenance of RNA-mediated inherited gene silencing. Small regulatory RNAs play a variety of crucial roles in organisms, including gene regulation, developmental timing, antiviral defense, and genome integrity, via a process termed as RNA interference (RNAi). Recent research has revealed that small RNAs and the RNAi machinery are engaged in establishing and promoting transgenerational gene silencing. Small RNAs direct the RNAi and chromatin modification machinery to the cognate nucleic acids to regulate gene expression and epigenetic alterations. Notably, these acquired small RNAs and epigenetic changes persist and are transmitted from parents to offspring for multiple generations. Thus, RNAi is a vital determinant of the inheritance of gene silencing and acts as a driving force of evolution.  相似文献   

19.
《遗传学报》2022,49(2):89-95
There is accumulating evidence to show that environmental stressors can regulate a variety of phenotypes in descendants through germline-mediated epigenetic inheritance. Studies of model organisms exposed to environmental cues (e.g., diet, heat stress, toxins) indicate that altered DNA methylations, histone modifications, or non-coding RNAs in the germ cells are responsible for the transgenerational effects. In addition, it has also become evident that maternal provision could provide a mechanism for the transgenerational inheritance of stress adaptations that result from ancestral environmental cues. However, how the signal of environmentally-induced stress response transmits from the soma to the germline, which may influence offspring fitness, remains largely elusive. Small RNAs could serve as signaling molecules that transmit between tissues and even across generations. Furthermore, a recent study revealed that neuronal mitochondrial perturbations induce a transgenerational induction of the mitochondrial unfolded protein response mediated by a Wnt-dependent increase in mitochondrial DNA levels. Here, we review recent work on the molecular mechanism by which parental experience can affect future generations and the importance of soma-to-germline signaling for transgenerational inheritance.  相似文献   

20.
Life experiences can induce epigenetic changes in mammalian germ cells, which can influence the developmental trajectory of the offspring and impact health and disease across generations. While this concept of epigenetic germline inheritance has long been met with skepticism, evidence in support of this route of information transfer is now overwhelming, and some key mechanisms underlying germline transmission of acquired information are emerging. This review focuses specifically on sperm RNAs as causal vectors of inheritance. We examine how they might become altered in the germline, and how different classes of sperm RNAs might interact with other epimodifications in germ cells or in the zygote. We integrate the latest findings with earlier pioneering work in this field, point out major questions and challenges, and suggest how new experiments could address them.  相似文献   

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