反式翻译模型

反式翻译是细菌体内一种修复翻译水平上受阻的遗传信息表达过程的机制。tmRNA是反式翻译的核心分子,它兼具tRNA和mRNA的特点,在SmpB蛋白的帮助下特异性识别携带mRNA缺失体的核糖体,在核糖体蛋白S1的传递作用下结合在A位点上,一方面延续被中断的mRNA上的遗传信息,一方面终止蛋白质的合成,释放被束缚的核糖体和tRNA进入新的翻译过程。本文对近年来关于反式翻译模型的研究进行综述。     

蛋白质翻译中的反转运

在蛋白质的翻译过程中,氨酰-tRNA进入核糖体,解密mRNA上的一个密码子,并带着mRNA向其5'的方向运动,直到空载的tRNA离开核糖体,整个过程tRNA在核糖体内始终沿着一个方向运动.但随着LepA(EF4)蛋白的发现和其功能的明确,tRNA在核糖体内的新运动形式--"反转运"被揭示,即tRNA带着mRNA倒退一步,向其3'的方向运动.通过对tRNA反向运动生理意义的研究,引发了对蛋白质翻译调控的深入思考.     

细菌核糖体的拯救机制

蛋白质翻译过程中,很多因素可能导致核糖体在mRNA上熄火,这对细胞的危害很大,因为这不仅占用了核糖体、氨基酸和tRNA,而且还可能产生有害的蛋白质.细菌进化出了多种核糖体拯救机制,释放熄火的核糖体,清除异常的mRNA,以规避毒害,如：① tmRNA·SmpB介导的拯救机制,又称为反式翻译介导的拯救机制|② ArfA(YhdL)介导的拯救机制|③ YaeJ(ArfB)介导的拯救机制.这些机制对于细菌的生理和繁殖都非常重要,但却在真核生物进化过程中消失了,使这些机制有可能成为抗菌药物靶点.本文主要就细菌核糖体的拯救机制做一概述,并对这些机制的应用前景进行了展望.     

基于翻译调控的细菌耐药研究进展

由于抗生素的大量使用,细菌耐药问题凸显,直接威胁人类生命健康和世界经济发展。过去对于细菌耐药的遗传和分子机制研究较为透彻,而对应的调控机制研究相对较少。翻译调控作为生命体最重要的调控方式之一,在细菌耐药研究领域的重要性尚未被学术界充分重视。本文介绍了影响翻译过程的抗生素的主要作用机制,重点从核糖体的修饰和突变、tRNA总量的动态调控、tRNA氨酰化、tRNA甲基化、核糖体保护蛋白和翻译因子这几个方面概述了基于翻译调控的细菌耐药研究进展,为研究者们提供了一个基于翻译调控角度研究细菌耐药的新视角,同时也为开发靶向细菌翻译调控的新型抗生素提供一些新思路。     

线粒体核糖体——细胞器中的翻译机器

线粒体核糖体作为细胞器中的翻译机器,与细菌核糖体以及真核细胞质核糖体在rRNA和蛋白质组分、拓扑结构、来源等方面差异显著。本文综述线粒体核糖体研究进展,对比分析其理化性质和实验结构的相似性与特殊性。基于线粒体核糖体的结构和生物学功能进一步推测:经过与tRNA的相互识别和空间取向,mRNA链构象能否影响其编码产物——新生肽链的构象,期望揭示mRNA在翻译过程中可能的作用机理。     

真核细胞tRNA的降解

tRNA在蛋白质合成过程中起着关键性的作用,不但为三联密码子翻译成氨基酸提供了接合体,而且为将氨基酸运送到核糖体提供了运送载体.在真核细胞中,tRNA前体必须经过广泛的加工修饰,成为成熟的tRNA分子才能充分发挥生物学功能.以往对tRNA的研究主要集中于tRNA的结构、功能、加工和成熟上,却很少关注tRNA分子的降解.最近研究发现tRNA的降解在tRNA的生成、加工和功能发挥上同样起着重要作用.     

核糖体结构研究中的里程碑

核糖体是一个以RNA和蛋白质为基础的合成蛋白质的分子机器.其复杂的结构使它长期被结晶学家视为该研究领域中的喜马拉雅山.最近在核糖体结构研究中的突破性进展,首次在核糖体及其亚基高度复杂的电子密度图上定位了几种已知三维结构的蛋白质和许多双链rRNA区,并揭示了亚基界面的精细结构和tRNA、mRNA和核糖体间复杂的相互作用.     

“严谨反应”还是“严紧反应”?

“Stringent response”是指细菌在遭受营养饥饿与环境胁迫时,由代谢酶RelA/SpoT催化合成信号分子鸟苷四/五磷酸[(p)ppGpp],从而诱导细菌细胞关闭rRNA、tRNA及核糖体蛋白基因转录,停止多种蛋白质的翻译,严控大部分代谢活动的一系列适应性基因表达过程。“Stringent response”几乎是所有细菌应对逆境的重要调节机制。目前,国内文献对“stringent response”的中文翻译存在“严谨反应”和“严紧反应”混用的现象。基于此,本文对“stringent response”的调控机制、生理功能及字面含义进行了分析,认为“stringent response”翻译为“严紧反应”更为合理、准确。     

真核翻译起始因子5A在蛋白质合成中的功能及机制

在蛋白质合成过程中,除核糖体、氨酰 tRNA和mRNA外,还有多种翻译因子参与其中。真核翻译起始因子5A（eukaryotic translation initiation factor 5A, eIF5A）是维持细胞活性必不可少的翻译因子,在进化上高度保守。eIF5A是真核细胞中唯一含有羟腐胺赖氨酸（hypusine）的蛋白质,该翻译后修饰对eIF5A的活性至关重要。1978年,人们首次鉴定出eIF5A,认为它在翻译起始阶段促进第1个肽键的形成。直到2013年才证实它主要在翻译延伸阶段调控含多聚脯氨酸基序蛋白质的翻译。在经过四十多年研究后,人们对eIF5A的功能有了新的认识。近期基于核糖体图谱数据的分析表明,eIF5A能够缓解翻译延伸过程中核糖体在多种基序处的停滞,并不局限于多聚脯氨酸基序,并且它还能够通过促进肽链的释放增强翻译终止。此外,eIF5A还可以通过调控某些蛋白质的翻译,间接影响细胞内的各种生命活动。本文综述了eIF5A的多种翻译后修饰、在蛋白质合成和细胞自噬过程中的调控作用以及与人类疾病的关系,并与细菌及古细菌中的同源蛋白质进行了比较,探讨了该因子在进化中的保守性,以期为相关领域的研究提供一定的理论基础。     

核糖体展示研究进展

核糖体展示是一种无细胞系统,可以从文库中筛选蛋白质和多肽。翻译的蛋白质及其mRNA同时结合在核糖体上形成mRNA-核糖体-蛋白质三聚体,通过配体亲和分离得到功能性蛋白及其编码的mRNA,转换成对应的DNA后进行相关蛋白的表达,可用于抗体及蛋白质文库选择、蛋白质体外改造等,而且其可以展示较大的文库而不受细菌转化的限制,可对毒蛋白、蛋白酶敏感和不稳定的蛋白质进行筛选,也可在特定位点进行氨基酸修饰。就核糖体展示技术的研究进展及其在蛋白质进化和筛选方面的应用进行综述。     

A new view of protein synthesis: mapping the free energy landscape of the ribosome using single-molecule FRET

This article reviews the application of single-molecule fluorescence resonance energy transfer (smFRET) methods to the study of protein synthesis catalyzed by the ribosome. smFRET is a powerful new technique that can be used to investigate dynamic processes within enzymes spanning many orders of magnitude. The application of wide-field smFRET imaging methods to the study of dynamic processes in the ribosome offers a new perspective on the mechanism of protein synthesis. Using this technique, the structural and kinetic parameters of tRNA motions within wild-type and specifically mutated ribosome complexes have been obtained that provide valuable new insights into the mechanism and regulation of translation elongation. The results of these studies are discussed in the context of current knowledge of the ribosome mechanism from both structural and biophysical perspectives.     

Single-molecule fluorescence measurements of ribosomal translocation dynamics

We employ single-molecule fluorescence resonance energy transfer (smFRET) to study structural dynamics over the first two elongation cycles of protein synthesis, using ribosomes containing either Cy3-labeled ribosomal protein L11 and A- or P-site Cy5-labeled tRNA or Cy3- and Cy5-labeled tRNAs. Pretranslocation (PRE) complexes demonstrate fluctuations between classical and hybrid forms, with concerted motions of tRNAs away from L11 and from each other when classical complex converts to hybrid complex. EF-G?GTP binding to both hybrid and classical PRE complexes halts these fluctuations prior to catalyzing translocation to form the posttranslocation (POST) complex. EF-G dependent translocation from the classical PRE complex proceeds via transient formation of a short-lived hybrid intermediate. A-site binding of either EF-G to the PRE complex or of aminoacyl-tRNA?EF-Tu ternary complex to the POST complex markedly suppresses ribosome conformational lability.     

Coupling of ribosomal L1 stalk and tRNA dynamics during translation elongation

By using single-molecule fluorescence resonance energy transfer (smFRET), we observe the real-time dynamic coupling between the ribosome, labeled at the L1 stalk, and transfer RNA (tRNA). We find that an interaction between the ribosomal L1 stalk and the newly deacylated tRNA is established spontaneously upon peptide bond formation; this event involves coupled movements of the L1 stalk and tRNAs as well as ratcheting of the ribosome. In the absence of elongation factor G, the entire pretranslocation ribosome fluctuates between just two states: a nonratcheted state, with tRNAs in their classical configuration and no L1 stalk-tRNA interaction, and a ratcheted state, with tRNAs in an intermediate hybrid configuration and a direct L1 stalk-tRNA interaction. We demonstrate that binding of EF-G shifts the equilibrium toward the ratcheted state. Real-time smFRET experiments reveal that the L1 stalk-tRNA interaction persists throughout the translocation reaction, suggesting that the L1 stalk acts to direct tRNA movements during translocation.     

Dynamics of the translational machinery

The recent growth in single molecule studies of translation has provided an insight into the molecular mechanism of ribosomal function. Single molecule fluorescence approaches allowed direct observation of the structural rearrangements occurring during translation and revealed dynamic motions of the ribosome and its ligands. These studies demonstrated how ligand binding affects dynamics of the ribosome, and the role of the conformational sampling in large-scale rearrangements intrinsic to translation elongation. The application of time-resolved cryo-electron microscopy revealed new conformational intermediates during back-translocation providing an insight into ribosomal dynamics from an alternative perspective. Recent developments permitted examination of conformational and compositional dynamics of the ribosome in real-time through multiple cycles of elongation at the single molecule level. The zero-mode waveguide approach allowed direct observation of the compositional dynamics of tRNA occupancy on the elongating ribosome. The emergence of single molecule in vivo techniques provided insights into the mechanism and regulation of translation at the organismal level.     

The ribosome as a molecular machine: the mechanism of tRNA-mRNA movement in translocation

Translocation of tRNA and mRNA through the ribosome is one of the most dynamic events during protein synthesis. In the cell, translocation is catalysed by EF-G (elongation factor G) and driven by GTP hydrolysis. Major unresolved questions are: how the movement is induced and what the moving parts of the ribosome are. Recent progress in time-resolved cryoelectron microscopy revealed trajectories of tRNA movement through the ribosome. Driven by thermal fluctuations, the ribosome spontaneously samples a large number of conformational states. The spontaneous movement of tRNAs through the ribosome is loosely coupled to the motions within the ribosome. EF-G stabilizes conformational states prone to translocation and promotes a conformational rearrangement of the ribosome (unlocking) that accelerates the rate-limiting step of translocation: the movement of the tRNA anticodons on the small ribosomal subunit. EF-G acts as a Brownian ratchet providing directional bias for movement at the cost of GTP hydrolysis.     

Cleavage of the sarcin–ricin loop of 23S rRNA differentially affects EF-G and EF-Tu binding

Ribotoxins are potent inhibitors of protein biosynthesis and inactivate ribosomes from a variety of organisms. The ribotoxin α-sarcin cleaves the large 23S ribosomal RNA (rRNA) at the universally conserved sarcin–ricin loop (SRL) leading to complete inactivation of the ribosome and cellular death. The SRL interacts with translation factors that hydrolyze GTP, and it is important for their binding to the ribosome, but its precise role is not yet understood. We studied the effect of α-sarcin on defined steps of translation by the bacterial ribosome. α-Sarcin-treated ribosomes showed no defects in mRNA and tRNA binding, peptide-bond formation and sparsomycin-dependent translocation. Cleavage of SRL slightly affected binding of elongation factor Tu ternary complex (EF-Tu•GTP•tRNA) to the ribosome. In contrast, the activity of elongation factor G (EF-G) was strongly impaired in α-sarcin-treated ribosomes. Importantly, cleavage of SRL inhibited EF-G binding, and consequently GTP hydrolysis and mRNA–tRNA translocation. These results suggest that the SRL is more critical in EF-G than ternary complex binding to the ribosome implicating different requirements in this region of the ribosome during protein elongation.     

Elongation factors on the ribosome

The ribosome is a complex macromolecular assembly capable of translating mRNA sequence into amino acid sequence. The adaptor molecule of translation is tRNA, but the delivery of aminoacyl-tRNAs--the primary substrate of the ribosome--relies on the formation of a ternary complex with elongation factor Tu (EF-Tu) and GTP. Likewise, elongation factor G (EF-G) is required to reset the elongation cycle through the translocation of tRNAs. Recent structures and biochemical data on ribosomes in complex with the ternary complex or EF-G have shed light on the mode of action of the elongation factors, and how this interplays with the state of tRNAs and the ribosome. A model emerges of the specific routes of conformational changes mediated by tRNA and the ribosome that trigger the GTPase activity of the elongation factors on the ribosome.     

Ribosome as a molecular machine

General principles of structure and function of the ribosome are surveyed, and the translating ribosome is regarded as a molecular conveying machine. Two coupled conveying processes, the passing of compact tRNA globules and the drawing of linear mRNA chain through intraribosomal channel, are considered driven by discrete acts of translocation during translation. Instead of mechanical transmission mechanisms and power-stroke 'motors', thermal motion and chemically induced changes in affinities of ribosomal binding sites for their ligands (tRNAs, mRNA, elongation factors) are proposed to underlie all the directional movements within the ribosomal complex. The GTP-dependent catalysis of conformational transitions by elongation factors during translation is also discussed.     

Dynamics of translation on the ribosome: molecular mechanics of translocation

The translocation step of protein elongation entails a large-scale rearrangement of the tRNA-mRNA-ribosome complex. Recent years have seen major advances in unraveling the mechanism of the process on the molecular level. A number of intermediate states have been defined and, in part, characterized structurally. The article reviews the recent evidence that suggests a dynamic role of the ribosome and its ligands during translocation. The focus is on dynamic aspects of tRNA movement and on the role of elongation factor G and GTP hydrolysis in translocation catalysis. The significance of structural changes of the ribosome induced by elongation factor G as well the role of ribosomal RNA are addressed. A functional model of elongation factor G as a motor protein driven by GTP hydrolysis is discussed.