mRNA的序列,结构以及翻译速率与蛋白质结构的关系

ｍＲＮＡ所包含的核苷酸序列通过三联体密码子决定了蛋白质的氨基酸序列,但是,由于对氨基酸同义密码使用频率上的差异,密码子与反密码子相互作用效率上的不同,以及密码子上下文关系和ｍＲＮＡ不同区域二级结构上的差异,造成了核糖体对ｍＲＮＡ不同区域翻译速度上的差异,加之共翻译折叠的作用,使得ｍＲＮＡ的序列和结构影响着蛋白质空间结构的形成。     

同义密码子用语与蛋白质结构的关系

对大肠杆菌的５４种三维结构已知的蛋白质及其对应的ｍＲＮＡ序列的集合的分析结果表明,绝大部分密码子与其编码的氨基酸在蛋白质α螺旋、β折叠和卷曲等三种二级结构中的偏好性没有显著的统计性差异。同时,又对Ａｄｚｈｕｂｅｉ提供的相应哺乳类数据集作了同样的偏好性检验,表明９种氨基酸的同义密码子携带蛋白质二级结构信息,与他们的结论一致。推测,这种差异可能由翻译机制的进化趋异造成的。这些结果对于真核基因在原核生物中实现高表达可能有重要的实际意义。     

真核细胞中多重表达框mRNA的选择性翻译起始

扫描模型和遗漏扫描模型是真核生物mRNA翻译起始的两种主要机制,但其仍存在某些例外情况,如对具有多顺反子结构的mRNA,选择性翻译起始的发生机制目前仍不清楚.本研究基于GFP蛋白开放表达框(ORF)构建了一系列重组表达载体,用以转录在移码翻译顺序及同一翻译顺序下,AUG起始密码子处于不同序列背景,以及间隔不同距离的多顺反子结构mRNA.通过转染人Bel 7402细胞系,研究了这些多顺反子结构mRNA的翻译起始模式.结果表明,在移码翻译顺序下,多顺反子mRNA可翻译出对应的不同蛋白质,而在同一翻译顺序下,GFP蛋白表达框中的多个AUG密码子,仅有首位起始密码子可发挥作用,提示核糖体在从首位起始密码子开始翻译的同时,可能会有部分核糖体继续向下扫描并识别下游的起始密码子,而这种选择性的翻译起始效率,主要取决于密码子所处的序列背景及间隔距离等因素.     

翻译速率与蛋白质二级结构的关系

统计分析了人的 119种蛋白质和大肠杆菌的 92种蛋白质密码子翻译速率和蛋白质二级结构的关系。据m 密码子片段在不同二级结构中的频数分布 ,我们发现人和大肠杆菌中翻译速率与蛋白质二级结构之间有一定关系 :高翻译速率时倾向编码α螺旋、不倾向编码线团 (coil) ;低翻译速率时倾向编码线团、不倾向编码α螺旋 ;β折叠结构则随翻译速率表现出明显的振荡。同时 ,密码子的使用在不同片段内一般也是不均匀的 :在α螺旋片段内 ,结构尾部偏向使用高翻译速率密码子 ;中部倾向使用中翻译速率密码子 ;而头部使用的密码子翻译速率偏低。这样的倾向性不大可能归结为随机起伏的影响。     

同义密码子使用模式对蛋白产物表达及构象形成的影响*

鉴于遗传密码子的简并性能够将基因遗传信息的容量提升,同义密码子使用偏嗜性得以在生物体的基因组中广泛存在。虽然同义密码子之间碱基的变化并不能导致氨基酸种类的改变,在研究mRNA半衰期、编码多肽翻译效率及肽链空间构象正确折叠的准确性和翻译等这一系列过程中发现,同义密码子使用的偏嗜性在某种程度上通过精微调控翻译机制体现其遗传学功能。同义密码子指导tRNA在翻译过程中识别核糖体的速率变化是由氨基酸的特定顺序决定,并且在新生多肽链合成时,蛋白质共翻译转运机制同时调节其空间构象的正确折叠从而保证蛋白的正常生物学功能。某些同义密码子使用偏嗜性与特定蛋白结构的形成具有显著相关性,密码子使用偏嗜性一旦改变将可能导致新生多肽空间构象出现错误折叠。结合近些年来国内外在此领域的研究成果,阐述同义密码子使用偏嗜性如何发挥精微调控翻译的生物学功能与作用。     

密码子中的密码:密码子偏好性与基因表达的精细调控

同义突变由于不改变编码蛋白质的氨基酸序列,常被认为是"沉默"突变.实际上,同义密码子的选择在进化尺度上是受到限制的,从而致使同义密码子的使用频率存在差异,称为密码子偏好性.密码子偏好性在转录、转录后加工、mRNA稳定性、翻译起始、延伸、蛋白折叠等方面都起着精细调节的作用.因此,同义突变在很多情况下可导致癌症等各类疾病的发生.本综述在分子机制层面简述了近年来关于密码子偏好性对翻译和转录过程调节作用的进展,以及对于基础研究及医学方面的意义.     

mRNA翻译起始区二级结构改变对干扰素基因在大肠杆菌中翻译的影响

为研究mRNA翻译起始区结构与基因表达的关系,利用密码子的简并性,在不改变表达产物氨基酸序列的前提下定点突变α8干扰素及αA干扰素衍生物基因的5′端若干位点,使其与表达载体重组后转录形成的mRNA翻译起始区结构发生改变。SDS-PAGE及活性测定证实这些改变提高了外源基因的表达水平。RNA斑点印迹表明突变前后基因转录水平差别不大,表达水平的提高主要由于翻译效率的提高。mRNA翻译起始区二级结构预测提示其生成自由能(ΔG)的变化可能与表达水平的提高有关。     

同义密码子的反常蛋白质二级结构偏好性

统计分析了 119种人蛋白质和 92种大肠杆菌蛋白质的mRNA序列和蛋白质二级结构的关系 .从二肽频数出发 ,研究了同义密码子使用对蛋白质二级结构的影响 ,证明其影响在 10 %到 2 0 %的量级 .对于人和大肠杆菌 ,在 90 %置信水平上 ,4 0 0对二肽中分别有 79对和 6 0对 ,在 95 %置信水平上 ,分别有 4 5对和 36对二肽的相应密码子二联体具有不同于氨基酸的反常二级结构偏好性 ,并且这种反常不能归因于随机涨落     

同义密码子使用偏嗜性对mRNA半衰期及翻译调控的影响北大核心CSCD

随着基因组学和转录组学在不同生物体遗传和细胞生物学领域的广泛应用,同义密码子使用的偏嗜性逐渐被接受,并且在研究生物进化与生物表型之间的深层联系时,同义密码子使用模式受到相关领域研究人员的重视。信使RNA(messenger RNA,mRNA)最终表达出具有正常生物活性的蛋白产物是生命活动的重要环节。被称为“第二遗传密码”的同义密码子使用模式,可以通过精微调控翻译选择压力等分子机制,从转录调控、翻译调控及代谢活动等水平表达其承载的遗传信息。研究表明,mRNA半衰期的长短对mRNA活性以及转录和翻译过程有显著的影响。因此,系统地归纳同义密码子使用模式在基因转录、翻译调控及翻译后修饰等生命活动中所扮演的角色,将有助于全方位审视生物体如何巧妙利用密码子使用模式所产生的遗传效应来精准合成不同种类蛋白质,并以此保障生长或分化的特定基因表达程序顺利执行、维持正常的生命周期。     

同义密码子使用模式对多肽链共翻译折叠的影响研究进展

同义密码子使用模式作为核苷酸与氨基酸的纽带,其多样性介导了核糖体扫描速率,同时扩充了基因的遗传信息存储量。随着新型技术的应用,发现特异性密码子和密码子结合力可调节核糖体扫描速率并影响蛋白质构象。同义密码子使用模式通过多种方式在不同环节影响着核糖体扫描速率,同时还影响着自身mRNA的稳定性。本文简述了密码子使用模式如何在核糖体扫描翻译mRNA的过程中实现对多肽链翻译延伸的调控,为今后生物工程学领域如何优化蛋白高效表达提供可参考的思路与理念。     

The relation between mRNA folding and protein structure

About 200 mRNA sequences of Escherichia coli and human with matching protein secondary structure data were studied. The mRNA folding for each native sequence and for corresponding randomized sequences was calculated through free energy minimization. We have found that the folding energy of mRNA segments in different protein secondary structures is significantly different. The average Z score is more negative for regular secondary structure (alpha-helix and beta-strand) than that for coil. This suggests that the codon choice in native mRNA sequence coding for protein regular structure contributes more to the mRNA folding stability.     

ACG, the initiator codon for a Sendai virus protein

Deletion and site-directed point mutants of the polycistronic P/C mRNA of Sendai virus revealed that one of the nonstructural proteins of this virus, the C' protein, initiates from an ACG codon. This ACG codon occurs in an optimum sequence context and precedes the first AUG of the P/C mRNA. The results presented in this communication are consistent with the concept that the ribosomes scan the P/C mRNA to initiate several proteins from its different initiator codons. The arrangement of several weak initiator codons in tandem in an mRNA, i.e. non-AUG in optimum sequence context and AUG in suboptimum sequence context, may represent an alternate means to regulate gene expression in eukaryotes and their viruses.     

SBP,SECIS binding protein,binds to the RNA fragment upstream of the Sec UGA codon in glutathione peroxidase mRNA

In mammals, most of the selenium contained in the body is present as an unusual amino acid, selenocysteine (Sec), whose codon is UGA. Because the UGA codon is typically recognized as a translation stop signal, it is intriguing how a cell recognizes and distinguishes a UGA Sec codon from a UGA stop codon. For eukaryotic selenoprotein mRNAs, it has been proposed that a conserved stem-loop structure designated the Sec insertion sequence (SECIS) in the 3'-untranslated (3'-UTR) region is required for recognition of UGA as a Sec codon. Some proteins which bind to SECIS (SBP) have been reported. However, it is not clear how the SECIS element in the 3'-UTR can mediate Sec insertion far at the in-frame UGA Sec codons. The idea that there must be a signal near the UGA Sec codon is still considered. Therefore, we searched for a protein which binds to an RNA sequence surrounding the UGA Sec codon on human glutathione peroxidase (GPx) mRNA. We found a protein which strongly bound to the RNA fragment upstream of the UGA Sec codon. However, this protein did not bind to the RNA sequence downstream of the UGA codon. This protein also bound to the SECIS sequence in the 3'-UTR of human GPx, and this binding to SECIS was competed with the RNA fragment upstream of the UGA Sec codon. Comparison of the RNA fragment with the SECIS fragment identified the conserved regions, which appeared in the region upstream of the in-frame UGA Sec codon of Se-protein mRNAs. Thus, this study proposes a novel model to understand the mechanisms of Sec incorporation at the UGA Sec codon, especially the regions upstream of the UGA codon of mRNAs of mammalian selenoproteins. This model explains that the stem-loop structure covering the UGA codon is recognized by SBP and how the UGA Sec codon escapes from attack by eRF of the peptide releasing factor.     

Polyamine stimulation of the synthesis of oligopeptide-binding protein (OppA). Involvement of a structural change of the Shine-Dalgarno sequence and the initiation codon aug in oppa mRNA.

We previously suggested that the degree of polyamine stimulation of oligopeptide-binding protein (OppA) synthesis is dependent on the secondary structure and position of the Shine-Dalgarno (SD) sequence of OppA mRNA. To study the structural change of OppA mRNA induced by polyamines and polyamine stimulation of initiation complex formation, four different 130-mer OppA mRNAs containing the initiation region were synthesized in vitro. The structural change of these mRNAs induced by polyamines was examined by measuring their sensitivity to RNase T(1), specific for single-stranded RNA, and RNase V(1), which recognizes double-stranded or stacked RNA. In parallel, the effect of spermidine on mRNA-dependent fMet-tRNA binding to ribosomes was examined. Our results indicate that the secondary structure of the SD sequence and initiation codon AUG is important for the efficiency of initiation complex formation and that spermidine relaxes the structure of the SD sequence and the initiation codon AUG. The existence of a GC-rich double-stranded region close to the SD sequence is important for spermidine stimulation of fMet-tRNA binding to ribosomes. Spermidine apparently binds to this GC-rich stem and causes a structural change of the SD sequence and the initiation codon, facilitating an interaction with 30 S ribosomal subunits.     

不同结构的蛋白编码基因的密码子偏性研究

利用聚类分析方法,对两类具有不同三级结构的75个蛋白的编码基因的密码子使用偏性进行了分析。75个基因样本序列按照对应蛋白的三级结构被很清晰的分成了两类,从而发现密码子的使用与蛋白质的三级结构有很大的相关性。这一重要结果证实了DNA的一维信息中蕴含着蛋白质的三级结构信息。     

A computational framework for the design of optimal protein synthesis

Despite the establishment of design principles to optimize codon choice for heterologous expression vector design, the relationship between codon sequence and final protein yield remains poorly understood. In this work, we present a computational framework for the identification of a set of mutant codon sequences for optimized heterologous protein production, which uses a codon-sequence mechanistic model of protein synthesis. Through a sensitivity analysis on the optimal steady state configuration of protein synthesis we are able to identify the set of codons, that are the most rate limiting with respect to steady state protein synthesis rate, and we replace them with synonymous codons recognized by charged tRNAs more efficient for translation, so that the resulting codon-elongation rate is higher. Repeating this procedure, we iteratively optimize the codon sequence for higher protein synthesis rate taking into account multiple constraints of various types. We determine a small set of optimized synonymous codon sequences that are very close to each other in sequence space, but they have an impact on properties such as ribosomal utilization or secondary structure. This limited number of sequences can then be offered for further experimental study. Overall, the proposed method is very valuable in understanding the effects of the different properties of mRNA sequences on the final protein yield in heterologous protein production and it can find applications in synthetic biology and biotechnology.     

枯草芽孢杆菌同义密码子使用偏性对蛋白质折叠速率的影响

目前,有关同义密码子使用偏性对蛋白质折叠的影响研究中,样本蛋白均来源于不同的物种。考虑到同义密码子使用偏性的物种差异性,选取枯草杆菌的核蛋白为研究对象。首先,将每条核蛋白按二级结构截取为α螺旋片段、β折叠片段和无规卷曲（α-β混合）片段,并计算其蛋白质折叠速率。然后,整理每个片段相应的核酸序列信息,计算其同义密码子使用度。在此基础上,分析枯草芽孢杆菌核蛋白的同义密码子使用偏性与蛋白质折叠速率的相关性。发现对于不同二级结构的肽链片段,都有部分密码子的使用偏性与其对应的肽链折叠速率显著相关。进一步分析发现,与肽链片段折叠速率显著相关的密码子绝大部分为枯草杆菌全序列或核蛋白序列的每一组同义密码子中使用度最高的密码子。结果表明,在蛋白质的折叠过程中,枯草芽孢杆菌的同义密码子使用偏性起着重要作用。