无细胞体系非天然蛋白质合成研究进展

无细胞非天然蛋白质合成作为蛋白质研究的新兴手段,已成功用于表征蛋白质分子间、蛋白质与核酸分子间相互作用等基础科学研究及医药蛋白、蛋白质材料等工业生产领域。无细胞非天然蛋白质合成系统不需维持细胞的生长,无细胞膜阻碍,可依据研究目的添加基因元件或化学物质从而增强工程设计和过程调控的自由性;也可赋予蛋白质新的特性、结构及功能,如可实现蛋白翻译后修饰、反应手柄引入、生物物理探针及多聚蛋白质合成等。文中系统地综述了目前应用于无细胞蛋白质合成系统中的非天然氨基酸嵌入方法,包括全局抑制及基于正交翻译体系的终止密码子抑制、移码抑制、有义密码子再分配和非天然碱基等方法的研究进展,及非天然氨基酸在蛋白质修饰、生物物理探针、酶工程、蛋白质材料以及医药蛋白质生产等领域的应用进展,并分析了该体系的发展前景及广泛工业化应用的机遇与挑战。     

糖-蛋白质相互作用在酶固定及蛋白质识别与分离中的应用

近些年来,糖-蛋白质相互作用的研究越来越受到研究人员的重视,它在生命过程中发挥着重要的作用,是生命体中信号传导、免疫应答、细胞黏附、病菌感染、受精、增殖、分化等许多细胞识别过程的基础。依据糖的类型不同对糖-蛋白质相互作用作了三个方面的应用总结:应用于酶的固定化,主要有壳聚糖,淀粉,琼脂糖,纤维素等多糖;应用于蛋白质的识别,主要是一些糖类芯片;应用于蛋白质的分离,主要有琼脂糖,肝素/硫酸类肝素,葡聚糖等。最后,对糖-蛋白质相互作用在生物化学领域的意义作了展望。     

基于古菌酪氨酰tRNA合成酶非天然氨基酸插入的研究进展

构筑蛋白质的编码信息存在于高度保守的密码子表中,而生物体仅利用20种天然氨基酸,就能排列组合出不同的蛋白质来行使多种生物学功能。通过合成生物学的飞速发展,使得在蛋白质合成中可控地引入非天然氨基酸成为可能。这极大地拓展了蛋白质的结构和功能,并为生物学工具的开发和生物生理过程的研究提供了便利。具有活性基团的非天然氨基酸可以广泛地应用于蛋白质结构研究、蛋白质功能调控以及新型生物材料构建和医药研发等诸多领域。基因密码子拓展技术利用正交翻译系统,通过重新分配密码子改造中心法则,可以在蛋白质的指定位点引入非天然氨基酸。系统地介绍了目前提升密码子拓展技术插入非天然氨基酸效率的方法,包括tRNA以及氨酰tRNA合成酶的各种突变方法和翻译辅助因子的改造。汇总了利用古细菌酪氨酰tRNA合成酶插入的非天然氨基酸和突变位点并总结了密码子拓展技术在生物医药领域的前沿进展。最后讨论了该项技术目前所面临的挑战,如可利用的密码子数量不多、正交翻译系统的种类有限和非天然氨基酸多插效率低下。希望能够帮助研究者建立适合的非天然氨基酸插入方法并推动密码子拓展技术进一步发展。     

蓝藻的蛋白质翻译后修饰研究进展

蛋白质翻译后修饰系统几乎参与了细胞所有的正常生命活动过程,并发挥着重要的调控作用。目前,基于生物质谱技术进行蛋白质翻译后修饰的规模化分析鉴定,已经成为蛋白质组学研究的核心内容之一。近年来的研究表明,蓝藻细胞中存在着复杂的蛋白质翻译后修饰系统,如磷酸化,乙酰化,甲基化,糖基化,氧化等,这些翻译后修饰在蓝藻细胞的代谢过程中可能发挥着重要的调控作用。本文主要针对蓝藻细胞中蛋白质翻译后修饰的发现与鉴定,以及翻译后修饰潜在的生物学功能展开简要综述。     

泛素、泛素链和蛋白质泛素化研究进展

蛋白质泛素化是以泛素单体和泛素链作为信号分子,共价修饰细胞内其他蛋白质的一种翻译后修饰形式。不同蛋白质底物、同一底物的不同氨基酸修饰位点以及同一位点上泛素链连接方式的不同均可导致细胞效应的差异。蛋白质泛素化在真核细胞内广泛存在,除了介导蛋白质的26S蛋白酶体降解途径之外,还广泛参与了基因转录、蛋白质翻译、信号传导、细胞周期控制以及生长发育等几乎所有的生命活动过程。泛素链的形成及其修饰过程的任何失调均可导致生物体内环境的紊乱,从而产生严重的疾病。文中结合实验室研究,综述了泛素的发现历史、基因特点、晶体结构,特别是泛素链的组装过程、结构、功能以及与人类相关疾病关系的新进展,可为这些疾病的治疗靶点和药物靶标的研究提供思路。     

PNAS:人工合成小蛋白提示癌症发生新线索

<正>近日,来自耶鲁大学的科学家们在国际学术期刊PNAS上发表了一项最新研究进展,他们通过化学合成的方法合成了一些简易蛋白分子,这些蛋白分子几乎不存在化学多样性,但仍然能够在调节细胞功能方面发挥特定作用。所有的生命都需要依赖蛋白质的功能,蛋白质的作用范围也非常广泛,目前已经知道这种功能多样性主要是由于成百上千的氨基酸形成特定序列,再经过蛋白质的加工和修饰过程形成特定的蛋白质结构实现的。这些氨基酸的侧链使得蛋白质呈现出巨大的化学多样性,更是形成众多     

蛋白质组学在细胞凋亡研究中的应用

细胞凋亡是一种遗传决定的在多细胞生物生长发育和稳态维持中发挥重要作用的细胞程序性死亡. 正常细胞中细胞凋亡程序受精细调控, 而肿瘤、自身免疫性疾病等多种疾病的发生与细胞凋亡的失调密切相关, 因此对其分子机制的研究备受关注. 在过去的20多年研究中, 发现很多凋亡相关的蛋白质被翻译后机制调控, 包括蛋白质剪切、转位、蛋白质相互作用和各种翻译后修饰等, 这些正是蛋白质组学的研究范畴. 近年来, 蛋白质组学技术飞速发展, 并与遗传学和化学生物学等学科交叉, 推动了功能蛋白质组学和化学/药物蛋白质组学的发展, 并被迅速地应用于细胞凋亡研究领域, 有对细胞凋亡研究产生重要影响的潜力. 本文综述了近年来本实验室及国际上运用蛋白质组学技术和策略研究细胞凋亡的主要进展, 同时展望了蛋白质组学在凋亡研究领域的方向和挑战.     

亮氨酰-tRNA合成酶通过细胞内的亮氨酸调节雷帕霉素受体复合物（TORC1）活性的新功能

TORC1（target of rapamycin complex 1）可整合营养、能量、生长因子及氨基酸等多种细胞外信号,调控基因转录、蛋白质翻译、核糖体合成等生物过程,在细胞生长和凋亡中发挥极为重要的作用。亮氨酰-tRNA合成酶（LeuRS）的经典功能是催化合成亮氨酰-tRNA直接参与遗传信息的解码合成蛋白质。最新研究结果表明人细胞质LeuRS除了经典功能外,还参与调控TORC1途径。综述了LeuRS的非经典功能,它是如何通过感受细胞内的亮氨酸浓度来调节TORC1活性的。这些结果表明了古老的氨基酰-tRNA合成酶家族在进化的过程中被赋予了新的功能。     

氨酰tRNA合成酶的分子网络和功能

氨酰tRNA合成酶是生命进化过程中最早出现的一类蛋白质,氨酰tRNA合成酶帮助氨基酸转移到相应的tRNA上,进而参与蛋白质的合成保证了生命体的严谨性和多样性.随着后基因组时代的到来,氨酰tRNA合成酶的结构和功能成为新的研究热点.结构生物学和生物信息学的研究结果表明,氨酰tRNA合成酶在真核生物体内以多聚复合物的形式行使功能,形成复杂的分子网络体系.最新的实验证据显示,氨酰tRNA合成酶不但是蛋白质合成过程中一类最重要的酶,而且参与了转录、翻译水平的调控、RNA剪接、信号传导和免疫应答等众多生命活动.     

翻译后修饰调控TRPV亚家族通道功能的研究进展

瞬时受体势(transient receptor potential,TRP)通道广泛分布于神经和非神经系统中,响应温度、化学和机械等多种刺激,在机体对外界环境的精确感知中发挥重要功能.根据蛋白质序列的相似性,哺乳动物中TRP通道家族的27个成员分属TRPA、TRPC、TRPM、TRPML、TRPP和TRPV 6个亚家族.其中TRPV亚家族包含了6个成员,分别为温度敏感型的TRPV1~4通道,以及对Ca2+具有高选择通透能力的TRPV5和TRPV6通道.研究结果表明,TRPV亚家族通道参与调控细胞内的离子稳态和信号传导,在温度感知和血管扩张等生理过程中发挥作用,并与癌症、心血管等多种疾病的发生和发展密切相关.翻译后修饰(post-translational modifications,PTMs)是翻译中或者翻译后在蛋白质特定氨基酸上添加或删减修饰官能团的过程.越来越多的研究结果表明,TRPV亚家族通道同样可以发生翻译后修饰,并对通道功能产生重要影响.本文综述了目前已报道的磷酸化、糖基化、泛素化、SUMO化和共价修饰等多种翻译后修饰调控TRPV亚家族成员功能的主要研究进展,以期为进一步研究翻译后修饰对TRPV通道的功能调节提供参考,丰富我们对蛋白质翻译后修饰与生理或病理活动相关性的认识.     

Synthesis of proteins with defined posttranslational modifications using the genetic noncanonical amino acid incorporation approach

Posttranslational modifications modulate the activities of most eukaryotic proteins and play a critical role in all aspects of cellular life. Understanding functional roles of these modifications requires homogeneously modified proteins that are usually difficult to purify from their natural sources. An emerging powerful tool for synthesis of proteins with defined posttranslational modifications is to genetically encode modified amino acids in living cells and incorporate them directly into proteins during the protein translation process. Using this approach, homogenous proteins with tyrosine sulfation, tyrosine phosphorylation mimics, tyrosine nitration, lysine acetylation, lysine methylation, and ubiquitination have been synthesized in large quantities. In this review, we provide a brief introduction to protein posttranslational modifications and the genetic noncanonical amino acid (NAA) incorporation technique, then discuss successful applications of the genetic NAA incorporation approach to produce proteins with defined modifications, and end with challenges and ongoing methodology developments for synthesis of proteins with other modifications.     

On the origin of the translation system and the genetic code in the RNA world by means of natural selection, exaptation, and subfunctionalization

Background  

The origin of the translation system is, arguably, the central and the hardest problem in the study of the origin of life, and one of the hardest in all evolutionary biology. The problem has a clear catch-22 aspect: high translation fidelity hardly can be achieved without a complex, highly evolved set of RNAs and proteins but an elaborate protein machinery could not evolve without an accurate translation system. The origin of the genetic code and whether it evolved on the basis of a stereochemical correspondence between amino acids and their cognate codons (or anticodons), through selectional optimization of the code vocabulary, as a "frozen accident" or via a combination of all these routes is another wide open problem despite extensive theoretical and experimental studies. Here we combine the results of comparative genomics of translation system components, data on interaction of amino acids with their cognate codons and anticodons, and data on catalytic activities of ribozymes to develop conceptual models for the origins of the translation system and the genetic code.     

Rare codons in E. coli and S. typhimurium signal sequences

Codon usage has been examined in the signal sequences of 27 genes encoding proteins which possess leader peptides, and are inner-membrane located or exported. The results have been compared with codon usage in the corresponding coding sequences of most of the mature proteins. A bias is observed in the usage of rare codons for two of the three hydrophobic amino acids for which there are rare codons. Since hydrophobic residues are predominant in leader peptides, we suggest that a resulting concentration of rare codons in the signal sequence may play a role (or have played a role in the evolutionary past) in the secretion process by delaying translation.     

Chemical and catalytical properties of thermal polymers of amino acids (proteinoids)

The significance of thermal polyamino acids (proteinoids) as abiotic predecessors of proteins is reviewed on the basis of new experimental results. Most proteinoids yield only 50% to 80% amino acid upon acid hydrolysis. They contain 40% to 60% less peptide links than typical proteins, whereas their average nitrogen content is like that of proteins. The arrangement of amino acid residues is nonrandom. The degree of nonrandomness is difficult to determine because unusual crosslinks disturb most of the sequencing methods typically applied, in protein chemistry. The products obtained in a polymerization experiment are heterogeneous. They can be separated into a limited number of related fractions by chromatography or electrophoresis and other separation methods applied in protein chemistry. Their molecular weights are typically between 400 and 10 000. The number of free NH₂-groups, is usually smaller than in comparable proteins A significant fraction of NH₂-groups yields imidazole-type bases during the thermal polymerization. Optically active amino acids racemize during the same process. So far no helicity could be detected. Proteinoids are thus clearly distinct from proteins However, many of them exhibit weak catalytic activities and tend to undergo self-assembly into microstructures. Their properties of which only a few have been mentioned still support their role as possible candidates for ancestors of first proteins.     

Protein synthesis: twenty three amino acids and counting

The genetic code can be interpreted during translation as 21 amino acids and three termination signals. Recent advances at the interface of chemistry and molecular biology are extending the genetic code to allow assignment of new amino acids to existing codons, providing new functional groups for protein synthesis.     

Role of amino acids in the translational control of protein synthesis in mammals

Amino acids, long considered simply substrates for protein synthesis, have been recently shown to act as modulators of intracellular signal transduction pathways typically associated with growth-promoting hormones such as insulin and insulin-like growth factor-1. Many of the endpoints of the signaling pathways regulated by amino acids are proteins involved in mRNA translation. Thus, particular amino acids not only serve as substrates for protein synthesis but are also modulators of the process. The focus of this article is to review recent studies that have used intact animals as experimental models to examine the role of amino acids as modulators of signal transduction pathways.     

微生物tRNA与密码子系统应用研究进展*

tRNA作为生命中心法则中翻译过程的重要参与分子,其种类、丰度都会对蛋白质的正常合成产生巨大影响。近年来通过对微生物tRNA的结构功能以及合成修饰过程的解析获得诸多启发,开展密码子扩展的研究,实现将非天然氨基酸引入特定位置从而获得新功能蛋白。同时,通过化学合成微生物基因组开展的密码子重编码工作将释放更多的密码子与tRNA用于更加广泛的密码子扩展研究。对微生物tRNA与密码子系统在合成生物学中的最新应用研究进展进行了综述,并讨论其未来的发展趋势。     

Cis control of gene expression in E.coli by ribosome queuing at an inefficient translational stop signal

An UGA stop codon context which is inefficient because of the 3'-flanking context and the last two amino acids in the gene protein product has a negative effect on gene expression, as shown using a model protein A' gene. This is particularly true at low mRNA levels, corresponding to a high intracellular ribosome/mRNA ratio. The negative effect is smaller if this ratio is decreased, or if the distance between the initiation and termination signals is increased. The results suggest that an inefficient termination codon can cause ribosomal pausing and queuing along the upstream mRNA region, thus blocking translation initiation of short genes. This cis control effect is dependent on the stop codon context, including the C-terminal amino acids in the gene product, the translation initiation signal strength, the ribosome/mRNA ratio and the size of the mRNA coding region. A large proportion of poorly expressed natural Escherichia coli genes are small, and the weak termination codon UGA is under-represented in small, highly expressed E.coli genes as compared with the efficient stop codon UAA.     

In vitro incorporation of nonnatural amino acids into protein using tRNACys-derived opal,ochre, and amber suppressor tRNAs

Amber suppressor tRNAs are widely used to incorporate nonnatural amino acids into proteins to serve as probes of structure, environment, and function. The utility of this approach would be greatly enhanced if multiple probes could be simultaneously incorporated at different locations in the same protein without other modifications. Toward this end, we have developed amber, opal, and ochre suppressor tRNAs derived from Escherichia coli, and yeast tRNA^Cys that incorporate a chemically modified cysteine residue with high selectivity at the cognate UAG, UGA, and UAA stop codons in an in vitro translation system. These synthetic tRNAs were aminoacylated in vitro, and the labile aminoacyl bond was stabilized by covalently attaching a fluorescent dye to the cysteine sulfhydryl group. Readthrough efficiency (amber > opal > ochre) was substantially improved by eRF1/eRF3 inhibition with an RNA aptamer, thus overcoming an intrinsic hierarchy in stop codon selection that limits UGA and UAA termination suppression in higher eukaryotic translation systems. This approach now allows concurrent incorporation of two different modified amino acids at amber and opal codons with a combined apparent readthrough efficiency of up to 25% when compared with the parent protein lacking a stop codon. As such, it significantly expands the possibilities for incorporating nonnative amino acids for protein structure/function studies.     

Digital coding of amino acids based on hydrophobic index

Analysis of amino acid sequences can provide useful insights into the tertiary structures of proteins and their biological functions. One of the critical problems in amino acid analysis is how to establish a digital coding system to better reflect the properties of amino acids and their degeneracy. Based on the hydrophobic index, a one-to-one relationship has been established between the amino acid sequence and the digital signal process. Such a "bridge" will make it possible to apply all the existing powerful methods in the signal processing area to analysis of the amino acid sequences.