固有无序蛋白质及逆境胁迫下的分子功能

固有无序蛋白质是一类在生理条件下缺乏稳定三维结构而具有正常功能,参与信号转导、转录调控、胁迫应答等多种生物学过程的蛋白质.植物中许多逆境响应蛋白是固有无序蛋白质,通过其结构无序或部分无序区域在蛋白质 蛋白质、蛋白质 膜脂、蛋白质 核酸的互作中发挥重要作用.本文主要对固有无序蛋白质的类别、氨基酸组成和结构特点以及在逆境胁迫下其稳定细胞膜、保护核酸和蛋白质、调控基因表达等分子功能进行综述,以拓展对逆境胁迫下蛋白质作用分子机制的认识.     

线性短模体：介导蛋白质相互作用的新模块

线性短模体是天然无序蛋白实现生物学功能的重要组件.线性短模体具有柔性结构和短小的序列,可以介导瞬时、可逆的蛋白质相互作用,并在发生相互作用时表现出杂泛性.随着实验技术的更新和预测手段的发展,越来越多的线性短模体被发现和重新定义,例如BH3线性短模体.本文重点总结了线性短模体在结构、生物学功能以及进化等方面的特点.对线性短模体功能的研究将为解析细胞信号转导网络、疾病靶标确认、新药发现等领域带来新的思路.     

蛋白质丰度调控及整体分布的规律性认识

蛋白质是生命的重要物质基础之一,也是生命活动的主要承担者.蛋白质丰度与其执行的生物学功能息息相关,受基因表达各个过程严格精密的调控.蛋白质丰度的直接影响因素包括相应mRNA初始量、蛋白质合成速率和降解速率.细胞对此3因素的调控将决定蛋白质最终的丰度.得益于定量蛋白质组学的飞速发展,规模化蛋白质丰度数据的产出,使得研究者可致力于发掘蛋白质丰度与其内在性质(如进化特征、结构特征、功能类型等)间规律性的相关性,这对于深入认识生命系统组成的基本原则具有重要意义.本文总结了蛋白质丰度调控及蛋白质丰度与其内在性质相关性的最新研究进展,及对这些规律性现象反映的生物学意义的解读.     

固有无序蛋白的特征、预测及其功能研究进展

固有无序蛋白是一类在天然条件下没有稳定单一的三维结构,存在多种动态互变结构,与传统蛋白不同类型的蛋白质。这类蛋白普遍参与多种生理过程,具有特定的生物学功能。该文对固有无序蛋白的序列、结构特点进行了介绍,总结了无序蛋白预测和鉴定方法,对固有无序蛋白的分子功能和抗逆机理进行了阐述,最后对其在国内外的发展趋势及应用前景进行了展望。     

固有无序蛋白研究进展及其对细胞胁迫耐受性的影响

固有无序蛋白(intrinsically disordered proteins,IDPs)是指在生理条件下缺乏有序稳定的高级结构,整体或局部不折叠,但能够参与多种生物学过程、行使特定生物学功能的一类蛋白质.固有无序蛋白决定了其不同于经典蛋白质"序列-结构-功能"的功能范式,丰富了蛋白质"结构-功能"的多样性.固有无序...     

GH79家族糖苷水解酶分子进化关系和蛋白结构研究

GH79家族的糖苷水解酶在碳水化合物改性、细胞免疫识别和信号传导等方面具有广泛的生理活性和重要的应用前景。然而,目前GH79家族的多样性催化机理仍不清楚,识别底物的结构基础和分子机制尚不清晰。本文总结了近几年GH79家族的研究进展,系统分析了GH79家族酶的来源与分布,通过对酶的序列特征、分子进化关系、蛋白结构解析等方面进行深入阐述,旨在为后续的GH79家族的蛋白质工程和功能催化机制的解析奠定基础。     

病毒RNA如何逃避宿主细胞的降解

细胞RNA的降解机制不仅在基因表达调节方面具有重要作用,而且也是一种重要的病毒防御机制. 作为一种必须在细胞内增殖的微生物,病毒已经进化出了多种机制,以保护它们的RNA免被宿主细胞降解,如病毒RNA模拟宿主细胞mRNA的结构、形成磷脂包膜、形成局部二级结构、结合自己或宿主细胞编码的蛋白质和编码核酸酶增强宿主细胞mRNA降解等. 本文主要论述了病毒RNA逃避宿主细胞降解的方式,并对其应用前景进行了展望,尤其是在研发抗病毒药物方面的应用前景.     

蛋白质体外进化建库技术研究

蛋白质体外进化技术是蛋白质工程发展的一个里程碑,也是改造蛋白质的一种有效工具。它不仅具有重要的应用价值,而且有助于蛋白质结构与功能的研究。通过蛋白质体外进化技术已成功地改造了许多蛋白质,有些已应用于工农业生产。体外进化技术分为两步:建库和筛选。本文主要对蛋白质体外进化策略及对体外随机突变技术、DNA重组技术、利用活细胞自身修复系统构建突变文库等几种定向进化突变文库建立技术进行了介绍与论述,同时还对蛋白质体外进化技术的应用及与其它学科结合的研究前景进行了分析,为获得具有改进功能或全新功能的蛋白质提供理论基础。     

热休克蛋白70的结构和功能

热休克蛋白70(HSP70)是进化上高度保守的一种的蛋白质,具有多种生物学功能,包括分子伴侣功能,具有细胞保护及抗细胞凋亡功能,参与免疫调节,以及在病毒感染与疾病研究中也有重要作用。本文着重对HSP70的结构和功能研究的进展作一综述。     

非编码保守DNA序列形成与演化机制

作为一种系统进化足迹,基因组非编码保守DNA序列受到极大关注。由于非编码保守DNA序列很可能与转录因子或特异蛋白质相互作用,直接参与调控基因表达或稳定染色体结构等重要的生命活动。因此,它极有可能成为基因组研究的下一个新浪潮。在总结对生物非编码保守DNA序列的认识过程的基础上,详细阐述了非编码保守DNA序列形成与演化的模型及其分子生物学机制,进一步展望了非编码保守DNA序列在生物学研究中的应用前景。     

Intrinsically Disordered Proteins and Their Environment: Effects of Strong Denaturants, Temperature, pH, Counter Ions, Membranes, Binding Partners, Osmolytes, and Macromolecular Crowding

Intrinsically disordered proteins (IDPs) differ from “normal” ordered proteins at several levels, structural, functional and conformational. Amino acid biases characteristic for IDPs determine their structural variability and lack of rigid well-folded structure. This structural plasticity is necessary for the unique functional repertoire of IDPs, which is complementary to the catalytic activities of ordered proteins. Amino acid biases also drive atypical responses of IDPs to changes in their environment. The conformational behavior of IDPs is characterized by the low cooperativity (or the complete lack thereof) of the denaturant-induced unfolding, lack of the measurable excess heat absorption peak(s) characteristic for the melting of ordered proteins, “turned out” response to heat and changes in pH, the ability to gain structure in the presence of various counter ions, osmolytes, membranes and binding partners, and by the unique response to macromolecular crowding. This review describes some of the most characteristic features of the IDP conformational behavior and the unique response of IDPs to changes in their environment.     

On the Potential of Machine Learning to Examine the Relationship Between Sequence,Structure, Dynamics and Function of Intrinsically Disordered Proteins

Intrinsically disordered proteins (IDPs) constitute a broad set of proteins with few uniting and many diverging properties. IDPs—and intrinsically disordered regions (IDRs) interspersed between folded domains—are generally characterized as having no persistent tertiary structure; instead they interconvert between a large number of different and often expanded structures. IDPs and IDRs are involved in an enormously wide range of biological functions and reveal novel mechanisms of interactions, and while they defy the common structure-function paradigm of folded proteins, their structural preferences and dynamics are important for their function. We here discuss open questions in the field of IDPs and IDRs, focusing on areas where machine learning and other computational methods play a role. We discuss computational methods aimed to predict transiently formed local and long-range structure, including methods for integrative structural biology. We discuss the many different ways in which IDPs and IDRs can bind to other molecules, both via short linear motifs, as well as in the formation of larger dynamic complexes such as biomolecular condensates. We discuss how experiments are providing insight into such complexes and may enable more accurate predictions. Finally, we discuss the role of IDPs in disease and how new methods are needed to interpret the mechanistic effects of genomic variants in IDPs.     

Markov models of amino acid substitution to study proteins with intrinsically disordered regions

Background

Intrinsically disordered proteins (IDPs) or proteins with disordered regions (IDRs) do not have a well-defined tertiary structure, but perform a multitude of functions, often relying on their native disorder to achieve the binding flexibility through changing to alternative conformations. Intrinsic disorder is frequently found in all three kingdoms of life, and may occur in short stretches or span whole proteins. To date most studies contrasting the differences between ordered and disordered proteins focused on simple summary statistics. Here, we propose an evolutionary approach to study IDPs, and contrast patterns specific to ordered protein regions and the corresponding IDRs.

Results

Two empirical Markov models of amino acid substitutions were estimated, based on a large set of multiple sequence alignments with experimentally verified annotations of disordered regions from the DisProt database of IDPs. We applied new methods to detect differences in Markovian evolution and evolutionary rates between IDRs and the corresponding ordered protein regions. Further, we investigated the distribution of IDPs among functional categories, biochemical pathways and their preponderance to contain tandem repeats.

Conclusions

We find significant differences in the evolution between ordered and disordered regions of proteins. Most importantly we find that disorder promoting amino acids are more conserved in IDRs, indicating that in some cases not only amino acid composition but the specific sequence is important for function. This conjecture is also reinforced by the observation that for of our data set IDRs evolve more slowly than the ordered parts of the proteins, while we still support the common view that IDRs in general evolve more quickly. The improvement in model fit indicates a possible improvement for various types of analyses e.g. de novo disorder prediction using a phylogenetic Hidden Markov Model based on our matrices showed a performance similar to other disorder predictors.     

Importance of electrostatic interactions in the association of intrinsically disordered histone chaperone Chz1 and histone H2A.Z-H2B

Histone chaperones facilitate assembly and disassembly of nucleosomes. Understanding the process of how histone chaperones associate and dissociate from the histones can help clarify their roles in chromosome metabolism. Some histone chaperones are intrinsically disordered proteins (IDPs). Recent studies of IDPs revealed that the recognition of the biomolecules is realized by the flexibility and dynamics, challenging the century-old structure-function paradigm. Here we investigate the binding between intrinsically disordered chaperone Chz1 and histone variant H2A.Z-H2B by developing a structure-based coarse-grained model, in which Debye-Hückel model is implemented for describing electrostatic interactions due to highly charged characteristic of Chz1 and H2A.Z-H2B. We find that major structural changes of Chz1 only occur after the rate-limiting electrostatic dominant transition state and Chz1 undergoes folding coupled binding through two parallel pathways. Interestingly, although the electrostatic interactions stabilize bound complex and facilitate the recognition at first stage, the rate for formation of the complex is not always accelerated due to slow escape of conformations with non-native electrostatic interactions at low salt concentrations. Our studies provide an ionic-strength-controlled binding/folding mechanism, leading to a cooperative mechanism of "local collapse or trapping" and "fly-casting" together and a new understanding of the roles of electrostatic interactions in IDPs' binding.     

Unusual biophysics of intrinsically disordered proteins

Research of a past decade and a half leaves no doubt that complete understanding of protein functionality requires close consideration of the fact that many functional proteins do not have well-folded structures. These intrinsically disordered proteins (IDPs) and proteins with intrinsically disordered protein regions (IDPRs) are highly abundant in nature and play a number of crucial roles in a living cell. Their functions, which are typically associated with a wide range of intermolecular interactions where IDPs possess remarkable binding promiscuity, complement functional repertoire of ordered proteins. All this requires a close attention to the peculiarities of biophysics of these proteins. In this review, some key biophysical features of IDPs are covered. In addition to the peculiar sequence characteristics of IDPs these biophysical features include sequential, structural, and spatiotemporal heterogeneity of IDPs; their rough and relatively flat energy landscapes; their ability to undergo both induced folding and induced unfolding; the ability to interact specifically with structurally unrelated partners; the ability to gain different structures at binding to different partners; and the ability to keep essential amount of disorder even in the bound form. IDPs are also characterized by the “turned-out” response to the changes in their environment, where they gain some structure under conditions resulting in denaturation or even unfolding of ordered proteins. It is proposed that the heterogeneous spatiotemporal structure of IDPs/IDPRs can be described as a set of foldons, inducible foldons, semi-foldons, non-foldons, and unfoldons. They may lose their function when folded, and activation of some IDPs is associated with the awaking of the dormant disorder. It is possible that IDPs represent the “edge of chaos” systems which operate in a region between order and complete randomness or chaos, where the complexity is maximal. This article is part of a Special Issue entitled: The emerging dynamic view of proteins: Protein plasticity in allostery, evolution and self-assembly.     

Towards the physical basis of how intrinsic disorder mediates protein function

Intrinsically disordered proteins (IDPs) are an important class of functional proteins that is highly prevalent in biology and has broad association with human diseases. In contrast to structured proteins, free IDPs exist as heterogeneous and dynamical conformational ensembles under physiological conditions. Many concepts have been discussed on how such intrinsic disorder may provide crucial functional advantages, particularly in cellular signaling and regulation. Establishing the physical basis of these proposed phenomena requires not only detailed characterization of the disordered conformational ensembles, but also mechanistic understanding of the roles of various ensemble properties in IDP interaction and regulation. Here, we review the experimental and computational approaches that may be integrated to address many important challenges of establishing a "structural" basis of IDP function, and discuss some of the key emerging ideas on how the conformational ensembles of IDPs may mediate function, especially in coupled binding and folding interactions.     

Advantages of proteins being disordered

The past decade has witnessed great advances in our understanding of protein structure‐function relationships in terms of the ubiquitous existence of intrinsically disordered proteins (IDPs) and intrinsically disordered regions (IDRs). The structural disorder of IDPs/IDRs enables them to play essential functions that are complementary to those of ordered proteins. In addition, IDPs/IDRs are persistent in evolution. Therefore, they are expected to possess some advantages over ordered proteins. In this review, we summarize and survey nine possible advantages of IDPs/IDRs: economizing genome/protein resources, overcoming steric restrictions in binding, achieving high specificity with low affinity, increasing binding rate, facilitating posttranslational modifications, enabling flexible linkers, preventing aggregation, providing resistance to non‐native conditions, and allowing compatibility with more available sequences. Some potential advantages of IDPs/IDRs are not well understood and require both experimental and theoretical approaches to decipher. The connection with protein design is also briefly discussed.