介导新生肽链折叠的胞质分子伴侣结构、功能及作用机制研究进展

分子伴侣是一类能够识别非天然蛋白并能协助其正确折叠、组装和转运的功能蛋白。最新研究发现,在原核或真核细胞中,不同结构、不同种类的分子伴侣形成了一个复杂的折叠系统,通过这个系统,蛋白质完成了从初步合成到形成具有生物活性的三维构象的过程,避免了折叠过程中多肽链的错误折叠、蛋白沉淀和有害物质的产生。文章综述了蛋白质折叠过程中不同种类分子伴侣组件的结构、功能和作用机制的研究进展,这些分子伴侣包括Hsp70、核糖体结合因子、伴侣素、前折叠素与Hsp90,并阐述了它们在蛋白质内稳态中的作用。     

HSP70分子伴侣系统研究进展

综述了HSP70分子伴侣系统的晶体结构、功能及作用机理方面的研究进展.HSP70分子伴侣能够帮助细胞内新生蛋白的折叠和跨膜运输、蛋白质多聚体结构的装配和解装配,并能在胁迫下维持蛋白质的特殊构象,防止未折叠的蛋白质变性和使聚集的蛋白质溶解复性.所有这些活性均依赖于ATP调节的HSP70与底物蛋白中的疏水片段的相互作用.     

分子内分子伴侣--Pro肽在蛋白质折叠中的作用

在体内,许多蛋白质,如很多胞外蛋白酶、某些多肽激素等都以含前导肽的前体形式合成,前导肽在蛋白质折叠中具有分子伴侣的功能。为了与一般意义上的分子伴侣相区别,人们将对蛋白质折叠有帮助的前导肽称为分子内分子伴侣,分子内分子伴侣帮助蛋白质在折叠过程中克服高的能量障碍,某些蛋白质的分子内分子伴侣甚至促进其在氧化性折叠中二硫键的正确配对。     

分子伴侣 SecB 基因和人淋巴毒素基因在大肠杆菌中的共表达

分于伴侣(Chaperohe)是细胞内催化及维持其他蛋白质正确梅象的一类蛋白质分子^[1,2]。研究表明,分子伴侣参与细胞内许多蛋白质的折叠、聚合以及跨膜运输^[3,4],通过瞬时稳定其他蛋白质折叠中间体,阻止了蛋白中间体的聚集,帮助其形成正确构象^[5,6]。SecB是一个胞质酸性蛋白．单体分子量为17kDa,在体内以4～6个相同亚基组成的寡聚体形式存在。它在大肠杆菌中参与蛋白质分泌系统,纯化后进行离体试验表明,它可以阻止抗蛋白酶的pre-MBP的出现,能稳定地结合前体蛋白．使其处于适合运输的构型^[7],它的作用是使蛋白质可以在正确折叠前跨过细胞膜,运输到细胞周质中。SecB通过与前体蛋白结合．从而阻止前体蛋自由于不正确折叠发生的聚集,属于分子伴侣家族的成员。分子伴侣的这些特性使得它们在基因工程中具有广阔的应用前景。外源蛋白在大肠杆菌中高表达时往往形成无活性的包涵体,包涵体大多是蛋白质在过量表达过程中不正确折叠形成的^[8],正确构象的形成需要在体外进行变性和复性。蛋白质的复性过程十分复杂,在方法上缺少一定的规律可循,特别是分子量较大以及二硫键较多的分子,复性更加困难,有的甚至根本难以复性。分子伴侣可以促进其它蛋白质的正确折叠,设想在基因工程中如果将分子伴侣基因与外源蛋白基因共存表达,可能会有效地促进外源蛋白形成正确的构象．提高其活性,减少包涵体的形成,对基因工程下游的处理带来很大方便。根 据这个思路,我们将克隆的SecB基因与重组人淋巴毒索(Lymphotoxin,简称LT)基因在同一个大肠杆菌细胞中共存表达,来研究分子伴侣SecB对外源基因表达的影响。     

分子伴侣在蛋白质折叠中的作用

分子伴侣主要由三个高度保守的蛋白质家族组成,这三个家族的成员广泛分布于原核和真核细胞中。TCP1复合物是真核细胞细胞溶质内的伴侣蛋白。分子伴侣在蛋白质折叠过程中防止多肽链形成聚集物或无活性结构,提高正确折叠率。本文重点讨论Stress-70家族蛋白质和伴侣蛋白协助蛋白质折叠过程中的协同性以及伴侣蛋白GroEL和GroES的作用机理。     

分子伴侣及其在蛋白质折叠中的作用研究进展

蛋白质折叠是一个复杂的、动态的过程,蛋白质的折叠不是自发的,需要其他物质的帮助.了解分子伴侣在蛋白质折叠过程中的的作用,有助于进一步研究蛋白质折叠机制.本文介绍了分子伴侣及其分类,重点综述了各类分子伴侣在蛋白质折叠中的机制,并提出了研究分子伴侣在蛋白质折叠中的作用的重要意义.     

伴侣素的发现者——霍维茨

伴侣素（chaperonin）是辅助蛋白质正确折叠过程中的重要元件,可有效防止蛋白质错误折叠和聚集,对细胞正常功能发挥和发育具有十分重要的意义。伴侣素功能缺陷或异常可导致许多神经退行性疾病如帕金森综合症等的发生,因此伴侣素介导的蛋白质折叠的研究对该类疾病的治疗具有重要帮助。伴侣素于1989年由霍维茨发现,经过近20年研究,人们对其作用机理和生理功能有了较为全面的理解,从而为应用奠定了基础。     

钙网蛋白与神经系统病变

钙网蛋白（calreticulin,CRT）是内质网中的一种多功能的分子伴侣,在协助蛋白质正确折叠和维持细胞Ca2＋稳态（Ca2＋信号）中发挥重要作用。近来的研究发现,钙网蛋白与神经系统病变包括阿尔茨海默氏病、帕金森病等有密切关系。     

分子伴侣HdeA与HdeB的作用机制

分子伴侣能够与其他蛋白质的不稳定构象相结合并使其稳定．它的功能之一是能够帮助蛋白质进行正确的折叠与组装．最新研究发现,在肠道致病菌的周质空间中存在着酸性条件下能帮助周质蛋白复性的分子伴侣HdeA和HdeB．HdeA在极端酸性的胃部环境中由二聚体迅速解离成具有伴侣活性的单体,HdeA单体能够和变性的底物蛋白结合防止它们酸诱导聚集,从而保护肠道致病菌安全到达肠道．本文对肠道致病菌的耐酸机制进行了总结,最后对 HdeA和HdeB作用机制的研究近况进行综述,最后对HdeA和HdeB以后的研究方向进行了展望．     

线粒体蛋白质组及蛋白质量控制

线粒体是哺乳动物细胞内重要细胞器,不仅通过氧化磷酸化产生ATP为细胞提供能量,也参与调节钙离子稳态、活性氧(reactive oxygen species,ROS)的产生、细胞应激反应和细胞死亡等过程,其功能障碍不仅导致多种人类疾病的发生,而且也能降低动物卵母细胞质量和早期胚胎发育能力。大量证据表明,线粒体的功能依赖于线粒体蛋白质组完整性和稳态。基于此,该文综述了线粒体蛋白组、线粒体蛋白转运,聚焦蛋白酶、分子伴侣、线粒体囊泡、线粒体自噬和线粒体未折叠蛋白反应在帮助正确的蛋白质折叠,去除错误折叠或聚集的蛋白质和清除功能失调的线粒体方面的作用,为调控线粒体蛋白质量,从而维持线粒体健康、降低疾病发生提供理论依据。     

Molecular chaperones as therapeutic targets to counteract proteostasis defects

The health of cells is preserved by the levels and correct folding states of the proteome, which is generated and maintained by the proteostasis network, an integrated biological system consisting of several cytoprotective and degradative pathways. Indeed, the health conditions of the proteostasis network is a fundamental prerequisite to life as the inability to cope with the mismanagement of protein folding arising from genetic, epigenetic, and micro-environment stress appears to trigger a whole spectrum of unrelated diseases. Here we describe the potential functional role of the proteostasis network in tumor biology and in conformational diseases debating on how the signaling branches of this biological system may be manipulated to develop more efficacious and selective therapeutic strategies. We discuss the dual strategy of these processes in modulating the folding activity of molecular chaperones in order to counteract the antithetic proteostasis deficiencies occurring in cancer and loss/gain of function diseases. Finally, we provide perspectives on how to improve the outcome of these disorders by taking advantage of proteostasis modeling.     

A microbial sensor for discovering structural probes of protein misfolding and aggregation

In all cell types, protein homeostasis, or “proteostasis,” is maintained by sophisticated quality control networks that regulate protein synthesis, folding, trafficking, aggregation, disaggregation, and degradation. In one notable example, Escherichia coli employ a proteostasis system that determines whether substrates of the twin-arginine translocation (Tat) pathway are correctly folded and thus suitable for transport across the tightly sealed cytoplasmic membrane. Herein, we review growing evidence that the Tat translocase itself discriminates folded proteins from those that are misfolded and/or aggregated, preferentially exporting only the former. Genetic suppressors that inactivate this mechanism have recently been isolated and provide direct evidence for the participation of the Tat translocase in structural proofreading of its protein substrates. We also discuss how this discriminatory “folding sensor” has been exploited for the discovery of structural probes (e.g., sequence mutations, pharmacologic chaperones, intracellular antibodies) that modulate the folding and solubility of virtually any protein-of-interest, including those associated with aggregation diseases (e.g., α-synuclein, amyloid-β protein). Taken together, these studies highlight the utility of engineered bacteria for rapidly and inexpensively uncovering potent anti-aggregation factors.     

Fluc‐EGFP reporter mice reveal differential alterations of neuronal proteostasis in aging and disease

The cellular protein quality control machinery is important for preventing protein misfolding and aggregation. Declining protein homeostasis (proteostasis) is believed to play a crucial role in age‐related neurodegenerative disorders. However, how neuronal proteostasis capacity changes in different diseases is not yet sufficiently understood, and progress in this area has been hampered by the lack of tools to monitor proteostasis in mammalian models. Here, we have developed reporter mice for in vivo analysis of neuronal proteostasis. The mice express EGFP‐fused firefly luciferase (Fluc‐EGFP), a conformationally unstable protein that requires chaperones for proper folding, and that reacts to proteotoxic stress by formation of intracellular Fluc‐EGFP foci and by reduced luciferase activity. Using these mice, we provide evidence for proteostasis decline in the aging brain. Moreover, we find a marked reaction of the Fluc‐EGFP sensor in a mouse model of tauopathy, but not in mouse models of Huntington’s disease. Mechanistic investigations in primary neuronal cultures demonstrate that different types of protein aggregates have distinct effects on the cellular protein quality control. Thus, Fluc‐EGFP reporter mice enable new insights into proteostasis alterations in different diseases.     

Preventing α-synuclein aggregation: The role of the small heat-shock molecular chaperone proteins

Protein homeostasis, or proteostasis, is the process of maintaining the conformational and functional integrity of the proteome. The failure of proteostasis can result in the accumulation of non-native proteins leading to their aggregation and deposition in cells and in tissues. The amyloid fibrillar aggregation of the protein α-synuclein into Lewy bodies and Lewy neuritis is associated with neurodegenerative diseases classified as α-synucleinopathies, which include Parkinson's disease and dementia with Lewy bodies. The small heat-shock proteins (sHsps) are molecular chaperones that are one of the cell's first lines of defence against protein aggregation. They act to stabilise partially folded protein intermediates, in an ATP-independent manner, to maintain cellular proteostasis under stress conditions. Thus, the sHsps appear ideally suited to protect against α-synuclein aggregation, yet these fail to do so in the context of the α-synucleinopathies. This review discusses how sHsps interact with α-synuclein to prevent its aggregation and, in doing so, highlights the multi-faceted nature of the mechanisms used by sHsps to prevent the fibrillar aggregation of proteins. It also examines what factors may contribute to α-synuclein escaping the sHsp chaperones in the context of the α-synucleinopathies.     

A genetic screening strategy identifies novel regulators of the proteostasis network

A hallmark of diseases of protein conformation and aging is the appearance of protein aggregates associated with cellular toxicity. We posit that the functional properties of the proteostasis network (PN) protect the proteome from misfolding and combat the proteotoxic events leading to cellular pathology. In this study, we have identified new components of the proteostasis network that can suppress aggregation and proteotoxicity, by performing RNA interference (RNAi) genetic screens for multiple unrelated conformationally challenged cytoplasmic proteins expressed in Caenorhabditis elegans. We identified 88 suppressors of polyglutamine (polyQ) aggregation, of which 63 modifiers also suppressed aggregation of mutant SOD1(G93A). Of these, only 23 gene-modifiers suppressed aggregation and restored animal motility, revealing that aggregation and toxicity can be genetically uncoupled. Nine of these modifiers were shown to be effective in restoring the folding and function of multiple endogenous temperature-sensitive (TS) mutant proteins, of which five improved folding in a HSF-1-dependent manner, by inducing cytoplasmic chaperones. This triage screening strategy also identified a novel set of PN regulatory components that, by altering metabolic and RNA processing functions, establish alternate cellular environments not generally dependent on stress response activation and that are broadly protective against misfolded and aggregation-prone proteins.     

Roles of extracellular chaperones in amyloidosis

Extracellular protein misfolding and aggregation underlie many of the most serious amyloidoses including Alzheimer's disease, spongiform encephalopathies and type II diabetes. Despite this, protein homeostasis (proteostasis) research has largely focussed on characterising systems that function to monitor protein conformation and concentration within cells. We are now starting to identify elements of corresponding systems, including an expanding family of secreted chaperones, which exist in the extracellular space. Like their intracellular counterparts, extracellular chaperones are likely to play a central role in systems that maintain proteostasis; however, the precise details of how they participate are only just emerging. It is proposed that extracellular chaperones patrol biological fluids for misfolded proteins and facilitate their clearance via endocytic receptors. Importantly, many amyloidoses are associated with dysfunction in rates of protein clearance. This is consistent with a model in which disruption to, or overwhelming of, the systems responsible for extracellular proteostasis results in the accumulation of pathological protein aggregates and disease. Further characterisation of mechanisms that maintain extracellular proteostasis will shed light on why many serious diseases occur and provide us with much needed strategies to combat them.     

Crowbars and ratchets: hsp100 chaperones as tools in reversing protein aggregation.

Molecular chaperones have the capacity to prevent inappropriate interactions between aggregation-prone folding or unfolding intermediates created in the cell during protein synthesis or in response to physical and chemical stress. What happens when surveillance by molecular chaperones is evaded or overwhelmed and aggregates accumulate? Recent progress in the elucidation of Hsp100/Clp function suggests that intracellular aggregates or stable complexes can be progressively dissolved by the action of chaperones that act as molecular crowbars or ratchets. These insights set the stage for new progress in the understanding and treatment of diseases of protein folding.     

Heat shock proteins in cell signaling and cancer

Heat Shock Proteins (HSPs) and their co-chaperones have well-established roles in regulating proteostasis within the cell, the nature of which continues to emerge with further study. To date, HSPs have been shown to be integral to protein folding and re-folding, protein transport, avoidance of protein aggregation, and modulation of protein degradation. Many cell signaling events are mediated by the chemical modification of proteins post-translationally that can alter protein conformation and activity, although it is not yet known whether the changes in protein conformation induced by post-translational modifications (PTMs) are also dependent upon HSPs and their co-chaperones for subsequent protein re-folding. We discuss what is known regarding roles for HSPs and other molecular chaperones in cell signaling events with a focus on oncogenic signaling. We also propose a hypothesis by which Hsp70 and Hsp90 may co-operate to facilitate cell signaling events that may link PTMs with the cellular protein folding machinery.     

Firefly luciferase mutants as sensors of proteome stress

Maintenance of cellular protein homeostasis (proteostasis) depends on a complex network of molecular chaperones, proteases and other regulatory factors. Proteostasis deficiency develops during normal aging and predisposes individuals for many diseases, including neurodegenerative disorders. Here we describe sensor proteins for the comparative measurement of proteostasis capacity in different cell types and model organisms. These sensors are increasingly structurally destabilized versions of firefly luciferase. Imbalances in proteostasis manifest as changes in sensor solubility and luminescence activity. We used EGFP-tagged constructs to monitor the aggregation state of the sensors and the ability of cells to solubilize or degrade the aggregated proteins. A set of three sensor proteins serves as a convenient toolkit to assess the proteostasis status in a wide range of experimental systems, including cell and organism models of stress, neurodegenerative disease and aging.