Sorting, recognition and activation of the misfolded protein degradation pathways through macroautophagy and the proteasome

Based on a functional categorization, proteins may be grouped into three types and sorted to either the proteasome or the macroautophagy pathway for degradation. The two pathways are mechanistically connected but their capacity seems different. Macroautophagy can degrade all forms of misfolded proteins whereas proteasomal degradation is likely limited to soluble ones. Unlike the bulk protein degradation that occurs during starvation, autophagic degradation of misfolded proteins can have a degree of specificity, determined by ubiquitin modification and the interactions of p62/SQSTM1 and HDAC6. Macroautophagy is initiated in response to endoplasmic reticulum (ER) stress caused by misfolded proteins, via the ER-activated autophagy (ERAA) pathway, which activates a partial unfolded protein response involving PERK and/or IRE1, and a calcium-mediated signaling cascade. ERAA serves the function of mitigating ER stress and suppressing cell death, which may be explored for controlling protein conformational diseases. Conversely, inhibition of ERAA may be explored for sensitizing resistant tumor cells to cytotoxic agents.     

Sorting,recognition and activation of the misfolded protein degradation pathways through macroautophagy and the proteasome

Based on a functional categorization, proteins may be grouped into three types and sorted to either the proteasome or the macroautophagy pathway for degradation. The two pathways are mechanistically connected but their capacity seems different. Macroautophagy can degrade all forms of misfolded proteins whereas proteasomal degradation is likely limited to soluble ones.Unlike the bulk protein degradation that occurs during starvation, autophagic degradation of misfolded proteins can have a degree of specificity, determined by ubiquitin modification and the interactions of p62/SQSTM1 and HDAC6. Macroautophagy is initiated in response to endoplasmic reticulum (ER) stress caused by misfolded proteins, via the ER-activated autophagy (ERAA) pathway, which activates a partial unfolded protein response involving PERK and/or IRE1, and a calcium-mediated signaling cascade. ERAA serves the function of mitigating ER stress and suppressing cell death, which may be explored for controlling protein conformational diseases. Conversely, inhibition of ERAA may be explored for sensitizing resistant tumor cells to cytotoxic agents.     

RIP1, a kinase on the crossroads of a cell's decision to live or die

Binding of inflammatory cytokines to their receptors, stimulation of pathogen recognition receptors by pathogen-associated molecular patterns, and DNA damage induce specific signalling events. A cell that is exposed to these signals can respond by activation of NF-kappaB, mitogen-activated protein kinases and interferon regulatory factors, resulting in the upregulation of antiapoptotic proteins and of several cytokines. The consequent survival may or may not be accompanied by an inflammatory response. Alternatively, a cell can also activate death-signalling pathways, resulting in apoptosis or alternative cell death such as necrosis or autophagic cell death. Interplay between survival and death-promoting complexes continues as they compete with each other until one eventually dominates and determines the cell's fate. RIP1 is a crucial adaptor kinase on the crossroad of these stress-induced signalling pathways and a cell's decision to live or die. Following different upstream signals, particular RIP1-containing complexes are formed; these initiate only a limited number of cellular responses. In this review, we describe how RIP1 acts as a key integrator of signalling pathways initiated by stimulation of death receptors, bacterial or viral infection, genotoxic stress and T-cell homeostasis.     

Emerging roles for ubiquitin in adenovirus cell entry

Adenovirus relies on numerous interactions between viral and host cell proteins to efficiently enter cells. Undoubtedly, post-translational modifications of host and cellular proteins can impact the efficiency of this cell entry process. Ubiquitylation, once simply thought of as a modification targeting proteins for proteasomal degradation, is now known to regulate protein trafficking within cells, protein-protein interactions and cell signalling pathways. Accumulating evidence suggests that protein ubiquitylation can influence all stages of the life cycle of other viruses such as cell entry, replication and egress. Until recently, the influence of ubiquitylation has only been documented during adenovirus replication. This review highlights the most recent evidence demonstrating direct engagement of host ubiquitylation and SUMOylation machinery by adenovirus during cell entry. Additionally, potential roles for host protein ubiquitylation and the potential for adenovirus regulation of host ubiquitylation machinery during cell entry are discussed.     

Caspase-independent cell deaths

A very common and the best understood of the mechanisms of physiological cell death is apoptosis, resulting from the activation, through either of two primary pathways, of site-specific proteases called caspases. There are, however, many other routes to cell death, prominently including autophagy and proteasomal degradation of critical constituents of cells. These routes are frequently seen in experimental situations in which initiator or effector caspases are inhibited or blocked through genetic means, but they are also encountered during normal physiological and pathological processes. Most frequently, autophagic or proteasomal degradation is used to eliminate massive cytoplasm of very large cells, especially post-mitotic cells, and these pathways are prominent even though caspase genes, messages, and pro-enzymes are found in the cells. These forms of cell death are fully physiological and not simply a default pathway for a defective cell; and they are distinct from necrosis. We do not yet understand the extent to which the pathways are linked, what mechanisms trigger the caspase-independent deaths, and how the choices are made.     

Plant natural compounds: targeting pathways of autophagy as anti-cancer therapeutic agents

Natural compounds derived from plant sources are well characterized as possessing a wide variety of remarkable anti-tumour properties, for example modulating programmed cell death, primarily referring to apoptosis, and autophagy. Distinct from apoptosis, autophagy (an evolutionarily conserved, multi-step lysosomal degradation process in which a cell destroys long-lived proteins and damaged organelles) may play crucial regulatory roles in many pathological processes, most notably in cancer. In this review, we focus on highlighting several representative plant natural compounds such as curcumin, resveratrol, paclitaxel, oridonin, quercetin and plant lectin - that may lead to cancer cell death - for regulation of some core autophagic pathways, involved in Ras-Raf signalling, Beclin-1 interactome, BCR-ABL, PI3KCI/Akt/mTOR, FOXO1 signalling and p53. Taken together, these findings would provide a new perspective for exploiting more plant natural compounds as potential novel anti-tumour drugs, by targeting the pathways of autophagy, for future cancer therapeutics.     

Macroautophagy in Immunity and Tolerance

Autophagy and proteasomal degradation constitute the two main catabolic pathways in cells. While the proteasome degrades primarily short-lived soluble proteins, macroautophagy, the main constitutive autophagic pathway, delivers cell organelles and protein aggregates for lysosomal degradation. Both the proteasome and macroautophagy are attractive effector mechanisms for the immune system because they can be used to degrade foreign substances, including pathogenic proteins, within cells. Therefore, both innate and adaptive immune responses use these pathways for intracellular clearance of pathogens as well as for presentation of pathogen fragments to the adaptive immune system. Because, however, the same mechanisms are used for the steady-state turnover of cellular self-components, the immune system has to be desensitized not to recognize these. Therefore, proteasomal degradation and macroautophagy are also involved in tolerizing the immune system prior to pathogen encounter. We will discuss recent advances in our understanding how macroautophagy selects self-structures in the steady state, how presentation of these on major histocompatibility complex class II molecules leads to tolerance and how macroautophagy assists both innate and adaptive immunity. This new knowledge on the specialized functions of the metabolic process macroautophagy in higher eukaryotes should allow us to target it for therapy development against immunopathologies and to improve vaccinations.     

p62 links the autophagy pathway and the ubiqutin–proteasome system upon ubiquitinated protein degradation

The ubiquitin–proteasome system (UPS) and autophagy are two distinct and interacting proteolytic systems. They play critical roles in cell survival under normal conditions and during stress. An increasing body of evidence indicates that ubiquitinated cargoes are important markers of degradation. p62, a classical receptor of autophagy, is a multifunctional protein located throughout the cell and involved in many signal transduction pathways, including the Keap1–Nrf2 pathway. It is involved in the proteasomal degradation of ubiquitinated proteins. When the cellular p62 level is manipulated, the quantity and location pattern of ubiquitinated proteins change with a considerable impact on cell survival. Altered p62 levels can even lead to some diseases. The proteotoxic stress imposed by proteasome inhibition can activate autophagy through p62 phosphorylation. A deficiency in autophagy may compromise the ubiquitin–proteasome system, since overabundant p62 delays delivery of the proteasomal substrate to the proteasome despite proteasomal catalytic activity being unchanged. In addition, p62 and the proteasome can modulate the activity of HDAC6 deacetylase, thus influencing the autophagic degradation.     

Mitochondria: regulating the inevitable

Apoptosis is a form of programmed cell death important in the development and tissue homeostasis of multicellular organisms. Abnormalities in cell death control can lead to a variety of diseases, including cancer and degenerative disorders. Hence, the process of apoptosis is tightly regulated through multiple independent signalling pathways that are initiated either from triggering events within the cell or at the cell surface. In recent years, mitochondria have emerged as the central components of such apoptotic signalling pathways and are now known to control apoptosis through the release of apoptogenic proteins. In this review we aim to give an overview of the role of the mitochondria during apoptosis and the molecular mechanisms involved.     

Multifaceted deaths orchestrated by mitochondria in neurones

Neurones undergo diverse forms of cell death depending on the nature and severity of the stress. These death outcomes are now classified into various types of programmed cell death, including apoptosis, autophagy and necrosis. Each of these pathways can run in parallel and all have mitochondria as a central feature. Recruitment of mitochondria into cell death signalling involves either (or both) induction of specific death responses through release of apoptogenic proteins into the cytosol, or perturbation in function leading to loss of mitochondrial energisation and ATP synthesis. Cross-talk between these signalling pathways, particularly downstream of mitochondria, determines the resultant pattern of cell death. The differential recruitment of specific death pathways depends on the timing of engagement of mitochondrial signalling. Other influences on programmed cell death pathways occur through stress of the endoplasmic reticulum and the associated ubiquitin-proteasome system normally handling potentially neurotoxic protein aggregates. Based upon contemporary evidence apoptosis is a relatively rare in the mature brain whereas the contribution of programmed necrosis to various neuropathologies has been underestimated. The death outcomes that neurones exhibit during acute or chronic injury or pathological conditions considered here (oxidative stress, hypoxic-ischaemic injury, amyotrophic lateral sclerosis, Parkinson's and Huntington's diseases) fall within a spectrum of the diverse death types across the apoptosis-necrosis continuum. Indeed, dying or dead neurones may simultaneously manifest characteristics of more than one type of death pathway. Understanding neuronal death pathways and their cross-talk not only informs the detailed pathobiology but also suggests novel therapeutic strategies.     

内质网应激与自噬及其交互作用影响内皮细胞凋亡

内质网应激是普遍存在于真核细胞中的应激-防御机制。在内环境稳态遭到破坏的情况下,未折叠蛋白质反应的3条信号通路,分别通过增强蛋白质折叠能力、减少蛋白质生成和促进内质网相关蛋白质降解等途径缓解细胞内压力。同时,也通过多种分子信号机制调控细胞凋亡。自噬是一种生理性的降解机制。通过形成自噬泡并与溶酶体结合摄取并水解胞内受损细胞器和蛋白质等,清除代谢废物,维持细胞正常功能。自噬缺陷或过度激活均可导致细胞凋亡或非程序性死亡。自噬的程度和细胞内压力水平有关。内质网应激通过未折叠蛋白质反应和Ca²⁺浓度变化及其相关分子信号调控自噬。自噬又可反馈性调节内质网应激反应,二者相互作用,在内皮细胞凋亡过程中发挥重要作用。未来内质网应激和自噬可作为药物靶点为内皮相关性疾病提供诊疗策略。     

Direct oxidative modifications of signalling proteins in mammalian cells and their effects on apoptosis

The production of ROS is an inevitable consequence of metabolism. However, high levels of ROS within a cell can be lethal and so the cell has a number of defences against oxidative cell stress. Occasionally the cell's antioxidant mechanisms fail and oxidative stress occurs. High levels of ROS within a cell have a number of direct and indirect consequences on cell signalling pathways and may result in apoptosis or necrosis. Although some of the indirect effects of ROS are well known, limitations in technology mean that the direct effects of the cell's redox environment upon proteins are less understood. Recent work by a number of groups has demonstrated that ROS can directly modify signalling proteins through different modifications, for example by nitrosylation, carbonylation, di-sulphide bond formation and glutathionylation. These modifications modulate a protein's activity and several recent papers have demonstrated their importance in cell signalling events, especially those involved in cell death/survival. Redox modification of proteins allows for further regulation of cell signalling pathways in response to the cellular environment. Understanding them may be critical for us to modulate cell pathways for our own means, such as in cytotoxic drug treatments of cancer cells. Protein modifications mediated by oxidative stress can modulate apoptosis, either through specific protein modifications resulting in regulation of signalling pathways, or through a general increase in oxidised proteins resulting in reduced cellular function. This review discusses direct oxidative protein modifications and their effects on apoptosis.     

Programmed cell death and the proteasome

A characteristic feature of apoptotic cell death is the activation of a cascade of cytoplasmic proteases that results in the cleavage of a limited number of target proteins. A central role in these proteolytic events has been assigned to members of the capase family. However, the use of low molecular weight proteasomal inhibitors has also demonstrated that protein degradation or processing by the ubiquitin-proteasome system of the cell has a decisive impact on cell survival and death as well, depending on the cell type and/or the proliferative status of the cells studied. Treatment of proliferating cells with proteasome inhibitors leads to cell death, potentially involving an internal signalling conflict between accumulating levels of the cdk inhibitor p27Kip1 and c-myc. In contrast, in terminally differentiated cells the same compounds have the opposite effect of blocking apoptosis, possibly by preventing proteasome-mediated degradation of a capase inhibitor. In this review the role of proteasome-mediated proteolysis in the dying cell is discussed and apparently conflicting results are integrated into a working hypothesis which functionally locates the proteasome upstream of capase3-like enzymes.     

Dismantling the autophagic arsenal when it is time to die

Under stress conditions cells activate different response pathways which result in cell survival or apoptosis depending on: (1) the nature of the insults, (2) the type, if acute or chronic stress, and (3) how long the stress persists. Generally, autophagy is induced early to sustain cell survival and inhibit cell death. However, adverse conditions are able to overcome autophagy to promote cell death. Increasing evidence suggests that the inhibition of autophagy by the apoptotic machinery has been proposed as one of the crucial events responsible for the irreversible switch from survival to death. The mechanism seems to be related to the selective apoptotic protease-mediated degradation of key autophagic proteins. We recently found that AMBRA1, an important regulator of the autophagic process mediating the initial steps of autophagosome formation, is also irreversibly degraded by the combined activity of caspases and calpains. This phenomenon is not merely a consequence of apoptosis execution but represents a key step required to efficiently promote the autophagic vs apoptosis switch.     

昆虫细胞程序性死亡的研究进展

在昆虫发育和抵抗病原微生物的入侵过程中,细胞凋亡与自噬性死亡现象十分常见。昆虫细胞凋亡的研究已经取得了许多的成果,但是有关细胞自噬程序性死亡的研究还正在深入。昆虫细胞凋亡的信号通路至少有3条：一条类似于线虫细胞的凋亡信号通路,另一条类似于哺乳动物细胞的凋亡信号通路, 还有一条不依赖于胱天蛋白酶的凋亡信号通路。在昆虫的多种组织细胞中,细胞凋亡与自噬程序性死亡在信号通路上存在互串(cross talking),可以相互促进、抑制或替代。了解昆虫细胞程序性死亡对防治害虫具有一定的意义。     

Autophagy, mitochondria and oxidative stress: cross-talk and redox signalling

Reactive oxygen and nitrogen species change cellular responses through diverse mechanisms that are now being defined. At low levels, they are signalling molecules, and at high levels, they damage organelles, particularly the mitochondria. Oxidative damage and the associated mitochondrial dysfunction may result in energy depletion, accumulation of cytotoxic mediators and cell death. Understanding the interface between stress adaptation and cell death then is important for understanding redox biology and disease pathogenesis. Recent studies have found that one major sensor of redox signalling at this switch in cellular responses is autophagy. Autophagic activities are mediated by a complex molecular machinery including more than 30 Atg (AuTophaGy-related) proteins and 50 lysosomal hydrolases. Autophagosomes form membrane structures, sequester damaged, oxidized or dysfunctional intracellular components and organelles, and direct them to the lysosomes for degradation. This autophagic process is the sole known mechanism for mitochondrial turnover. It has been speculated that dysfunction of autophagy may result in abnormal mitochondrial function and oxidative or nitrative stress. Emerging investigations have provided new understanding of how autophagy of mitochondria (also known as mitophagy) is controlled, and the impact of autophagic dysfunction on cellular oxidative stress. The present review highlights recent studies on redox signalling in the regulation of autophagy, in the context of the basic mechanisms of mitophagy. Furthermore, we discuss the impact of autophagy on mitochondrial function and accumulation of reactive species. This is particularly relevant to degenerative diseases in which oxidative stress occurs over time, and dysfunction in both the mitochondrial and autophagic pathways play a role.