FUNDC1与运动诱导线粒体自噬北大核心CSCD

线粒体为细胞正常生命活动提供物质和能量,然而各种因素会导致线粒体损伤,衰老及功能紊乱。线粒体自噬是维持细胞稳态,及时清除细胞潜在危险因素的关键过程,FUNDC1是新近发现的一种线粒体自噬受体蛋白,在介导线粒体自噬方面有重要作用。运动是激活线粒体自噬的应激条件,其诱导骨骼肌线粒体自噬及FUNDC1在此过程中的作用机制正逐步明确。本文介绍FUNDC1的结构、功能和调节,分析FUNDC1与线粒体分裂、融合、自噬的关系,探讨运动诱导线粒体自噬过程中FUNDC1的调控机制,为进一步研究提供参考依据。     

Atg11的功能研究进展

Atg11利用自身众多螺旋结构域作为支架蛋白,主要介导选择性自噬过程中自噬体的形成.选择性自噬可特异性清除损坏的生物大分子和细胞器,在真核生物的胞内物质周转及细胞器质量控制中起重要作用.本文首先介绍了Atg11的结构特点,其次重点介绍了Atg11在3种选择性自噬(细胞质到液泡靶向(Cvt)途径、过氧化物酶体自噬和线粒体自噬)中的作用,最后概括了Atg11的其他功能.本文系统总结了近几年关于Atg11的研究进展,以期为自噬体形成机制研究及Atg11在自噬体形成过程中的功能研究提供参考.     

线粒体融合蛋白2的结构与功能研究进展

线粒体融合蛋白2(mitofusin 2,Mfn2)位于线粒体外膜上,是线粒体外膜融合的重要蛋白之一。研究发现,它不仅参与调控线粒体形态结构,还与细胞代谢、增殖、凋亡密切相关。近年来资料提示,Mfn2参与调控内质网应激、自噬、线粒体自噬等方面。由于Mfn2作用复杂,生理状态下细胞内必定存在精细的调控网络以使其保持在稳定水平。本文概括介绍了Mfn2结构、功能及其调控机制新进展。     

线粒体自噬的研究进展

线粒体自噬(mitophagy)是指细胞通过自噬机制选择性清除多余或损伤线粒体的过程,对于线粒体质量控制以及细胞生存具有重要作用。在线粒体自噬的过程中,线粒体自噬受体FUNDCl、Nix、BNIP3,接头蛋白OPTN、NDP52以及去泛素化酶UPS30、UPS8等发挥了重要的调控作用。近年来,研究发现线粒体自噬与神经退行性疾病、脑损伤以及胶质瘤相关。因此,研究线粒体自噬的分子机制具有重要意义。本文就与哺乳动物相关的线粒体自噬分子机制及最新研究进展做一综述。     

PINK1/Parkin介导的线粒体自噬

线粒体自噬（mitochondrial autophagy, or mitophagy）指的是细胞通过自吞噬作用,降解与清除受损线粒体或者多余线粒体,其对整个线粒体网络的功能完整性和细胞存活具有重要作用。线粒体自噬过程受多种途径调控,PINK1/Parkin通路是其中的一条,其异常与多种疾病的发生密切相关,如心血管疾病、肿瘤和帕金森病等。在去极化线粒体中,磷酸酶及张力蛋白同源物(PTEN)诱导的激酶1（PTEN-induced kinase 1,PINK1）作为受损线粒体的分子传感器,触发线粒体自噬的起始信号,并将Parkin募集至线粒体;Parkin作为线粒体自噬信号的“增强子”,通过对线粒体蛋白质进一步泛素化介导自噬信号的扩大;去泛素化酶和PTEN-long蛋白参与调控该过程,并对维持线粒体稳态具有重要作用。本文主要对PINK1与Parkin蛋白质的分子结构和其介导线粒体自噬发生的分子机制,以及参与调控该途径的关键蛋白质进行综述,为进一步研究以线粒体自噬缺陷为特征的疾病治疗提供理论基础。     

线粒体自噬进程及其受病毒感染的影响

线粒体自噬(mitophagy)属于巨自噬的范畴,即受损线粒体被一种双层膜结构(如粗面内质网的无核糖体附着区脱落的双层膜)包裹后形成自噬小体(autophagosome),接着自噬小体的外膜与溶酶体膜融合,底物蛋白进入溶酶体,最终被各类水解酶降解的一系列过程.然而,一些病毒的细胞感染过程与线粒体自噬的发生有着密切联系.本文对线粒体自噬发生的前提条件、起始与发展的全过程以及病毒感染对线粒体自噬的影响等进行综述,以期为进一步研究线粒体自噬提供新思路.     

鳞翅目昆虫中自噬相关分子Atg8的研究进展

自噬是细胞通过溶酶体自主降解以实现细胞内物质循环利用的过程,在昆虫细胞分化和个体发育中起着重要作用。鳞翅目昆虫属于完全变态昆虫,会通过自噬和凋亡完成蜕变重建过程,是研究自噬机制的模式生物。自噬相关蛋白Atg8是哺乳动物微管相关蛋白1轻链3的同系物,是自噬相关蛋白的核心蛋白家族,对自噬小体形成、膜的延伸、特定物质识别等具有重要意义。文中就鳞翅目昆虫Atg8在自噬信号通路中的作用、Atg8结构特点、Atg8表达分布及Atg8-PE/Atg8水平与自噬活性关系进行了综述。Atg8-PE是自噬信号通路中两个类泛素结合系统之一,在自噬中起着关键作用。序列分析表明,鳞翅目昆虫Atg8与其他真核生物同源蛋白的整体结构相似,尤其与其他昆虫同源蛋白的氨基酸序列高度一致,体现了Atg8的高度保守性。鳞翅目昆虫发育不同阶段,Atg8在中肠、唾液腺、卵巢、脂肪体、丝腺等器官中的表达分布各不相同。并且,Atg8在核质中分布也存在差异,Atg8在细胞核与细胞质之间的穿梭可能存在蛹化前阶段的某些细胞中。通过检测Atg8-PE在细胞内的表达水平或Atg8含量的变化,可以评价细胞自噬的发生程度。     

线粒体动力学及线粒体自噬调控机制的研究进展

线粒体形态和功能的异常与多种疾病的发生密切相关。线粒体通过不断的分裂和融合,维持线粒体网络的动态平衡,该过程称为线粒体动力学,是维持线粒体形态、分布和数量,保证细胞稳态的重要基础。此外,机体还通过线粒体自噬过程降解胞内功能异常的线粒体,维持线粒体稳态。线粒体动力学与线粒体自噬二者之间可相互调控,共同维持线粒体质量平衡。探讨线粒体动力学和线粒体自噬的调控机制对揭示多种疾病发生的分子机制、开发新的靶向线粒体动力学蛋白或线粒体自噬调控蛋白的药物具有重要意义。本文从线粒体动力学与线粒体自噬出发,对线粒体动力学调控机制、线粒体自噬及其发生机制以及二者的相互作用关系、线粒体动力学及线粒体自噬与人类相关疾病等方面作一综述。     

自体吞噬———Ⅱ型程序性死亡

自噬 (autophagy) 是广泛存在于真核细胞内的一种溶酶体依赖性的降解途径,在饥饿的条件下,它可以调节细胞内长寿命蛋白和细胞器的降解,降解产物再被细胞重新利用 . 因此自噬在细胞发育、细胞免疫、组织重塑及对环境适应等方面有着十分重要的作用 . 近来发现,自噬还参与降解病原微生物、抵御感染的过程,称之为异噬 . 对自噬的分子机制和调节以及其在生理病理过程中的作用进行相应讨论 .     

SIRT3抑制线粒体自噬并减轻高糖加重的神经元缺氧再灌注损伤*

目的:探讨SIRT3调控的线粒体自噬对高糖加重神经元缺氧再灌注损伤的影响及机制。方法:高糖(50 mmol/L)干预HT22细胞后,构建细胞缺氧/复氧模型,利用SIRT3抑制剂3-TYP抑制SIRT3表达。倒置显微镜观察细胞形态改变,CCK8法检测细胞存活率,流式细胞术检测细胞凋亡率,TMRE荧光试剂盒检测细胞线粒体膜电位,RT-qPCR、Western blot检测相关分子的基因和蛋白质表达。结果:高糖使神经元缺氧再灌注后的细胞碎片进一步增加,细胞存活率降低,细胞凋亡率升高(P<0.05)。此外,高糖降低了神经元缺氧再灌注后的线粒体膜电位(P<0.05)。进一步研究发现,高糖上调神经元缺氧再灌注后线粒体分裂相关蛋白DRP1的表达水平,降低了线粒体融合相关蛋白OPA1和线粒体外膜蛋白TOM20的表达;并且增加了自噬相关蛋白LC3Ⅱ、Beclin-1和线粒体自噬相关蛋白PINK1、Parkin的表达;同时,高糖升高了SIRT3的基因和蛋白质表达(P<0.05)。而SIRT3抑制剂3-TYP使神经元高糖缺氧再灌注损伤加重,同时进一步上调DRP1、LC3Ⅱ和PINK1的蛋白质表达(P<0.05)。结论:高糖可显著加重神经元缺氧再灌注损伤,破坏细胞线粒体功能,激活细胞线粒体自噬;SIRT3可抑制PINK1-Parkin通路介导的线粒体自噬并减轻神经元高糖缺氧再灌注损伤。     

Autophagy-related protein 32 acts as autophagic degron and directly initiates mitophagy

Autophagy-related degradation selective for mitochondria (mitophagy) is an evolutionarily conserved process that is thought to be critical for mitochondrial quality and quantity control. In budding yeast, autophagy-related protein 32 (Atg32) is inserted into the outer membrane of mitochondria with its N- and C-terminal domains exposed to the cytosol and mitochondrial intermembrane space, respectively, and plays an essential role in mitophagy. Atg32 interacts with Atg8, a ubiquitin-like protein localized to the autophagosome, and Atg11, a scaffold protein required for selective autophagy-related pathways, although the significance of these interactions remains elusive. In addition, whether Atg32 is the sole protein necessary and sufficient for initiation of autophagosome formation has not been addressed. Here we show that the Atg32 IMS domain is dispensable for mitophagy. Notably, when anchored to peroxisomes, the Atg32 cytosol domain promoted autophagy-dependent peroxisome degradation, suggesting that Atg32 contains a module compatible for other organelle autophagy. X-ray crystallography reveals that the Atg32 Atg8 family-interacting motif peptide binds Atg8 in a conserved manner. Mutations in this binding interface impair association of Atg32 with the free form of Atg8 and mitophagy. Moreover, Atg32 variants, which do not stably interact with Atg11, are strongly defective in mitochondrial degradation. Finally, we demonstrate that Atg32 forms a complex with Atg8 and Atg11 prior to and independent of isolation membrane generation and subsequent autophagosome formation. Taken together, our data implicate Atg32 as a bipartite platform recruiting Atg8 and Atg11 to the mitochondrial surface and forming an initiator complex crucial for mitophagy.     

Backbone and side chain resonance assignments for a structured domain within Atg32

Autophagy is a catabolic cellular process that targets cytosolic material, including mitochondria, to the vacuole or lysosomes for degradation. The selective degradation of mitochondria by autophagy is termed mitophagy. Dysfunctional mitophagy, which leads to the accumulation of damaged mitochondria, has been implicated in Parkinson’s disease, cancer, cardiac disease and metabolic disease. In Saccharomyces cerevisiae, mitophagy is initiated by the autophagy receptor Atg32, an outer mitochondrial membrane protein. A lack of structural information for Atg32 has hindered our understanding of the molecular mechanisms of mitophagy initiation. To gain new structural insight into Atg32, we have identified the location of a structured domain within the cytosolic region of Atg32 and completed the backbone and side chain resonance assignments for this domain.     

The progression of peroxisomal degradation through autophagy requires peroxisomal division

Peroxisomes are highly dynamic organelles that have multiple functions in cellular metabolism. To adapt the intracellular conditions to the changing extracellular environment, peroxisomes undergo constitutive segregation and degradation. The segregation of peroxisomes is mediated by 2 dynamin-related GTPases, Dnm1 and Vps1, whereas, the degradation of peroxisomes is accomplished through pexophagy, a selective type of autophagy. During pexophagy, the size of the organelle is always a challenging factor for the efficiency of engulfment by the sequestering compartment, the phagophore, which implies a potential role for peroxisomal fission in the degradation process, similar to the situation with selective mitochondria degradation. In this study, we report that peroxisomal fission is indeed critical for the efficient elimination of the organelle. When pexophagy is induced, both Dnm1 and Vps1 are recruited to the degrading peroxisomes through interactions with Atg11 and Atg36. In addition, we found that specific peroxisomal fission, which is only needed for pexophagy, occurs at mitochondria-peroxisome contact sites.     

The progression of peroxisomal degradation through autophagy requires peroxisomal division

Peroxisomes are highly dynamic organelles that have multiple functions in cellular metabolism. To adapt the intracellular conditions to the changing extracellular environment, peroxisomes undergo constitutive segregation and degradation. The segregation of peroxisomes is mediated by 2 dynamin-related GTPases, Dnm1 and Vps1, whereas, the degradation of peroxisomes is accomplished through pexophagy, a selective type of autophagy. During pexophagy, the size of the organelle is always a challenging factor for the efficiency of engulfment by the sequestering compartment, the phagophore, which implies a potential role for peroxisomal fission in the degradation process, similar to the situation with selective mitochondria degradation. In this study, we report that peroxisomal fission is indeed critical for the efficient elimination of the organelle. When pexophagy is induced, both Dnm1 and Vps1 are recruited to the degrading peroxisomes through interactions with Atg11 and Atg36. In addition, we found that specific peroxisomal fission, which is only needed for pexophagy, occurs at mitochondria-peroxisome contact sites.     

Different effects of Atg2 and Atg18 mutations on Atg8a and Atg9 trafficking during starvation in Drosophila

The Atg2–Atg18 complex acts in parallel to Atg8 and regulates Atg9 recycling from phagophore assembly site (PAS) during autophagy in yeast. Here we show that in Drosophila, both Atg9 and Atg18 are required for Atg8a puncta formation, unlike Atg2. Selective autophagic degradation of ubiquitinated proteins is mediated by Ref(2)P/p62. The transmembrane protein Atg9 accumulates on refractory to Sigma P (Ref(2)P) aggregates in Atg7, Atg8a and Atg2 mutants. No accumulation of Atg9 is seen on Ref(2)P in cells lacking Atg18 or Vps34 lipid kinase function, while the Atg1 complex subunit FIP200 is recruited. The simultaneous interaction of Atg18 with both Atg9 and Ref(2)P raises the possibility that Atg18 may facilitate selective degradation of ubiquitinated protein aggregates by autophagy.     

Drosophila Gyf/GRB10 interacting GYF protein is an autophagy regulator that controls neuron and muscle homeostasis

Autophagy is an essential process for eliminating ubiquitinated protein aggregates and dysfunctional organelles. Defective autophagy is associated with various degenerative diseases such as Parkinson disease. Through a genetic screening in Drosophila, we identified CG11148, whose product is orthologous to GIGYF1 (GRB10-interacting GYF protein 1) and GIGYF2 in mammals, as a new autophagy regulator; we hereafter refer to this gene as Gyf. Silencing of Gyf completely suppressed the effect of Atg1-Atg13 activation in stimulating autophagic flux and inducing autophagic eye degeneration. Although Gyf silencing did not affect Atg1-induced Atg13 phosphorylation or Atg6-Pi3K59F (class III PtdIns3K)-dependent Fyve puncta formation, it inhibited formation of Atg13 puncta, suggesting that Gyf controls autophagy through regulating subcellular localization of the Atg1-Atg13 complex. Gyf silencing also inhibited Atg1-Atg13-induced formation of Atg9 puncta, which is accumulated upon active membrane trafficking into autophagosomes. Gyf-null mutants also exhibited substantial defects in developmental or starvation-induced accumulation of autophagosomes and autolysosomes in the larval fat body. Furthermore, heads and thoraxes from Gyf-null adults exhibited strongly reduced expression of autophagosome-associated Atg8a-II compared to wild-type (WT) tissues. The decrease in Atg8a-II was directly correlated with an increased accumulation of ubiquitinated proteins and dysfunctional mitochondria in neuron and muscle, which together led to severe locomotor defects and early mortality. These results suggest that Gyf-mediated autophagy regulation is important for maintaining neuromuscular homeostasis and preventing degenerative pathologies of the tissues. Since human mutations in the GIGYF2 locus were reported to be associated with a type of familial Parkinson disease, the homeostatic role of Gyf-family proteins is likely to be evolutionarily conserved.     

A landmark protein essential for mitophagy

Degradation of mitochondria is a fundamental process conserved from yeast to humans that utilizes the machinery of autophagy. In contrast to starvation-induced, nonselective autophagy responsible for nutrient recycling, selective autophagy, which involves particular cues and receptors required for induction and cargo recognition, respectively, mediates mitochondria-specific breakdown. Although numerous studies highlight that mitochondria autophagy (mitophagy) contributes to homeostatic control of mitochondria, the molecular mechanisms underlying this selective clearance process are poorly understood. Using a genome-wide visual screen, we identified Atg32, a protein essential for mitophagy in budding yeast. During respiratory growth, Atg32 is highly expressed, likely in response to oxidative stress, and anchored on the surface of mitochondria. We also demonstrate that Atg32 interacts with Atg8 and Atg11, proteins critical for recognition of cargo receptors. Notably, Atg32 contains WXXI/L/V, a conserved motif that serves as a binding site for the Atg8 family members. Our recent findings suggest that Atg32 is a transmembrane receptor that directs autophagosome formation to mitochondria.     

Atg17/FIP200 localizes to perilysosomal Ref(2)P aggregates and promotes autophagy by activation of Atg1 in Drosophila

Phagophore-derived autophagosomes deliver cytoplasmic material to lysosomes for degradation and reuse. Autophagy mediated by the incompletely characterized actions of Atg proteins is involved in numerous physiological and pathological settings including stress resistance, immunity, aging, cancer, and neurodegenerative diseases. Here we characterized Atg17/FIP200, the Drosophila ortholog of mammalian RB1CC1/FIP200, a proposed functional equivalent of yeast Atg17. Atg17 disruption inhibits basal, starvation-induced and developmental autophagy, and interferes with the programmed elimination of larval salivary glands and midgut during metamorphosis. Upon starvation, Atg17-positive structures appear at aggregates of the selective cargo Ref(2)P/p62 near lysosomes. This location may be similar to the perivacuolar PAS (phagophore assembly site) described in yeast. Drosophila Atg17 is a member of the Atg1 kinase complex as in mammals, and we showed that it binds to the other subunits including Atg1, Atg13, and Atg101 (C12orf44 in humans, 9430023L20Rik in mice and RGD1359310 in rats). Atg17 is required for the kinase activity of endogenous Atg1 in vivo, as loss of Atg17 prevents the Atg1-dependent shift of endogenous Atg13 to hyperphosphorylated forms, and also blocks punctate Atg1 localization during starvation. Finally, we found that Atg1 overexpression induces autophagy and reduces cell size in Atg17-null mutant fat body cells, and that overexpression of Atg17 promotes endogenous Atg13 phosphorylation and enhances autophagy in an Atg1-dependent manner in the fat body. We propose a model according to which the relative activity of Atg1, estimated by the ratio of hyper- to hypophosphorylated Atg13, contributes to setting low (basal) vs. high (starvation-induced) autophagy levels in Drosophila.     

Mitochondria: The hub of energy deprivation-induced autophagy

Macroautophagy/autophagy, a process that is highly conserved from yeast to mammals, delivers unwanted cellular contents to lysosomes or the vacuole for degradation. It has been reported that autophagy is crucial for maintaining glucose homeostasis. However, the mechanism by which energy deprivation induces autophagy is not well established. Recently, we found that Mec1/ATR, originally identified as a sensor of DNA damage, is essential for glucose starvation-induced autophagy. Mec1 is recruited to mitochondria where it is phosphorylated by activated Snf1 in response to glucose starvation. Phosphorylation of Mec1 leads to the assembly of a Snf1-Mec1-Atg1 module on mitochondria, which promotes the association of Atg1 with Atg13. Furthermore, we found that mitochondrial respiration is specifically required for glucose starvation-induced autophagy but not autophagy induced by canonical stimuli. The Snf1-Mec1-Atg1 module is essential for maintaining mitochondrial respiration and regulating glucose starvation-induced autophagy.     

An Atg9-containing compartment that functions in the early steps of autophagosome biogenesis

Eukaryotes use the process of autophagy, in which structures targeted for lysosomal/vacuolar degradation are sequestered into double-membrane autophagosomes, in numerous physiological and pathological situations. The key questions in the field relate to the origin of the membranes as well as the precise nature of the rearrangements that lead to the formation of autophagosomes. We found that yeast Atg9 concentrates in a novel compartment comprising clusters of vesicles and tubules, which are derived from the secretory pathway and are often adjacent to mitochondria. We show that these clusters translocate en bloc next to the vacuole to form the phagophore assembly site (PAS), where they become the autophagosome precursor, the phagophore. In addition, genetic analyses indicate that Atg1, Atg13, and phosphatidylinositol-3-phosphate are involved in the further rearrangement of these initial membranes. Thus, our data reveal that the Atg9-positive compartments are important for the de novo formation of the PAS and the sequestering vesicle that are the hallmarks of autophagy.