Autophagosomes,phagosomes, autolysosomes,phagolysosomes, autophagolysosomes… Wait,I’m confused

When an autophagosome or an amphisome fuse with a lysosome, the resulting compartment is referred to as an autolysosome. Some people writing papers on the topic of autophagy use the terms “autolysosome” and “autophagolysosome” interchangeably. We contend that these words should be used to denote 2 different compartments, and that it is worthwhile maintaining this distinction—the autophagolysosome has a particular origin in the process of xenophagy that makes it distinct from an autolysosome.     

Autophagy and innate immunity: Triggering,targeting and tuning

Autophagy is a conserved catabolic stress response pathway that is increasingly recognized as an important component of both innate and acquired immunity to pathogens. The activation of autophagy during infection not only provides cell-autonomous protection through lysosomal degradation of invading pathogens (xenophagy), but also regulates signaling by other innate immune pathways. This review will focus on recent advances in our understanding of three major areas of the interrelationship between autophagy and innate immunity, including how autophagy is triggered during infection, how invading pathogens are targeted to autophagosomes, and how the autophagy pathway participates in “tuning” the innate immune response.     

Autophagy in regulation of Toll-like receptor signaling

Toll-like receptors (TLRs) serve as the major innate immune sensors for detection of specific molecular patterns on various pathogens. TLRs activate signaling events mainly by utilizing ubiquitin-dependent mechanisms. Recent research advances have provided evidence that TLR signaling is linked to induction of autophagy. Autophagy is currently known to affect both of the immune defense and suppression of inflammatory responses. In TLR-associated immune responses, autophagic lysis of intracellular microbes (called xenophagy) contributes to the former mechanism, while the latter seems to be mediated by the control of the mitochondrial integrity or selective autophagic clearance of aggregated signaling proteins (called aggrephagy). Several autophagy-related ubiquitin-binding proteins, such as SQSTM1/p62 and NDP52, mediate xenophagy and aggrephagy. In this review, we summarize the expanded knowledge regarding TLR signaling and autophagy signaling. After that, we will focus on autophagy-associated signaling downstream of TLRs and the effect of autophagy on TLR signaling, thus highlighting the signaling crosstalk between the TLR-associated innate immune responses and the regulation of innate immunity by xenophagy and aggrephagy.     

Bacterial xenophagy and its possible role in cancer: A potential antimicrobial strategy for cancer prevention and treatment

Macroautophagy/autophagy is a conserved catabolic process through which cellular excessive or dysfunctional proteins and organelles are transported to the lysosome for terminal degradation and recycling. Over the past few years increasing evidence has suggested that autophagy is not only a simple metabolite recycling mechanism, but also plays a critical role in the removal of intracellular pathogens such as bacteria and viruses. When autophagy engulfs intracellular pathogens, the pathway is called ‘xenophagy’ because it leads to the elimination of foreign microbes. Recent studies support the idea that xenophagy can be modulated by bacterial infection. Meanwhile, convincing evidence indicates that xenophagy may be involved in malignant transformation and cancer therapy. Xenophagy can suppress tumorigenesis, particularly during the early stages of tumor initiation. However, in established tumors, xenophagy may also function as a prosurvival pathway in response to microenvironment stresses including bacterial infection. Therefore, bacterial infection-related xenophagy may have an effect on tumor initiation and cancer treatment. However, the role and machinery of bacterial infection-related xenophagy in cancer remain elusive. Here we will discuss recent developments in our understanding of xenophagic mechanisms targeting bacteria, and how they contribute to tumor initiation and anticancer therapy. A better understanding of the role of xenophagy in bacterial infection and cancer will hopefully provide insight into the design of novel and effective therapies for cancer prevention and treatment.     

Eating the strangers within: host control of intracellular bacteria via xenophagy

Many bacterial pathogens rely on an intracellular cycle to ensure their proliferation within infected hosts, through their ability to avoid or circumvent host bactericidal pathways. Recent evidence supports an increasingly important role for the autophagy pathway in innate immune defences against intracellular pathogens, as a mechanism of capture of either cytosol-adapted or vacuolar bacteria that redirect them to the lysosomal compartment for killing. Antibacterial autophagy, also referred to as xenophagy, involves selective recognition of intracellular bacteria and their targeting to the autophagic machinery for degradation. Here we review recent advances in our molecular understanding of these processes, and in how bacteria have adapted to avoid xenophagy or even take advantage of this innate immune process.     

Eating oneself and uninvited guests: autophagy-related pathways in cellular defense

The eukaryotic cell uses an evolutionarily conserved lysosomal pathway of self-digestion (autophagy) for survival when extracellular nutrients are limited. In this issue of Cell, new evidence indicates that autophagy is used to for survival when intracellular nutrients are limited by growth factor deprivation (Lum et al., 2005). Other recent studies indicate that the autophagy machinery is also used to degrade foreign microbial invaders (xenophagy).     

Autophagy: Mechanisms, regulation, and its role in tumorigenesis

Autophagy (from Greek “auto” — self, “phagos” — to eat) is the major catabolic process involved in the delivery and lysosomal degradation of long-lived intracellular components: proteins, lipids, nucleic acids, and organelles. Since the discovery of genes involved in regulation of autophagy in the 1990s, there has been a significant increase in studies of autophagy as a process involved in maintaining cellular homeostasis, as well as its role in the development of different pathologies. This review focuses on the basics of autophagy and its regulatory mechanisms. The role of autophagy in the maintenance of cellular homeostasis and tumorigenesis is also discussed.     

异体自噬的操控:病原微生物对宿主翻译后修饰的调节作用

自噬是一种广泛存在于真核细胞中的溶酶体依赖性分解代谢途径,涉及细胞分化、饥饿耐受和免疫防御等生物学功能.其中,异体自噬被定义为真核细胞特异性识别并清除胞内病原微生物的过程,是免疫细胞行使宿主防御的重要方式.然而,许多病原微生物已经"开发"了特殊的毒力因子(包括效应蛋白质和表面蛋白质等),衍生出多种逃避或劫持自噬作用的策...     

The Autophagy Receptor TAX1BP1 and the Molecular Motor Myosin VI Are Required for Clearance of Salmonella Typhimurium by Autophagy

Autophagy plays a key role during Salmonella infection, by eliminating these pathogens following escape into the cytosol. In this process, selective autophagy receptors, including the myosin VI adaptor proteins optineurin and NDP52, have been shown to recognize cytosolic pathogens. Here, we demonstrate that myosin VI and TAX1BP1 are recruited to ubiquitylated Salmonella and play a key role in xenophagy. The absence of TAX1BP1 causes an accumulation of ubiquitin-positive Salmonella, whereas loss of myosin VI leads to an increase in ubiquitylated and LC3-positive bacteria. Our structural studies demonstrate that the ubiquitin-binding site of TAX1BP1 overlaps with the myosin VI binding site and point mutations in the TAX1BP1 zinc finger domains that affect ubiquitin binding also ablate binding to myosin VI. This mutually exclusive binding and the association of TAX1BP1 with LC3 on the outer limiting membrane of autophagosomes may suggest a molecular mechanism for recruitment of this motor to autophagosomes. The predominant role of TAX1BP1, a paralogue of NDP52, in xenophagy is supported by our evolutionary analysis, which demonstrates that functionally intact NDP52 is missing in Xenopus and mice, whereas TAX1BP1 is expressed in all vertebrates analysed. In summary, this work highlights the importance of TAX1BP1 as a novel autophagy receptor in myosin VI-mediated xenophagy. Our study identifies essential new machinery for the autophagy-dependent clearance of Salmonella typhimurium and suggests modulation of myosin VI motor activity as a potential therapeutic target in cellular immunity.     

Autophagy–virus interplay in plants: from antiviral recognition to proviral manipulation

Autophagy is a conserved self-cleaning and renewal system required for cellular homeostasis and stress tolerance. Autophagic processes are also implicated in the response to ‘non-self’ such as viral pathogens, yet the functions and mechanisms of autophagy during plant virus infection have only recently started to be revealed. Compelling evidence now indicates that autophagy is an integral part of antiviral immunity in plants. It can promote the hypersensitive cell death response upon incompatible viral infections or mediate the selective elimination of entire particles and individual proteins from compatible viruses in a pathway similar to xenophagy in animals. Several viruses, however, have evolved measures to antagonize xenophagic degradation or utilize autophagy to suppress disease-associated cell death and other defence pathways like RNA silencing. Here, we highlight the current advances and gaps in our understanding of the complex autophagy–virus interplay and its consequences for host immunity and viral pathogenesis in plants.     

Phospholipid synthetic defect and mitophagy in muscle disease

Mitophagy, selective autophagy of mitochondria, has been extensively demonstrated in cultured cell models but has never been described in skeletal muscle in the context of muscle disease. We recently reported the first example of human muscle disease where mitophagy plays a role in the peculiar muscle pathology. This disease is caused by loss-of-function mutations in the CHKB gene encoding choline kinase β. “Patients” and rostrocaudal muscular dystrophy (rmd) mice, spontaneous Chkb mutants, develop congenital muscular dystrophy with a peculiar mitochondrial abnormality—mitochondria are markedly enlarged at the periphery of muscle fibers and absent from the center. Choline kinase is the first enzymatic step in a biosynthetic pathway for phosphatidylcholine, the most abundant phospholipid in eukaryotes. Our discovery demonstrates that a phosphatydilcholine biosynthetic defect leads to mitochondrial dysfunction and increased mitophagy.     

PKR-dependent autophagic degradation of herpes simplex virus type 1

The lysosomal pathway of autophagy is the major catabolic mechanism for degrading long-lived cellular proteins and cytoplasmic organelles. Recent studies have also shown that autophagy (xenophagy) may be used to degrade bacterial pathogens that invade intracellularly. However, it is not yet known whether xenophagy is a mechanism for degrading viruses. Previously, we showed that autophagy induction requires the antiviral eIF2alpha kinase signaling pathway (including PKR and eIF2alpha) and that this function of eIF2alpha kinase signaling is antagonized by the herpes simplex virus (HSV-1) neurovirulence gene product, ICP34.5. Here, we show quantitative morphologic evidence of PKR-dependent xenophagic degradation of herpes simplex virions and biochemical evidence of PKR and eIF2alpha-dependent degradation of HSV-1 proteins, both of which are blocked by ICP34.5. Together, these findings indicate that xenophagy degrades HSV-1 and that this cellular function is antagonized by the HSV-1 neurovirulence gene product, ICP34.5. Thus, autophagy-related pathways are involved in degrading not only cellular constituents and intracellular bacteria, but also viruses.     

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 .     

A bacterial effector counteracts host autophagy by promoting degradation of an autophagy component

Beyond its role in cellular homeostasis, autophagy plays anti‐ and promicrobial roles in host–microbe interactions, both in animals and plants. One prominent role of antimicrobial autophagy is to degrade intracellular pathogens or microbial molecules, in a process termed xenophagy. Consequently, microbes evolved mechanisms to hijack or modulate autophagy to escape elimination. Although well‐described in animals, the extent to which xenophagy contributes to plant–bacteria interactions remains unknown. Here, we provide evidence that Xanthomonas campestris pv. vesicatoria (Xcv) suppresses host autophagy by utilizing type‐III effector XopL. XopL interacts with and degrades the autophagy component SH3P2 via its E3 ligase activity to promote infection. Intriguingly, XopL is targeted for degradation by defense‐related selective autophagy mediated by NBR1/Joka2, revealing a complex antagonistic interplay between XopL and the host autophagy machinery. Our results implicate plant antimicrobial autophagy in the depletion of a bacterial virulence factor and unravel an unprecedented pathogen strategy to counteract defense‐related autophagy in plant–bacteria interactions.     

Selective autophagy gets more selective: Uncoupling of autophagy flux and xenophagy flux in Mycobacterium tuberculosis-infected macrophages

Induction of autophagy has been reported as a potential means to eliminate intracellular pathogens. Corroborating that, many studies report inhibition of autophagy as a survival strategy of bacterial pathogens. Incidentally, autophagy at the basal level is critical for survival of host cells including macrophages. We asked how a bacterial pathogen could inhibit autophagy for its survival if the inhibition resulted in cell death. In a recent study we show distinct regulation of autophagy in Mycobacterium tuberculosis (Mtb)-infected macrophages where Mtb containing- and nonMtb-containing autophagosomes show different fates in terms of maturation. We show that upon Mtb infection, there is no dramatic change in the autophagy flux in macrophages. However, autophagosomes that contain the virulent strains of Mtb show selective resilience to the maturation phase of autophagy. Surprisingly, nonMtb-containing autophagosomes in the infected cells continue to mature into autolysosomes. The block in the xenophagy flux is missing in the case of avirulant infections. We show that this selectivity is achieved through selective exclusion of RAB7 from virulent Mtb-containing autophagosomes, thereby restricting the formation of amphisomes.     

Viral evasion of autophagy

Autophagy is an evolutionarily ancient pathway for survival during different forms of cellular stress, including infection with viruses and other intracellular pathogens. Autophagy may protect against viral infection through degradation of viral components (xenophagy), by promoting the survival or death of infected cells, through delivery of Toll-like receptor (TLR) ligands to endosomes to activate innate immunity, or by feeding antigens to MHC class II compartments to activate adaptive immunity. Given this integral role of autophagy in innate and adaptive antiviral immunity, selective pressure likely promoted the emergence of escape mechanisms by pathogenic viruses. This review will briefly summarize the current understanding of autophagy as an antiviral pathway, and then discuss strategies that viruses may utilize to evade this host defense mechanism.     

PKR-Dependent Xenophagic Degradation of Herpes Simplex Virus Type 1

The lysosomal pathway of autophagy is the major catabolic mechanism for degrading long-lived cellular proteins and cytoplasmic organelles. Recent studies have also shown that autophagy (xenophagy) may be used to degrade bacterial pathogens that invade intracellularly. However, it is not yet known whether xenophagy is a mechanism for degrading viruses. Previously, we showed that autophagy induction requires the antiviral eIF2alpha kinase signaling pathway (including PKR and eIF2alpha) and that this function ofeIF2alpha kinase signaling is antagonized by the herpes simplex virus (HSV-1) neurovirulence gene product, ICP34.5. Here, we show quantitative morphologic evidence of PKR-dependent xenophagic degradation of herpes simplex virions and biochemical evidence of PKR and eIF2alpha-dependent degradation of HSV-1 proteins, both of which are blocked by ICP34.5. Together, these findings indicate that xenophagy degrades HSV-1 and that this cellular function is antagonized by the HSV-1 neurovirulence gene product, ICP34.5. Thus, autophagy-related pathways are involved in degrading not only cellular constituents and intracellular bacteria, but also viruses.     

Why just eat in,when you can also eat out?

The current working definition of autophagy is the following: all processes in which intracellular material is degraded within the lysosome/vacuole and where the macromolecular constituents are recycled. There are several ways to classify the different types of autophagy. For example, we can separate autophagy into two primary types, based on the initial site of cargo sequestration. In particular, during microautophagy and chaperone-mediated autophagy, uptake occurs directly at the limiting membrane of the lysosome or vacuole. In contrast, macroautophagy—whether selective or nonselective—and endosomal microautophagy involve sequestration within an autophagosome or an omegasome, or late endosomes/multivesicular bodies, respectively; the key point being that in these types of autophagy the initial sequestration event does not occur at the limiting membrane of the degradative organelle. In any case, the cargo is ultimately delivered into the lysosome or vacuole lumen for subsequent degradation. Thus, I think most autophagy researchers view the degradative organelle as the ultimate destination of the pathway. Indeed, this fits with the general concept that organelles allow reactions to be compartmentalized. With regard to the lysosome or vacuole, this also confers a level of safety by keeping the lytic contents away from the remainder of the cell. If we are willing to slightly modify our definition of autophagy, with a focus on “degradation of a cell’s own components through the lysosomal/vacuolar machinery,” we can include a newly documented process, programmed nuclear destruction (PND).