Viruses and the autophagy machinery

Autophagy is a major intracellular pathway for degradation and recycling of long-lived proteins and cytoplasmic organelles that plays an essential role in maintenance of homeostasis in response to starvation and other cellular stresses. Autophagy is also important for a variety of other processes including restriction of intracellular pathogen replication. Our understanding of the fascinating relationship between viruses and the autophagy machinery is still in its infancy but it is clear that autophagy is a newly recognized facet of innate and adaptive immunity against viral infection. Although the autophagy pathway is emerging as a component of host defense, certain viruses have developed strategies to counteract these antiviral mechanisms, and others appear to have co-opted the autophagy machinery as proviral host factors favoring viral replication. The complex interplay between autophagy and viral infection will be discussed in this review.     

Autophagy and the cytoskeleton: new links revealed by intracellular pathogens

Actin-based motility is used by various pathogens such as Listeria and Shigella for dissemination within cells: and tissues, yet host factors counteracting this process have not been identified. We have recently discovered that infected host cells can prevent actin-based motility of Shigella by compartmentalizing bacteria inside 'septin cages,' revealing a novel mechanism of host defense that restricts dissemination. Because bacterial proteins controlling actin-based motility also regulate the autophagy process, we hypothesized and then established a link between septin caging and autophagy. Together, these results unveiled the first cellular mechanism that counteracts pathogen dissemination. Understanding the role of septins, a so far poorly characterized component of the cytoskeleton, will thus provide new insights into bacterial infection and autophagy.     

Autophagy and inflammatory cell death, partners of innate immunity

By law in the evolutionary jungle, any host defense mechanism that efficiently kills microbes also exerts a strong selective pressure for tolerant variants to emerge. As a consequence, pathogens can be exploited as powerful tools to examine host defense mechanisms. Recent studies of the confrontation between macrophages and the opportunistic pathogen Legionella pneumophila have revealed a regulatory mechanism that may link autophagy to pyroptosis, a type of programmed cell death. Building from the extensive literature on autophagy, cell death, and innate immunity, we propose here a testable model in which the NOD-LRR protein Naip5 dictates whether murine macrophages elevate autophagy or pyroptosis as a barrier to infection.     

Autophagy in the intestinal epithelium regulates Citrobacter rodentium infection

Autophagy, a ubiquitous degradation pathway, is important for the survival and homeostasis of cells. Previous studies have demonstrated the role of autophagy in host defense against bacterial infection, but the importance of autophagy in the intestinal epithelium for the regulation of bacterial infection has not been fully elucidated. In this study, we showed that the essential autophagy protein Atg7 is required for resistance to Citrobacter rodentium infection in the intestinal epithelium. Infected mice in which Atg7 had been conditionally deleted from the intestinal epithelium exhibited greater clinical evidence of disease and higher expression levels of pro-inflammatory cytokine mRNA in the large intestine. Moreover, C. rodentium clearance was reduced in the Atg7 conditional knockout mice. These results demonstrate that autophagy in intestinal epithelial cells plays an important role in host defense against C. rodentium infection and the regulation of C. rodentium infectious colitis.     

Autophagy Enhances Bacterial Clearance during P. aeruginosa Lung Infection

Pseudomonas aeruginosa is an opportunistic bacterial pathogen which is the leading cause of morbidity and mortality among cystic fibrosis patients. Although P. aeruginosa is primarily considered an extacellular pathogen, recent reports have demonstrated that throughout the course of infection the bacterium acquires the ability to enter and reside within host cells. Normally intracellular pathogens are cleared through a process called autophagy which sequesters and degrades portions of the cytosol, including invading bacteria. However the role of autophagy in host defense against P. aeruginosa in vivo remains unknown. Understanding the role of autophagy during P. aeruginosa infection is of particular importance as mutations leading to cystic fibrosis have recently been shown to cause a blockade in the autophagy pathway, which could increase susceptibility to infection. Here we demonstrate that P. aeruginosa induces autophagy in mast cells, which have been recognized as sentinels in the host defense against bacterial infection. We further demonstrate that inhibition of autophagy through pharmacological means or protein knockdown inhibits clearance of intracellular P. aeruginosa in vitro, while pharmacologic induction of autophagy significantly increased bacterial clearance. Finally we find that pharmacological manipulation of autophagy in vivo effectively regulates bacterial clearance of P. aeruginosa from the lung. Together our results demonstrate that autophagy is required for an effective immune response against P. aeruginosa infection in vivo, and suggest that pharmacological interventions targeting the autophagy pathway could have considerable therapeutic potential in the treatment of P. aeruginosa lung infection.     

细胞自噬与机体免疫机制及抗微生物感染的关系

细胞自噬作为细胞的一种生理机制,一方面为细胞提供再生资源,一方面也可以作为防御机制抵抗微生物的感染和寄生。本文对它与先天性免疫、适应性免疫的关系做了综述,并探讨了自噬与微生物感染的关系。本文为我们理解细胞自噬在机体抗感染机制中的作用提供了帮助,也为我们研究感染性疾病治疗药物开启新的视野。     

Autophagy and the cytoskeleton

Actin-based motility is used by various pathogens such as Listeria and Shigella for dissemination within cells

and tissues, yet host factors counteracting this process have not been identified. We have recently discovered that infected host cells can prevent actin-based motility of Shigella by compartmentalizing bacteria inside ‘septin cages,’ revealing a novel mechanism of host defense that restricts dissemination. Because bacterial proteins controlling actin-based motility also regulate the autophagy process, we hypothesized and then established a link between septin caging and autophagy. Together, these results unveiled the first cellular mechanism that counteracts pathogen dissemination. Understanding the role of septins, a so far poorly characterized component of the cytoskeleton, will thus provide new insights into bacterial infection and autophagy.     

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.     

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.     

Nondegradative role of Atg5-Atg12/ Atg16L1 autophagy protein complex in antiviral activity of interferon gamma

Host resistance to viral infection requires type I (α/β) and II (γ) interferon (IFN) production. Another important defense mechanism is the degradative activity of macroautophagy (herein autophagy), mediated by the coordinated action of evolutionarily conserved autophagy proteins (Atg). We show that the Atg5-Atg12/Atg16L1 protein complex, whose prior known function is in autophagosome formation, is required for IFNγ-mediated host defense against murine norovirus (MNV) infection. Importantly, the direct antiviral activity of IFNγ against MNV in macrophages required Atg5-Atg12, Atg7, and Atg16L1, but not induction of autophagy, the degradative activity of lysosomal proteases, fusion of autophagosomes and lysosomes, or the Atg8-processing protein Atg4B. IFNγ, via Atg5-Atg12/Atg16L1, inhibited formation of the membranous cytoplasmic MNV replication complex, where Atg16L1 localized. Thus, the Atg5-Atg12/Atg16L1 complex performs a pivotal, nondegradative role in IFNγ-mediated antiviral defense, establishing that multicellular organisms have evolved to use portions of the autophagy pathway machinery in a cassette-like fashion for host defense.     

Role of autophagy in disease resistance and hypersensitive response-associated cell death

Ancient autophagy pathways are emerging as key defense modules in host eukaryotic cells against microbial pathogens. Apart from actively eliminating intracellular intruders, autophagy is also responsible for cell survival, for example by reducing the deleterious effects of endoplasmic reticulum stress. At the same time, autophagy can contribute to cellular suicide. The concurrent engagement of autophagy in these processes during infection may sometimes mask its contribution to differing pro-survival and pro-death decisions. The importance of autophagy in innate immunity in mammals is well documented, but how autophagy contributes to plant innate immunity and cell death is not that clear. A few research reports have appeared recently to shed light on the roles of autophagy in plant-pathogen interactions and in disease-associated host cell death. We present a first attempt to reconcile the results of this research.     

Autophagy and Inflammatory Cell Death,Partners of Innate Immunity

Alas, it is the law of the evolutionary jungle that any host defen! se mechanism that efficiently kills microbes also exerts a strong selective pressure for tolerant variants to emerge. A silver lining in this otherwise dark cloud is that pathogens can be exploited as powerful tools to examine host defense mechanisms. Recent studies of the confrontation between macrophages and the opportunistic pathogen Legionella pneumophila have revealed a regulatory mechanism that may link autophagy to pyroptosis. Building from the extensive literature on autophagy, cell death, and innate immunity, we propose here a testable model in which the NOD-LRR protein Naip5 dictates whether macrophages elevate autophagy or pyroptosis as a barrier to infection.     

Herpes Simplex Virus-1 Fine-Tunes Host’s Autophagic Response to Infection: A Comprehensive Analysis in Productive Infection Models

Herpes simplex virus-1 (HSV-1) infection causes severe conditions, with serious complications, including corneal blindness from uncontrolled ocular infections. An important cellular defense mechanism against HSV-1 infection is autophagy. The autophagic response of the host cell was suggested to be regulated by HSV-1. In this study, we performed a detailed analysis of autophagy in multiple HSV-1-targeted cell types, and under various infection conditions that recapitulate a productive infection model. We found that autophagy was slightly inhibited in one cell type, while in other cell types autophagy maintained its basal levels mostly unchanged during productive infection. This study refines the concept of HSV-1-mediated autophagy regulation to imply either inhibition, or prevention of activation, of the innate immune pathway.     

Phosphoethanolamine Modification of Neisseria gonorrhoeae Lipid A Reduces Autophagy Flux in Macrophages

Autophagy, an ancient homeostasis mechanism for macromolecule degradation, performs an important role in host defense by facilitating pathogen elimination. To counteract this host defense strategy, bacterial pathogens have evolved a variety of mechanisms to avoid or otherwise dysregulate autophagy by phagocytic cells so as to enhance their survival during infection. Neisseria gonorrhoeae is a strictly human pathogen that causes the sexually transmitted infection, gonorrhea. Phosphoethanolamine (PEA) addition to the 4'' position of the lipid A (PEA-lipid A) moiety of the lipooligosaccharide (LOS) produced by gonococci performs a critical role in this pathogen’s ability to evade innate defenses by conferring decreased susceptibility to cationic antimicrobial (or host-defense) peptides, complement-mediated killing by human serum and intraleukocytic killing by human neutrophils compared to strains lacking this PEA decoration. Heretofore, however, it was not known if gonococci can evade autophagy and if so, whether PEA-lipid A contributes to this ability. Accordingly, by using murine macrophages and human macrophage-like phagocytic cell lines we investigated if PEA decoration of gonococcal lipid A modulates autophagy formation. We report that infection with PEA-lipid A-producing gonococci significantly reduced autophagy flux in murine and human macrophages and enhanced gonococcal survival during their association with macrophages compared to a PEA-deficient lipid A mutant. Our results provide further evidence that PEA-lipid A produced by gonococci is a critical component in the ability of this human pathogen to evade host defenses.     

Crohn disease ATG16L1 polymorphism increases susceptibility to infection with Helicobacter pylori in humans

Autophagy plays key roles both in host defense against bacterial infection and in tumor biology. Helicobacter pylori (H. pylori) infection causes chronic gastritis and is the single most important risk factor for the development of gastric cancer in humans. Its vacuolating cytotoxin (VacA) promotes gastric colonization and is associated with more severe disease. Acute exposure to VacA initially triggers host autophagy to mitigate the effects of the toxin in epithelial cells. Recently, we demonstrated that chronic exposure to VacA leads to the formation of defective autophagosomes that lack CTSD/cathepsin D and have reduced catalytic activity. Disrupted autophagy results in accumulation of reactive oxygen species and SQSTM1/p62 both in vitro and in vivo in biopsy samples from patients infected with VacA (+) but not VacA (-) strains. We also determined that the Crohn disease susceptibility polymorphism in the essential autophagy gene ATG16L1 increases susceptibility to H. pylori infection. Furthermore, peripheral blood monocytes from individuals with the ATG16L1 risk variant show impaired autophagic responses to VacA exposure. This is the first study to identify both a host autophagy susceptibility gene for H. pylori infection and to define the mechanism by which the autophagy pathway is affected following H. pylori infection. Collectively, these findings highlight the synergistic effects of host and bacterial autophagy factors on H. pylori pathogenesis and the potential for subsequent cancer susceptibility.     

Secretory autophagy holds the key to lysozyme secretion during bacterial infection of the intestine

In 2013, Dr. Lora Hooper and colleagues described the induction of antibacterial macroautophagy/autophagy in intestinal epithelial cells as a cytoprotective host defense mechanism against invading Salmonella enterica serovar Typhimurium (S. Typhimurium). Canonical autophagy functions in a primarily degradative capacity to safeguard cells and ensure survival during stress conditions, including pathogen infection. In contrast, secretory autophagy has emerged as an alternative nondegradative mechanism for cellular trafficking and unconventional protein secretion. More recently, a study by Bel et al. from Dr. Hooper's lab describes how intestinal Paneth cells exploit the endoplasmic reticulum (ER) stress response to release antibacterial lysozyme through secretory autophagy in response to S. Typhimurium infection.     

Autophagy as a macrophage response to bacterial infection

The macrophage is a key component of host defense mechanisms against pathogens. In addition to the phagocytosis of bacteria and secretion of proinflammatory mediators by macrophages, autophagy, a process involved in turnover of cellular material, is a recently identified component of the immune response to bacterial infection. Despite the bactericidal effect of autophagy, some species of intracellular bacteria are able to survive by using one or more strategies to avoid host autophagic attack. Here, we review the latest findings on the interactions between bacteria and autophagy in macrophages. ? 2012 IUBMB Life, 64(9): 740-747, 2012.     

The induction of host cell autophagy triggers defense mechanisms against Trypanosoma cruzi infection in vitro

Trypanosoma cruzi causes Chagas disease, a neglected illness that affects millions of people worldwide, especially in Latin America. The balance between biochemical pathways triggered by the parasite and host cells response will ultimately define the progression of a life-threatening disease, justifying the efforts to understand cellular mechanisms for infection restrain. In this interaction, parasite and host cells are affected by different physiological responses as autophagy modulation, which could be under intense cellular stress, such as nutrient deprivation, hormone depletion, or infection. Autophagy is a constitutive pathway that leads to degradation of macromolecules and cellular structures and may induce cell death. In Trypanosoma cruzi infection, the relevance of host autophagy is controversial regarding in vitro parasite intracellular life cycle. In the present study, we evaluated host cell autophagy during T. cruzi infection in phagocytic and non-professional phagocytic cells. We described that the presence of the parasite increased the number of LC3 puncta, a marker for autophagy, in cardiac cells and peritoneal macrophages in vitro. The induction of host autophagy decreased infection in macrophages in early and late time-periods. We suggest that starved phagocytic cells reduced internalization, also confirmed by inert particles and dead trypomastigotes. Whereas, in cardiac cells, starvation-induced autophagy decreased lipid droplets and infection in later time-point, by reducing parasite differentiation/proliferation. In ATG5 knockout MEF cells, we confirmed our hypothesis of autophagy machinery activation during parasite internalization, increasing infection. Our data suggest that host autophagy downregulates T. cruzi infection through impairing parasite intracellular life cycle, reducing the infection in primary culture cells.