Abstract
Autophagy is a self-degradative process important for balancing cellular homeostasis at critical times in development and/or in response to nutrient stress. This is particularly relevant in tumor model in which autophagy has been demonstrated to have an important impact on tumor behavior. In one hand, autophagy limits tumor transformation of precancerous cells in early stage, and in the other hand, it favors the survival, proliferation, metastasis, and resistance to antitumor therapies in more advanced tumors. This catabolic machinery can be induced by an important variety of extra- and intracellular stimuli. For instance, viral infection has often been associated to autophagic modulation, and the role of autophagy in virus replication differs according to the virus studied. In the context of tumor development, virus-modulated autophagy can have an important impact on tumor cells’ fate. Extensive analyses have shed light on the molecular and/or functional complex mechanisms by which virus-modulated autophagy influences precancerous or tumor cell development. This review includes an overview of discoveries describing the repercussions of an autophagy perturbation during viral infections on tumor behavior.
Autophagy
Autophagy is a general term defining a catabolic mechanism present in all eukaryotic cells that leads to three different intracellular routes to the degradation of substrates present in the cell by the lysosome. It includes chaperone-mediated autophagy (CMA), microautophagy, and macroautophagy. CMA is the way by which cells degrade intracellular proteins by their translocation to the lysosome through the interaction of chaperone recognizing universal motif in the sequence of CMA substrate (KFERQ motif) and the lysosome protein LAMP-2A (1). Microautophagy involves a direct engulfment of cargos through the invagination of the lysosome membrane or through the direct entry of cytoplasmic materials to the multivesicular bodies of late endosomes (1). Macroautophagy, referred hereafter as autophagy, is a multistep process consisting of the formation of phagophore that elongates, engulfs targeted proteins or organelles in a double-membrane vesicle called autophagosome, and finally fuses with lysosome (Figure 1) (2). This process is orchestrated by more than 30 autophagic proteins (Atg), organized in complex. Autophagic induction is modulated by two protein complexes: the ULK1/2 (unc51-like autophagy activating kinase) and the Beclin-1/PI3KC3 (class III phosphatidylinositol 3-kinase) complexes. Once activated, these complexes recruit other proteins involved in elongation and formation of autophagosomes, including the two conjugated systems comprising Atg12-Atg5-Atg16L and LC3. After completion, the mature autophagosome fuses with lysosome to form autolysosome, wherein the sequestered materials and organelles are degraded by lysosomal enzymes (Figure 1). Even if autophagy has often been considered as a non-selective mechanism, many studies highlighted an important role for autophagy in selective materials and/or organelles recycling, including mitophagy, which selectively targets damaged mitochondria to autophagosome, or xenophagy, which permits the selective degradation of pathogens and/or pathogens’ elements through autophagy (2).
Figure 1
Since its discovery by Christian Deduve in 1963, our knowledges on autophagy and its role in physiology has greatly been increased. Autophagy acts as a quality control mechanism by degrading and recycling damaged or old proteins and organelles. Given its important role in homeostasis, it is not surprising that a defect of autophagy has been associated with various pathologies, including neurodegenerative diseases, infection susceptibility, aging, metabolic disorders, and cancer. In cancer, autophagy seems acting as a double-edged sword: in one hand, autophagy limits the tumorigenesis of precancerous cells, and in another hand, it serves as an important survival mechanism for established tumors. The role of autophagy in cancer will be detailed in the different parts of this review and is illustrated in Figure 2.
Figure 2
Autophagy and Viruses
As an intracellular parasite, a virus’s behavior is closely linked to its capacity to prevent and/or subvert cellular antiviral responses. Given that viral infection and replication cause cellular stresses, autophagy is frequently associated with a by-product of infection. However, viral infection-induced autophagy is not a passive process, and an increasing number of studies have shown that autophagy has both antiviral and proviral capacities for the replication of a broad range of viruses (3).
Viral Infections Modulate Autophagy
Any single step of viral life cycle, including virus binding, entry and recognition, membrane fusion, exposure of viral component, and replication or even antiviral responses, may modulate autophagy (Figure 1) (4–6).
The first evidence demonstrating that virions binding could induce autophagy has been observed following measles virus (MeV) infection (7). CD46, a complement family receptor, serves as a binding and entry receptor for vaccinal or attenuated strains of MeV (8, 9). The team of Mathias Faure demonstrated that MeV/CD46 binding leads to an induction of autophagy through a direct interaction of CD46 with the Beclin-1/PI3KC3 using a scaffold protein named Golgi associated PDZ and coiled coil motif-containing (GOPC) (7). Further investigations showed that MeV also activates autophagy by targeting an autophagy-associated protein called immunity-associated GTPase family M (IRGM) (10, 11). Human immunodeficiency virus type 1 (HIV-1) can also activate autophagy in uninfected CD4 T cells through the fusiogenic activity of envelope glycoproteins gp120 and gp41 (called Env) (12). While specific pathway has not been really elucidated, it is important to note that the signaling activity of CD4 and CXCR4 are not associated with autophagy induction in infected cells, in contrast to the fusiogenic activity of Env proteins (12).
In addition to binding and membrane fusion, a broad range of studies have demonstrated an induction of autophagy following the virus recognition. The delivery of viral elements into the cytosol can lead to the induction of autophagy through the activation of pattern recognition receptor (PRR). Among PRR, intracellular endosomal Toll-like receptors (TLRs) are important sensors of viral components, including single-stranded (ss)RNA (e.g., TLR7 and TLR8), double-stranded (ds)RNA (e.g., TLR3), and DNA with CpG site (e.g., TLR9). The majority of TLRs recruit the adaptor myeloid differentiation primary response protein MyD88, whereas TLR3 and TLR4 recruit the TIR domain-containing adaptor molecule 1 (TRIF). In all cases, TLR stimulation leads to the activation of nuclear factor-kB (NF-kB) for the production of inflammatory cytokines and interferon (IFN) production (13). TLR stimulation also activates autophagy, presumably by promoting the binding of both MyD88 or TRIF to Beclin-1 (14). The role of TLR-induced autophagy in virus remains to be determined, but several studies have shown an important impact of this process on antiviral immune responses (4). For instance, plasmacytoid dendritic cells (pDCs) deficient for Atg5 exhibited a reduced TLR-dependent production of IFNs after infection with vesicular stomatitis virus (VSV), sendai virus (SeV), or herpes virus type 1 (HSV-1) (15). The RIG-I like receptors (RLRs) retinoic acid-inducible gene I (RIG-I), which senses dsRNA in the cytosol, also induces autophagy following sendai virus infection (16). RIG-I-mediated autophagy is regulated by the translocation of beclin-1 into the mitochondria dependently of the mitochondrial antiviral signaling protein (MAVS) and tumor necrosis factor receptor-associated factor (TRAF) 6 (16). Protein Kinase R (PKR), which recognizes dsRNA, also triggers autophagy by the phosphorylation of the eukaryotic translation initiation factor (EiF) 2 (17). During HSV-1 infection, the cytosolic DNA sensor cyclic GMP_AMP (cGAMP) synthase (cGAS), which recognizes dsDNA, triggers autophagy through the activation of the initiation complex, releasing Rubicon (an autophagy inhibitor) from the beclin-1/PI3KC3 complex (18, 19).
Viral replication causes drastic modifications to cell homeostasis, which often enhance autophagy. As a good example, chikungunya virus (CHIKV) replication induces autophagy through the synergy of both endoplasmic reticulum (ER) and oxidative stresses (8). CHIKV proteins accumulation promotes ER stress and unfold protein responses (UPR) via the activation of inositol-requiring Ser/Thr protein kinase/endonuclease (IRE) 1a. CHIKV also increases the production of reactive oxygen species (ROS) and reactive nitrogen species (NOS), which stimulates autophagy by activating AMP-activated protein kinase (AMPK)-mediated inhibition of mammalian target of rapamycin complex 1 (mTORC1) (20). Similar observation has been reported during HCV infection, whose replication enhances ER and UPR responses that lead to autophagy induction (21).
Autophagy During Viral Infection: A Double-Edged Sword
Due to its role in cytosolic materials clearance, autophagy can degrade viral components, including viral particles or proteins or even host factors required for the replication of the virus. Indeed, autophagy is considered as an important part of innate antiviral responses, especially in non-immune cells. However, this virus-specific autophagic degradation, also known as virophagy, can be subverted by many viruses.
The first example of virophagy has been observed during Sindbis virus (SINV) infection, in which Beclin-1 and Atg5 protect against viral infection and finally against SINV-mediated encephalitis (22). Mechanistically, SAMD-specific E3 ubiquitin protein ligase 1 (SMUF1) and Fanconi anemia group C protein (FANCC) are both required for the delivery of SINV capsid protein into the autophagosome, through the interaction of the autophagy receptor p62 with SINV proteins (23, 24). SMURF1 and FANCC are also involved in the targeting of herpes simplex virus -1 (HSV-1) proteins for autophagic degradation (24). During poliovirus infection, galectin 8 restricts viral infection through the initiation of autophagic degradation of the viral RNA genome (25). Autophagic degradation of the viral non-structural protein A5 (NS5A) of hepatitis C virus (HCV) has been observed in infected cell through the interaction of NSA5 with an ER transmembrane protein, SHISA5 (26). Human immunodeficiency virus 1 (HIV-1) replication can also be perturbed by autophagic degradation. Histone deacetylase 6 (HDAC6), in complex with the HIV restriction factor APOBEC3G, is responsible for the degradation of the virion infectivity factor Vif by autophagy (27). In addition to eliminate Vif factor, autophagy also selectively degrades both the transactivator Tat, involved in viral transcription, and the restriction factor tripartite motif-containing protein 5α (TIRM5α), respectively, in HIV-infected CD4+ T cells and Langerhans cells (28, 29).
Autophagy can also influence the immune antiviral responses. In infected plasmacytoïd dendritic (pDC) cells, autophagy favors the transport of viral genome of vesicular stomatitis virus (VSV) from the cytosol to TLR7-containing endosome, enhancing the type I interferon (IFN) production (15). Similarly, in mouse models of murine norovirus (MNV) infection, production of IFNγ-mediated antiviral responses require the autophagy elongation complex Atg12/Atg5/Atg16L1 (30). Importantly, the antiviral adaptive immune response can also be modulated by autophagy, mainly by promoting viral antigen presentation on class II major histocompatibility complex (MHC). That mechanism has been notably observed for Epstein-Barr virus (EBV), SINV, or HSV (4, 31).
While autophagy can restrict viral infection, some persisting viruses have developed several strategies to escape from the autophagic degradation, or even manipulate autophagy for their own benefit. The inhibition of autophagy induction has been noticed for a broad range of viral infections mainly by targeting Beclin-1. Indeed, HSV-encoded neurovirulence factor ICP34.5, viral homologues of Bcl-2, ORF16, or M11—respectively expressed by Kaposi’s sarcoma associated herpesvirus (KHSV) and murine γ-herpers virus (MHV) 68—and human cytomegalovirus (HCMV)-encoded TRS1 and IRS1 are all viral proteins capable to bind Beclin-1 and inhibit autophagy (32–35). mTOR pathway, an important negative regulator of autophagy initiation complex, can also be targeted by viruses to inhibit autophagy. A good example is the KSHV G protein-coupled receptor (vGPCR), which stimulates mTOR pathway and therefore inhibits autophagy in cells during KHSV infection (36).
In addition to target the initiation step of autophagy, some viral proteins also prevent the fusion of autophagosomes with lysosomes. HSV-1 encodes the TANK-binding kinase (TBK1) protein to prevent autophagic degradation, by regulating the autophagosome maturation through the phosphorylation of the autophagy receptors p62 and optineurin (37). Similarly, the K7 protein of KHSV promotes rubicon/beclin-1 interaction and inhibits the activity of PI3KC3, which leads to the blocking of the fusion of autophagosomes with lysosomes (38). In most of the cases, viruses with the ability to block autophagy maturation step can use autophagic vacuoles as support membranes for their own replication. The first example of virus that has been described to manipulate autophagy to enhance its replication is the poliovirus, for which autophagy inhibition decreases infection efficiency, whereas the autophagy inducer rapamycin increases it (39). Other picornaviruses, such as coxsackievirus B3 (CVB3) and foot-and-month disease virus (FMDV), also use autophagy to replicate (40, 41). HCV induces the formation of autophagosomes but blocks its fusion with the lysosome, which favors viral replication and virion production (42). Like K7 protein of KHSV, HCV-encoded NS4B induces rubicon expression, leading to the inhibition of autophagy maturation (43). Influenza virus (IAV) and human parainfluenza virus type 3 (HPIV3) can also trigger the accumulation of autophagosomes for viral replication, respectively, via the interaction of the viral protein M2 or M with LC3 (44, 45).
Indeed, manipulation of autophagy by many viruses confers double advantages for viruses: (i) it permits to avoid their degradation by inhibiting the autophagy influx, and (ii) it supplies to the viruses a double-membrane vacuole that could serve as a support for their replication.
Oncogenic Viruses Modulate Autophagy to Favor Tumorigenesis
Oncogenic Viruses and Tumorigenesis
Cancer is a multifactorial disease, combining genetic predispositions and environmental factors. Among all the elements promoting the cancer development, viruses can be directly linked with the formation of tumor. It is now well admitted that 15% of human cancers are caused by viruses (46). So far, only seven viruses have been demonstrated to have an oncogenic activity: Epstein-Barr virus (EBV), hepatitis B and C viruses (HBV and HCV), human papilloma virus (HPV), human T lymphotrophic virus type 1 (HTLV-1), Kaposi sarcoma-associated herpes virus (KSHV), and Merkel cell polyomavirus (MCPyV). Despite being very different in terms of tropism or viral structure and cycle, they share one characteristic: they are all responsible for persistent infections, criteria that seem to be essential to lead to virus-mediated oncogenesis. In order to persist and proliferate, viruses have to maintain their genome inside infected cell, prevent apoptosis of host cell while favoring its replication and escaping from the recognition of antiviral immune cells (47). To do that, oncogenic viruses encode proteins, called oncoproteins, that target and inactivate tumor suppressor proteins, such as retinoblastoma protein (pRb) or tumor protein 53 (p53) (48–52). p53 is a key transcription factor activated under stress responses, and it is responsible for cell cycle arrest or apoptosis induction. Similarly, pRb blocks cell cycle progression in G1 phase under stress conditions. HBV-encoded hepatitis B virus X (HBx), HTLV-1-encoded latency-associated nuclear antigen (LANA), and MCPyV-encoded large T antigen are all viral proteins that target and inhibit both p53 and pRb (52–55). Oncogenic viruses can also express proteins that target specifically p53 [such as E6 protein of HPV, latent membrane protein 1 (LMP1) of EBV, or NS5A protein of HCV] or pRb [including core protein of HCV, Epstein Barr virus latent 3C (EBNA3C) of EBV or E7 protein of HPV] (56, 57). Dysregulation of several cell cycle components, such as cyclins and cyclin dependent kinases (CDK), are also observed following oncogenic virus infection to bypass cell cycle checkpoints and pursue an infinite proliferation of infected cell. For example, E6 and E7 proteins of HPV have inhibitory activities on the CDK inhibitors p21 or p27 (58–60). Direct integration of viral genomic materials into the host genome may also modify expression of tumorigenesis-leading genes (61). Other studies demonstrated that oncogenic viruses have also developed strategy to escape from antiviral immune responses, inhibiting type I IFN response or cytotoxic activities of CD8+ T cells and natural killer (NK) cells (62–75).
Oncogenic Viruses and Autophagy Inhibition
In precancerous cells, autophagy limits the formation of ROS, damages of DNA, and inflammation with the consequence of limiting tumorigenesis. This observation has been established in a lot of studies using different cancer models, where a decrease of autophagy activity has been observed in precancerous cells compared with non-tumor cells. Depletion of key autophagy genes has been associated with an increase of tumorigenesis in several tissues, leading to classify some autophagy genes as tumor suppressor genes. The first autophagy gene described to be involved in tumor formation is Beclin-1, for which a monoallelic depletion has been observed in various cancers (e.g., breast, ovarian, prostate, hepatocarcinoma, or lymphoma). Depletion of UVRAG in breast, colon, gastric, and prostate cancers also increases tumorigenesis (76–79). Similarly, knockout of both conjugated systems (Atg5/Atg7 or Atg3) favors tumorigenesis in liver tumor murine model, due to the accumulation of ROS in cells (80).
An increased range of studies highlighted that oncogenic viruses are able to modulate autophagy to persist in infected cells and/or favor the virus-induced tumorigenesis [extensively reviewed elsewhere (81–83)]. For instance, HPV inhibits autophagy during several steps of viral cycle. Cellular entry of type 16 HPV inhibits autophagy through the activation of autophagy-suppressor PI3K/akt/mTOR pathway, induced by the binding of viral proteins L1 and L2 to heparan sulfate proteoglycans (HSPGs) expressed on cell membrane (84). HPV-encoded E5 protein, by inhibiting p53, alters the transcription level of several autophagy genes involved in the formation of autophagosome (Beclin 1, atg5, atg7…), whereas E6 and E7 viral proteins inhibit the autophagy maturation step, observable by an accumulation of p62 (85, 86). In HPV-infected precancerous tissues and primary human keratinocytes, Mattoscio et al. have observed an accumulation of the autophagy receptor p62 in the cytosol of infected cells, suggesting an inhibition of autophagy in those cells (86). Similarly, in patients with oropharyngeal and oral cavity squamous cell carcinoma (SSC), HPV-positive tumors exhibit a lower level of LC3B as compared with HPV negative tumors, demonstrating that infection represses autophagy (87). Importantly, HPV-encoded E6 and E7 proteins inhibit autophagy maturation in anal tumor mice model, and this inhibition is associated with a greater susceptibility to HPV-induced anal carcinogenesis (88). Altogether, those studies strongly suggest that inhibition of autophagy during HPV infection actively participate in normal cells transformation.
HBV and HCV, the causative agents of hepatocellular carcinoma (HCC), have developed mechanisms to inhibit autophagy maturation, leading to the accumulation of autophagosomes inside infected cells and favoring the replication of viruses and the tumorigenesis (89–91). HBV-encoded oncogenic protein HBx prevents autophagosome maturation possibly by repressing the v-ATPase activity, and therefore by impairing the fusion of autophagosome with lysosome (92). This study highlights that HBx-mediated disruption of autophagic degradation may be critical for the development of HBV-associated HCC. Importantly, downregulation of autophagy in HBV-associated HCC patient specimens is inversely correlated with the expression of the microRNA-224 (miR-224), factor that promotes liver tumorigenesis. Moreover, the same study shows that miR-224 is preferentially recruited and degraded by autophagy, suggesting that HBx-mediated autophagy inhibition could promote HBV-associated tumorigenesis through the accumulation of miR-224 (93). While HBx protein has been shown to perturb the autophagic influx, another study observes an induction of HBx-mediated autophagy in HBV infected cells, which promotes the degradation of tumor necrosis factor receptor superfamily member 10B (TNFS10, called also TRAIL) and prevents the TNFS10-mediated antiviral immunity (94). Moreover, HBx-mediated autophagy has also been demonstrated to play an important role in NFκB-dependent production of pro-inflammatory cytokines, such as interleukin (IL)-6 or IL-8 that are two predictors of HCC progression in patients suffering from chronic hepatitis infection (95, 96). As previously described, HCV-encoded NS4B protein induces rubicon expression, leading to the inhibition of autophagosomes maturation (97, 98). Autophagy inhibition leads to an accumulation of the autophagy receptor p62 in HCV-associated HCC patients. Recent report also observed that an elevated expression of clusterin (CLU) in tumor tissues of HCV-HCC patients increases autophagy genes and upregulated p62 (99). Importantly, upregulation and phosphorylation of p62 activate the transcription factor Nrf2, involved in the metabolic reprogramming that promotes malignancy of HCV-positive HCC (100).
Viral cycles of KSHV and EBV, which belong to the herpesvirus family, are divided into two phases : a latency and a lytic phase (101, 102). Oncogenic properties of these viruses are linked with the latency phase, with a cell proliferation promoted and a cell survival increased. Interestingly, it has been shown that during this phase, autophagy is mainly inhibited. For KSHV infection, autophagy inhibition is led by both the viral FLICE-like proteins FLIP (vFLIP) through the repression of the conjugated system LC3 and LANA viral protein by preventing the downstream autophagy genes expression related to p53 (52, 103, 104). Autophagy is also inhibited during the lytic phase of KHSV infection. Expression of viral G-protein-coupled receptors (vGPCR) promotes the autophagy repressor pathway PI3K/AKT/mTOR as well as the degradation of the autophagic protein ATG14L, and viral bcl2 (vBcl2) represses Beclin-1 activation (105–107). Moreover, as previously mentioned, K7 protein of KSHV leads to the inhibition of autophagy maturation (108). The autophagy-associated protein p62 can also interfere with the lytic phase of KSHV, as an inhibition of exportin 1 (XPO1) induced retention of p62, which enhanced expression of innate immune-related genes (e.g., IRF7, ISG15, IFIT1, IFIT2, and IFIT3) that leads to a reduction of KSHV lytic replication (109). While further investigations are required to decipher the relation linking autophagy inhibition and oncogenesis in KSHV infected cells, one study showed that KSHV-mediated subversion of autophagy perturbs senescence and facilitates the proliferation of infected cells, two processes involved in cell tumorigenesis (110). Similarly, in EBV-infected cell, latency protein LMP-2 promotes mTOR pathway and inhibits autophagy (111). Recent study also demonstrates that EBV infection blocks the autophagic flux to favor its replication through the activation of two viral Bcl-2 homologue proteins, BHRF1 and BALF1 (112, 113). This impairment of complete autophagy leads to an accumulation of p62 in the nucleus of EBV-transformed lymphoblastic cell lines (LCLs) that promotes oxidative stress and limits the efficiency of DNA damage response, processes that could enhance virus-mediated oncogenesis (114). Recent investigation also suggested that autophagy induction, mediated by the upregulation of CXCR4 in EBV-associated gastric carcinoma (EBVaGC), protects tumor cells from apoptosis and promotes replication of EBV (115). Interestingly, publications converge to show that modulation of autophagy in EBV-infected tumor cells supports the replication of viruses and favors persistent latent infection, two processes that could facilitate tumorigenesis.
HTLV-1 also encodes an oncoprotein, called Tax-1, that modulates autophagy by acting both on autophagy initiation and maturation steps (116). In HTLV-1 transformed T or in Tax-immortalized CD4 memory T cells, Tax-1 facilitates autophagic initiation by activating IκB kinase complex, which subsequently recruits and activates the autophagy initiation complex Beclin-1/PI3KC3 (117). Tax-1 also blocks the fusion of autophagosomes with lysosomes, leading to an accumulation of autophagic vacuoles in the cytosol that promotes HTLV-1 production (118). It is interesting to note that another study has observed that HTLV-1-encoded basic leucine-zipper factor (HBZ) promotes the activity of mTOR pathway, which could be an additional autophagic suppressor mechanism in infected cells (119). These results indicate a critical role of HTLV-1-deregulated autophagy in promoting survival and transformation of T cells infected by the virus.
MCPyV, the causative agent of Merkel cell carcinoma (MCC), reduces autophagy level in infected cells dependently of the viral oncogenic large antigen (LT-ag) protein. LT-ag favors the expression of miR-30a-3p, miR-30a-5p, and miR-375, which target and repress the level of expression of key autophagy genes (Beclin-1, atg7, and p62) (120). In MCC tumor, low expression of ATG7 and p62 are correlated with MCPyV-positive tumor, suggesting the importance of autophagy evasion in MCPyV-associated tumorigenesis. Moreover, Torin-1 treatment (an mTORC1 inhibitor) induces cell death of MCC, which can be reduced by autophagy inhibitors, suggesting that MCPyV oncoproteins suppress autophagy to protect cancer cells from cell death (120).
Oncolytic Viruses Enhance Autophagy to Increase Tumor Cell Death and Immunogenicity
Oncolytic viruses (OVs) have recently emerged as a promising cancer therapeutic approach with great potential for the treatment of a broad spectrum of cancer, especially tumors that have acquired drug resistance to the first-line chemotherapeutics. OVs have been selected or designed to specifically target and kill cancer cells, with low replication capacity in normal tissues (121, 122). The mechanisms of tumor selectivity are multiple, including the expression of viral genome through the cancer-specific gene overexpression involved in the transcriptional element, the specific expression of virus receptor by the cancer cells, the overactivity of metabolic capacity in tumor cells (which is required for virus replication) but also tumor-specific defects of antiviral immunity [extensively reviewed elsewhere (123)]. Several interesting OVs are under investigation in preclinical and clinical studies, including coxsackievirus, adenoviruses (AdV), herpes simplex virus (HSV), Marada virus, Measles virus (MeV), Newcastle disease virus (NDV), vesicular stomatitis virus (VSV), parvovirus, and vaccinia virus (123). Direct lysis of tumor cells along with indirect induction of antitumoral immunity against specific tumor antigens are the two ways by which OVs limit tumor progression.
Oncolytic Viruses and Autophagy-Dependent Cell Death
Paradoxically, although autophagy is well recognized as a cell survival process that promotes tumor development, it can also participate in a caspase-independent form of programmed cell death. Due to the important role of autophagy in cell survival and the close relationship between autophagy and other types of cell death (e.g., apoptosis or necrosis), classification of autophagy as type of programmed cell death has been largely discussed and debated during the last decade [extensively reviewed elsewhere (124)]. However, it is now admitted that autophagy-dependent cell death (ADCD) is a type of cell death that requires autophagy and/or autophagy components and for which the inhibition of autophagy machinery and/or components, genetically or chemically, prevents cell death (125). ADCD has been firstly described to mediate physiological cell death in vivo, during the developmental program of D. melanogaster (126), but autophagy also appears to be involved in the death of many cancer cells in response to several therapies, especially in tumors with the lack of crucial apoptotic modulators (e.g., BAX and BAK or caspases) [extensively reviewed elsewhere (127)].
Oncolytic viruses destroy tumor cells by inducing different types of cell death. For example, parvovirus and NDV exert oncolytic activities by triggering apoptotic pathways in many cancers, while vaccinia virus leads to programmed necrotic cell death in ovarian and colon infected tumor cells (128–131). In addition, some oncolytic viruses are also able to induce tumor cell lysis through autophagy induction (Figure 3) (132).
Figure 3
A number of different conditionally replicating adenoviruses (CRAds) have been shown to induce autophagy in tumor cells (133). In nude mice subcutaneously transfected with glioma tumor cells, adenoviruses expressing the adenovirus early (E)1A gene (which leads to viral replication) under the control of the human telomerase reverse transcriptase promoter (hTERT-Ad) kill telomerase-positive tumor cells by inducing autophagic cell death, notably by inhibiting the mTORC1 activity in infected cells (134). A more recent study showed that OBP-31, an oncolytic adenovirus that is derived from hTERT-Ad, induces the autophagic cell death of human glioma tumor cells through an E2F1-mir7-EGRF pathway (135). Similarly, CRAds, which use the survivin promoter, enhance autophagy in glioma infected cells and favor the elimination of tumor cells via a beclin-1 dependent mechanism (136). Delta-24-RGD, an oncolytic adenovirus that selectively replicates in cancer cells with an abnormal Rb pathway, induces an autophagy-dependent cell death of brain tumor stem cells and improves the survival of glioma-bearing mice (137). In vitro experiments also showed that wild-type or E1-deficient adenoviruses induce autophagy in lung, cervical, and colon cancer cells and that autophagy induction correlates with an increase of viral replication and tumor cell death (138).
The oncolytic HSV-1 strain RH2, which lacks the γ34.5 gene, induces the cell death of squamous cell carcinoma (SSC). While no significant changes were observed using caspase inhibitors, the cytotoxicity of RH2 infection was inhibited when infected tumors cells were treated with autophagy inhibitors (3-methyladenine and bafilomycin), demonstrating that HSV-1/RH2 induces autophagic cell death in SCC cells (139). In gastric carcinoma, an excessive endoplasmic reticulum stress was observed in Newcastle disease virus (NVD)-infected cancer cells, triggering autophagy and cell death (140). Similarly, Meng et al. (2012) reported that infection of malignant U251 cells with NDV boosts the formation of autophagosomes, which facilitates the replication of the virus (141). Interestingly, pharmacological modulation of autophagy was investigated in order to enhance the oncolytic potential of NDV strain FMW (NDV/FMW) in drug-resistant lung tumor cells (A549 resistant to cisplatin or paclitaxel). Combination of NDV with chloroquine or rapamycin significantly promoted the oncolytic efficiency of NDV/FMW in lung cancer bearing mice (142). Edmonton strain of MeV (MeV-Edm) exploits selective autophagy to increase its replication in non-small-cell lung cancer (NSCLC) by targeting the degradation of mitochondria via autophagy (mitophagy), which results in a decrease of innate immune response by limiting the production of RIG-I like receptor (RLR)-dependent type-I interferon production (143). Another study showed that the persistent viral replication mediated by MeV-Edm-induced mitophagy prevents apoptosis but at the end leads to necrotic cell death (144), suggesting that MeV-induced autophagy could switch from apoptosis to a more immunogenic cell death in NSCLCs following the infection.
An attractive strategy among virus-based oncolytic system is to design viral vectors that express pro-autophagic genes, in which gene-virotherapy approach significantly enhances tumor cell death by activating autophagy, especially in tumors that have acquired resistance for apoptosis. Several studies have investigated the therapeutic effect of engineered recombinant OV expressing beclin-1 gene. For example, the oncolytic adenovirus expressing beclin-1 (SG511-BECN) infection induces a significant autophagic cell death in a variety of leukemic cell lines and primary leukemic blast (145). Interestingly, SG511-BECN induces cell death of both acute and chronic myeloid leukemia, but has less cytotoxicity in normal cells. In murine leukemia model, SG511-BECN prolongs mice survival and decreases the xenograft tumor size by inducing autophagic cell death (145). Recently, oncolytic vaccinia virus that expresses Beclin-1 (OVV-BECN) was also tested for its in vitro and in vivo oncolytic activity in blood cancer (146). OVV-BECN induces a significant autophagic cell death in both wild-type leukemia and multiple myeloma cells lines and has a greater antitumor activity compared with the wild-type vaccinia virus, demonstrating a favorable therapeutic effect of autophagy in vaccinia-based treatment of blood cancers.
Oncolytic Viruses and Autophagy-Mediated Immunogenic Cell Death
Besides their direct killing potential, oncolytic viruses require the activation of immune responses to be long-lasting effective against cancer. Most of the OVs, including HSV-1, MeV, adenoviruses, or NDV, have been described to induce an immunogenic cell death (ICD), which is critical for their virotherapy efficacy (147). ICD is a type of cell death that is sufficient to induce an adaptive immune response against exogenous or endogenous antigens expressed by dying cells and elicited by the presence of danger associated molecular patterns (DAMP). While pathways of ICD induction could be multiple, it is often related to endoplasmic reticulum (ER) stress and reactive oxygen species (ROS) production (148). The main hallmarks of ICD that have been described so far include ecto-expression of calreticulin (which is normally expressed in ER), ATP release, high-mobility group box (HMGB) 1 release in different redox states but also the activation of annexin 1, the secretion of type I IFN and IL-1β, or the exposure of F-actin and heat shock protein (HSP-70 and HSP90) (147). ICD leads to the activation of adaptive immune cells, including dendritic cells (DC) and T lymphocytes (LT). OVs are one of the most described ICD inducers, and infected tumor dying cells are often associated with the presence of danger signals (ATP and HMGB1 release or CRT exposure), the secretion of pro-inflammatory cytokines, as well as the release of tumor associated antigens (TAA), which lead to a strong activation of antitumor immune responses (149–153).
Pathways of ICD induction vary a lot between viruses, but mounting evidences indicate that autophagy plays a critical role in that induction. One of the first examples highlighting the importance of autophagy in ICD has been observed during embryonic development. During embryonic cavitation, embryonic bodies (EBs) derived from cells deficient for autophagy genes (atg5 or beclin-1) fail to cavitate. This defect is due to the persistence of cells corps during the embryonic development, which is the result of the absence of “eat-me” signal (exposure of phosphatidylserine) and the poor release of ATP in autophagy-deficient EBs (154). In tumor model, Michaud et al. reported that autophagy is required for the immunogenicity of chemotherapy-induced cell death, as autophagy-deficient dying cells fail to release ATP and subsequently to attract DC and LT into the tumor bed in colon carcinoma mice model (155). Similarly, it has been observed that radiotherapy of lung and colon cancer elicited an anticancer immune response that was dependent on autophagy-induced ATP release from dying cells, release that is required for a dense recruitment of lymphocytes into the tumor site (156). In epithelial and glioblastoma cancer cells, autophagy regulates the passive HMGB1 release from dying cells and active HMGB1 secretion (157, 158). Strikingly, the close correlation between autophagy induction and ICD properties observed during antitumor cytotoxic agents treatment in blood cancers supports the relationship between autophagy and ICD (158). In addition to favoring the exposition of DAMP from dying cells, autophagy can also promote antigen presentation from cancer cells to DCs and subsequently to T cells, a necessary step for the implementation of a robust antitumor immune response. Indeed, autophagy promotes the presentation of antigens not only by major histocompatibility complex (MHC) class II but also by MHC class I, as observed for endogenous viral antigens during HSV-1 infection or during influenza infection of tumor cells, and for cross-presentation of TAA from uninfected tumor cells (159, 160).
Oncolytic adenoviruses have been shown to induce an autophagy-dependent ICD, leading to the release of a great number of DAMP molecules and TAAs (137). In prostate cancer cells, the combination of Ad5/3 fiber-modified oncolytic adenovirus armed with granulocyte macrophage colony-stimulating factor (Ad5/3-D24-GMCSF) with low-dose of temozolomide (a chemotherapeutic agent) results in the increase of intracellular level of autophagy in tumor dying cells and favors immunogenic cell death, as indicated by elevated calreticulin exposure, ATP secretion, and HMGB1 release (161). A more recent report demonstrated that oncolytic adenovirus-induced autophagy is critical for the processing and the presentation of TAAs incorporated into viral capsid protein on MHC class II, suggesting that the combination of adenoviruses with autophagy inducers may enhance the antitumor immune responses (162). NDV infection also induces a strong ICD in lung and glioblastoma cancer cells, observable by the elevated exposure of calreticulin, the release of HMGB1, ATP, and HSP79/90, and the induction of a long-term tumor-specific immune response (163, 164). A recent study has shed light on the important role of autophagy in NDV-mediated ICD in lung cancer, as the depletion of autophagy-related genes, in contrast to inhibition of apoptosis or necrosis, significantly inhibits the induction of ICD determinants by NDV infection (165). In addition to increase the DAMP or TAAs expression by tumor dying cells, autophagy can also modify the tumor microenvironment. Using the herpes simplex virus type 2 (HSV-2)-based oncolytic virus ΔPK, one report has demonstrated that autophagy promotes the release of proinflammatory cytokines (TNFα, IL-1β; and GM-CSF) through the TLR2 activation, and that contributes to the inhibition of tumor immunosuppressive microenvironment in melanoma cells (166).
Other Correlations Between Viral Infection, Autophagy, and Tumor Progression
In addition to favoring the tumorigenesis and the immunogenic cell death, modulation of autophagy by viral infections could also influence other steps of tumor development, including tumor cell survival, proliferation, migration, and resistance to antitumor therapies, as well as immune response efficiency.
Tumor Cell Survival
When the tumor is established, the impact of autophagy on tumor growth and/or clinical features of patients remains unclear and seems to be greatly influenced by the type and/or the stage of the disease. However, several studies described that autophagy has pro-tumor effects, promoting the tumor cell survival, the proliferation, the migration, and the resistance to radio- and chemotherapies (Figure 2) (167). One of the most obvious involvement of autophagy in tumor growth is the fact that autophagy could recycle non-essential cytoplasmic elements to support tumor cell survival. Indeed, the more the tumor grows, the more the cells are moved away from the vascular system, leading cells under hypoxic and/or starvation condition (168). Both starvation and hypoxia have been demonstrated to induce a strong autophagy response in tumor cells, and this autophagy acts as recycling mechanism to promote stress tolerance and to supply metabolic precursors for the tumor cell survival (169, 169). Interestingly, some common oncogenic gene mutations (e.g., ras) have been shown to increase autophagy in order to maintain tumor cell survival (170).
Autophagy could also limit the induction of programmed cell death, including apoptosis, by the selective removal of damaged organelles (e.g., damaged mitochondria) or by the selective elimination of the pro-apoptotic signal transduction [extensively reviewed elsewhere (171)]. Interestingly, several viruses have been observed to promote survival of infected cells by repressing apoptosis through an autophagy-dependent mechanism (Figure 4) (172–179). In human and mouse neuroblastoma cells, wild-type rabies virus limits apoptosis in infected cells by inducing a complete autophagic influx (179). The overexpression of HBV protein HBx and HCV protein NS5A can both reduce the starvation-induced cell death through the activation of autophagy and the inhibition of mitochondrial apoptosis, leading to the tumor cell survival of respectively advanced HCC and hepatoblastoma cells (174, 175). Similarly, the Tax protein of human T-cell leukemia virus type 1 (HTLV-1) favors the resistance of astroglioma infected cells for FASL-mediated and TRAIL-mediated apoptosis by increasing autophagy (176). In lung tumor, NDV-induced autophagy promotes viral replication and tumor cell survival by preventing cancer cells from caspases-dependent apoptosis, recruiting p62-mediated autophagy to control cytochrome c release from mitochondria (180).
Figure 4
Contribution of autophagy in tumor survival has also been illustrated by the fact that autophagy could prevent lysis of tumor cells from antitumor cytotoxic immune cells. For instance, autophagy has been reported to play an important role in hypoxia-induced resistance of lung tumor cells to cytolytic T lymphocyte-mediated lysis (181). Indeed, inhibition of Atg5 or Beclin-1 reduce the phosphorylation of STAT3, an important transcription factor involved in tumor survival and resistance to T cell cytotoxicity. Similarly, Viry et al. revealed that hypoxia-induced autophagy is responsible for the degradation of granzyme B in tumor cells delivered by NK cells, leading to their resistance to NK-mediated cell death (182). Interestingly, similar STAT3 modulation has been reported in infected cells (183). Given the fact that these proteins are also responsible for autophagy-mediated resistance to starvation in tumor, it will be very interesting to investigate the impact of virus-induced autophagy on the resistance to antitumor immunity.
Metastasis Formation
Autophagy has also been associated with metastasis formation. Actually, the role of autophagy in metastasis occurrence is controversial (184). In one hand, autophagy has been shown to limit metastasis of some tumor cells. For instance, autophagy decreases the glioblastoma tumor cells migration and invasion, reversing the epithelial-mesenchymal transition (EMT) (185). Similarly, autophagy has been associated with the selective degradation of MET/HGF receptor tyrosine kinase, two kinases involved in cell invasion, therefore inhibiting cancer cell lines mobility (186). In the other hand, autophagy has been described to be essential for the resistance to cell-detachment-induced apoptosis, called anoikis (187). For example, the group of Jian Fan demonstrated that the inhibition of autophagy suppresses pulmonary metastasis of hepatocellular carcinoma in mice through impairing anoikis resistance (188). Emerging evidence show that autophagy not only enhances the survival of disseminating tumor cells but also promotes the survival and the maintenance of a stem-like subpopulation of tumor cells that drives invasion, treatment resistance, and cancer recurrence (189). In addition, several autophagy substrates have been shown to be involved in the regulation of the epithelial-mesenchymal transition (EMT), tumor cell migration, and invasion [extensively reviewed elsewhere (190)].
Viral infections and virus-related molecules are also known to promote metastasis formation. EBV has been shown to encode several mature miRNAs, where some of them have been demonstrated to promote tumor development by targeting virus-infected host genes or self-viral genes. Several studies demonstrated that these miRNA could promote EMT, migration and metastasis of the nasopharyngeal carcinoma (NPC) cells (191–195). HPV16 E6 protein expression has been shown to increase actin polymerization through the degradation of Na+/H+ exchanger regulatory factor 1 (NHERF1) protein, facilitating the migration of the cervical cancer cell and the development of metastasis (196). Viral proteins E7 of HPV16 and E1 of HCV have been shown to inactivate the tumor metastasis repressor Nm23-H1 in human keratinocyte HaCaT cell line and HCC cells line, respectively, increasing metastasis formation (197, 198). HSV2, HBV, or HCMV related-proteins or miRNA have also been demonstrated to promote metastasis development (199–201). Interestingly, HCMV-mediated promigratory signal requires the activation of Ras homolog family member A (RhoA), a protein involved in cell migration that can be modulated by autophagy (202). A recent report showed that under HBV infection, HBx-induced autophagy promotes the expression of long non-coding RNA activated by transforming growth factor (TGF)−β (lncRNA−ATB) and TGF−β, two key actors for the migration and invasion capabilities of liver cells (203).
While the role of autophagy in virus-induced metastasis needs to be further analyzed to understand the actual function of this mechanism in tumor development, it is interesting to notice the increasing number of evidences that report a strong correlation between viruses capable to modulate autophagy and their capacity to increase tumor cell migration and metastasis development.
Resistance to Antitumor Therapies
Another aspect by which autophagy favors the tumor development concern its impact on the resistance to antitumor treatments. In various tumor models (e.g., ovarian, colon, or osteosarcoma tumors), autophagy has been demonstrated to be an important actor of chemoresistance, leading to an increase of the survival of tumor cells under treatment of salt-based chemotherapies (204–208). Autophagy has also been observed to be an important promoter of resistance to radiotherapy in various tumor models, including lung, glioma, pancreatic, and colorectal cancer (209–212). Interestingly, in order to overcome this resistance, several therapeutic approaches consisting in combining chemotherapy and radiotherapy with autophagy inhibitors have emerged with very promising results (213, 214).
Viruses or viral proteins have also been linked with the resistance to different antitumor therapies (215–220). While mechanisms involved in viruses-mediated resistance to therapies differ with the type of viral infection, the main strategy consists in inhibiting apoptotic cell death in infected tumor cells. EBV miR BART20-5p has been observed to favor chemoresistance to 5-FU and docetaxel in gastric cancer by targeting the pro-apoptotic BCL2-associated agonist of cell death (BAD) expression (221). EBV, though the viral LMP1 protein, has been demonstrated to decrease the expression of the two pro-apoptotic factors PDCD4 and FasL, leading to a chemoresistance to cisplatin in nasopharyngeal carcinoma cells (222). EBV has also been shown to induce chemoresistance to 5-FU in gastric cancer cells by decreasing the cleavage of PARP and caspase 3 and increasing the anti-apoptotic Bcl2 expression (223). In nasopharyngeal carcinoma, EBV-encoded miR-BART4 and miR-BART8-3p favor resistance to radiotherapy by inhibiting apoptosis (224, 225). EBV latent viral protein LMP1 has also been demonstrated to induce radioresistance by preventing DNA Damage Response (DDR) through the phosphorylation of AMPK (thr172) and inhibiting therefore its interaction with DNA-dependent protein kinase (DNA-PK), required for the DDR (226). While autophagy has not been investigated in this study, it is interesting to note that AMPK activity is an important regulator of autophagy, and AMPK-induced autophagy could help to the EBV induced radioresistance. Similarly, a recent study demonstrated that LMP1 induces autophagy via the binding of BCL2/adenovirus E1B 19 kDa protein-interacting protein 3 (BNIP3) to beclin-1 (227). This autophagy stimulation has been shown to enhance the resistance of LMP1-positive nasopharyngeal carcinoma (NPC) cells against irradiation by protecting tumor cells from apoptosis. M. Antonioli et al. also demonstrated that HPV infection in oropharyngeal squamous cell carcinoma sensitize tumor cells to cisplatin-induced apoptosis by inhibiting autophagy, supporting the idea that modulation of autophagy during acute or latent infections could impact the resistance of tumor cells to antitumor therapies (228).
Antitumor Immune Responses
Type I interferon (IFN-I) is an important class of pro-inflammatory cytokines produced in response to viral infection and other environmental stresses. While IFN-I is very important for efficient virus clearance, emerging studies have shown that these proteins are also a very important driver for antitumor immunity, promoting the efficiency of immune cells to eliminate tumor [extensively reviewed elsewhere (229)]. Many intracellular pathways can recognize viral components and lead to the production of IFN-I, including the stimulation of RIG-I like receptor (RLR) and mitochondria antiviral signaling protein (MAVS), present in the outer membrane of mitochondria. Autophagy, notably through the targeting of mitochondria (mitophagy), is able to regulate RLR-mediated IFN-I production (230). Several viruses induce mitophagy to impair the type-I interferon production, including the SARS-Coronavirus, the IAV and parainfluenza virus or MeV (Figure 5) (231–234). Damaged mitochondria can also release danger signals, including the reactive oxygen species (ROS) and mitochondrial DNA, which in return can activate inflammasome and the release of pro-inflammatory cytokines that could perturb tumor immunity (235, 236). Interestingly, some viruses, including IAV and MeV, have been also shown to induce mitophagy to prevent NLRP3-mediated inflammation (237, 238). Autophagy could also prevent virus-induced IFN-I production by other mechanisms. Induction of autophagy by HPV16 E7 protein is responsible for the autophagic degradation of STING protein, which impairs IFN-I production and induces important deregulation of tumor immunity and promotion of Head and Neck Squamous cell carcinoma (239). Similarly, Bluetongue virus (BTV), an orbovirus targeting ruminants, impairs IFN-I pathway by preventing STAT1 phosphorylation and by degrading STAT2 through autophagy (240). Inhibition of autophagy maturation in HCV-infected hepatocytes, through the expression of Rubicon, was recently associated with an increase of expression of type I IFN-related genes and an upregulation of HCV replication (241). Other pro-inflammatory cytokines, important for tumor immunity, could also be regulated by virus-induced autophagy. As a good example, MCMV M45 protein induces the autophagic degradation of two cellular signaling proteins involved in nuclear factor κ-light-chain-enhancer of activated B cells (NF-κB)-mediated cytokine production, the NF-κB essential modulator (NEMO), and the receptor-interacting protein kinase 1 (RIPK1) (242, 243).
Figure 5
In addition to limit pro-inflammatory cytokine production, viruses have elaborated strategies to escape from the cytotoxic immune cells. To avoid the recognition and elimination of infected cells by cytotoxic lymphocytes, many viruses decrease the major histocompatibility (MHC) class I antigen presentation pathway [extensively reviewed elsewhere (244)]. Similar strategy has also been observed in many cancer cells. The decrease of MHC-I expression has also been observed in dendritic cell (DC) infected with HIV, MCMV, or varicella zoster virus, and it has been associated with a reduction of their capacity to stimulate T cell proliferation (245). Interestingly, autophagy has been associated to a decrease of MHC-I expression on DC by facilitating the endocytosis and the degradation of MHC-I (246). A recent study demonstrated that autophagy regulates the expression of MHC-I in pancreatic tumor cells, as the inhibition of the autophagy machinery increased MHC-I expression on tumor cells, enhanced antitumor T cell response, and reduced tumor growth in mice model (247).
Conclusion
Since several years, investigations on autophagy process shed light many biological pathways to an autophagy-dependent modulation. To understand the role of autophagy in host cells, it is important to consider the physiologic context, as autophagy could have distinct functions according to the biological model and/or the stage of the disease. During the initial step of tumor development, cells accumulate damages that disturb key molecules involved in cell cycle and promote tumorigenesis. Both tumor suppressor genes and oncogenes are implicated in autophagy regulation, linking autophagy directly to cancer occurrence. Recent discoveries showed that oncogenic viruses, which lead to the transformation of precancerous cells to malignant tumor, inhibit autophagy by targeting specifically autophagy molecules. Inhibiting autophagy in infected cells favors the accumulation of damaged organelles and/or proteins in host cells and therefore promotes the accumulation of stress components and genetic mutations.
In another hand, autophagy induced in more advanced tumor is more prone to help tumor growth. As a cellular degradative process, autophagy helps proliferative tumor cells for their nutrient supply and has an important prosurvival function, favoring tumor cell resistance to several therapies. Autophagy may also promote metastasis by protecting detached and stressed tumor cells as they travel through blood vessels and establish new colonies at distant sites. Importantly, many viruses capable to modulate autophagy have similar impact on tumor behavior, and while the direct link between autophagy and tumor development has not been well established in all studies, strong evidences have suggested an important connection between autophagy and virus-mediated tumor modifications. However, further investigations are needed to clarify autophagy’s modulation by viral infections and tumor development. Considering the role of autophagy in aberrant cell physiology, the understanding of these molecular processes is crucial for the development of new therapeutics against cancers and potentially other proliferative diseases.
Funding
This work was supported by the “Institut National de la Sante et de la Recherche Medicale” (INSERM), Sorbonne Université and Université de Paris.
Publisher’s Note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
Statements
Author contributions
LL and P-EJ performed similar bibliography. LL and P-EJ equally contributed to write the manuscript. P-EJ performed figures and supervised this work. IC, SS and MA helps authors during the conception and correction of the manuscript. All authors contributed to the article and approved the submitted version.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
1
TekirdagKCuervoAM. Chaperone-Mediated Autophagy and Endosomal Microautophagy: Joint by a Chaperone. J Biol Chem (2018) 293:5414–24. doi: 10.1074/jbc.R117.818237
2
LevineBKroemerG. Biological Functions of Autophagy Genes: A Disease Perspective. Cell (2019) 176:11–42. doi: 10.1016/j.cell.2018.09.048
3
MaoJLinEHeLYuJTanPZhouY. Autophagy and Viral Infection. Autophagy Regul Innate Immun (2019) 1209:55–78. doi: 10.1007/978-981-15-0606-2_5
4
ChoiYBowmanJJungJ. Autophagy During Viral Infection — A Double-Edged Sword. Nat Rev Microbiol (2018) 16(6):341–54. doi: 10.1038/s41579-018-0003-6
5
JoubertP-EAlbertML. Autophagy During Viral Infections: A Double-Edge Sword. Virologie (2013) 17:331–42. doi: 10.1684/vir.2013.0533
6
KudchodkarSBLevineB. Viruses and Autophagy. Rev Med Virol (2009) 19:359–78. doi: 10.1002/rmv.630
7
JoubertP-EMeiffrenGGrégoireIPPontiniGRichettaCFlacherMet al. Autophagy Induction by the Pathogen Receptor CD46. Cell Host Amp Microbe (2009) 6:354–66. doi: 10.1016/j.chom.2009.09.006
8
JoubertP-EWernekeSde la CalleCGuivel-BenhassineFGiodiniAPedutoLet al. Chikungunya-Induced Cell Death Is Limited by ER and Oxidative Stress-Induced Autophagy. Autophagy (2012) 8:1261–3. doi: 10.4161/auto.20751
9
MeiffrenGJoubertP-EGrégoireIPCodognoPRabourdin-CombeCFaureM. Pathogen Recognition by the Cell Surface Receptor CD46 Induces Autophagy. Autophagy (2010) 6:299–300. doi: 10.4161/auto.6.2.11132
10
GrégoireIPRabourdin-CombeCFaureM. Autophagy and RNA Virus Interactomes Reveal IRGM as a Common Target. Autophagy (2012) 8:1136–7. doi: 10.4161/auto.20339
11
RozièresAViretCFaureM. Autophagy in Measles Virus Infection. Viruses (2017) 9(12):359. doi: 10.3390/v9120359
12
DenizotMVarbanovMEspertLRobert-HebmannVSagnierSGarciaEet al. HIV-1 Gp41 Fusogenic Function Triggers Autophagy in Uninfected Cells. Autophagy (2008) 4:998–1008. doi: 10.4161/auto.6880
13
LeeMSKimY-J. Signaling Pathways Downstream of Pattern-Recognition Receptors and Their Cross Talk. Annu Rev Biochem (2007) 76:447–80. doi: 10.1146/annurev.biochem.76.060605.122847
14
DelgadoMAElmaouedRADavisASKyeiGDereticV. Toll-Like Receptors Control Autophagy. EMBO J (2008) 27:1110–21. doi: 10.1038/emboj.2008.31
15
LeeHKLundJMRamanathanBMizushimaNIwasakiA. Autophagy-Dependent Viral Recognition by Plasmacytoid Dendritic Cells. Science (2007) 315:1398–401. doi: 10.1126/science.1136880
16
LeeN-RBanJLeeN-JYiC-MChoiJ-YKimHet al. Activation of RIG-I-Mediated Antiviral Signaling Triggers Autophagy Through the MAVS-TRAF6-Beclin-1 Signaling Axis. Front Immunol (2018) 9:2096. doi: 10.3389/fimmu.2018.02096
17
TallóczyZJiangWVirginHWLeibDAScheunerDKaufmanRJet al. Regulation of Starvation- and Virus-Induced Autophagy by the Eif2α Kinase Signaling Pathway. Proc Natl Acad Sci USA (2002) 99:190–5. doi: 10.1073/pnas.012485299
18
KonnoHKonnoKBarberGN. Cyclic Dinucleotides Trigger ULK1 (ATG1) Phosphorylation of STING to Prevent Sustained Innate Immune Signaling. Cell (2013) 155:688–98. doi: 10.1016/j.cell.2013.09.049
19
LiangQSeoGJChoiYJKwakM-JGeJRodgersMAet al. Crosstalk Between the Cgas DNA Sensor and Beclin-1 Autophagy Protein Shapes Innate Antimicrobial Immune Responses. Cell Host Microbe (2014) 15:228–38. doi: 10.1016/j.chom.2014.01.009
20
JoubertP-EWernekeSWde la CalleCGuivel-BenhassineFGiodiniAPedutoLet al. Chikungunya Virus-Induced Autophagy Delays Caspase-Dependent Cell Death. J Exp Med (2012) 209:1029–47. doi: 10.1084/jem.20110996
21
DashSChavaSAydinYChandraPKFerrarisPChenWet al. Hepatitis C Virus Infection Induces Autophagy as a Prosurvival Mechanism to Alleviate Hepatic ER-Stress Response. Viruses (2016) 8(5):150. doi: 10.3390/v8050150
22
OrvedahlAMacPhersonSSumpterRTallóczyZZouZLevineB. Autophagy Protects Against Sindbis Virus Infection of the Central Nervous System. Cell Host Microbe (2010) 7:115–27. doi: 10.1016/j.chom.2010.01.007
23
OrvedahlASumpterRXiaoGNgAZouZTangYet al. Image-Based Genome-Wide Sirna Screen Identifies Selective Autophagy Factors. Nature (2011) 480:113–7. doi: 10.1038/nature10546
24
SumpterRSirasanagandlaSFernándezÁFWeiYDongXFrancoLet al. Fanconi Anemia Proteins Function in Mitophagy and Immunity. Cell (2016) 165:867–81. doi: 10.1016/j.cell.2016.04.006
25
StaringJvon CastelmurEBlomenVAvan den HengelLGBrockmannMBaggenJet al. PLA2G16 Represents a Switch Between Entry and Clearance of Picornaviridae. Nature (2017) 541:412–6. doi: 10.1038/nature21032
26
KimNKimM-JSungPSBaeYCShinE-CYooJ-Y. Interferon-Inducible Protein SCOTIN Interferes With HCV Replication Through the Autolysosomal Degradation of NS5A. Nat Commun (2016) 7:10631. doi: 10.1038/ncomms10631
27
ValeraM-Sde Armas-RilloLBarroso-GonzálezJZiglioSBatisseJDuboisNet al. The HDAC6/APOBEC3G Complex Regulates HIV-1 Infectiveness by Inducing Vif Autophagic Degradation. Retrovirology (2015) 12:53. doi: 10.1186/s12977-015-0181-5
28
RibeiroCMSSarrami-ForooshaniRSetiawanLCZijlstra-WillemsEMvan HammeJLTigchelaarWet al. Receptor Usage Dictates HIV-1 Restriction by Human TRIM5α in Dendritic Cell Subsets. Nature (2016) 540:448–52. doi: 10.1038/nature20567
29
SagnierSDaussyCFBorelSRobert-HebmannVFaureMBlanchetFPet al. Autophagy Restricts HIV-1 Infection by Selectively Degrading Tat in CD4+ T Lymphocytes. J Virol (2015) 89:615–25. doi: 10.1128/JVI.02174-14
30
HwangSMaloneyNSBruinsmaMWGoelGDuanEZhangLet al. Nondegradative Role of Atg5-Atg12/Atg16L1 Autophagy Protein Complex in Antiviral Activity of Interferon Gamma. Cell Host Microbe (2012) 11:397–409. doi: 10.1016/j.chom.2012.03.002
31
PaludanCSchmidDLandthalerMVockerodtMKubeDTuschlTet al. Endogenous MHC Class II Processing of a Viral Nuclear Antigen After Autophagy. Science (2005) 307:593–6. doi: 10.1126/science.1104904
32
ChaumorcelMLussignolMMounaLCavignacYFahieKCotte-LaffitteJet al. The Human Cytomegalovirus Protein TRS1 Inhibits Autophagy via Its Interaction With Beclin 1. J Virol (2012) 86:2571–84. doi: 10.1128/JVI.05746-11
33
CuconatiAWhiteE. Viral Homologs of BCL-2: Role of Apoptosis in the Regulation of Virus Infection. Genes Dev (2002) 16:2465–78. doi: 10.1101/gad.1012702
34
MounaLHernandezEBonteDBrostRAmazitLDelguiLRet al. Analysis of the Role of Autophagy Inhibition by Two Complementary Human Cytomegalovirus BECN1/Beclin 1-Binding Proteins. Autophagy (2016) 12:327–42. doi: 10.1080/15548627.2015.1125071
35
OrvedahlAAlexanderDTallóczyZSunQWeiYZhangWet al. HSV-1 ICP34.5 Confers Neurovirulence by Targeting the Beclin 1 Autophagy Protein. Cell Host Microbe (2007) 1:23–35. doi: 10.1016/j.chom.2006.12.001
36
BhattAPDamaniaB. Aktivation of PI3K/AKT/Mtor Signaling Pathway by KSHV. Front Immunol (2013) 3:401. doi: 10.3389/fimmu.2012.00401
37
KanaiRZaupaCSgubinDAntoszczykSJMartuzaRLWakimotoHet al. Effect of γ34.5 Deletions on Oncolytic Herpes Simplex Virus Activity in Brain Tumors. J Virol (2012) 86:4420–31. doi: 10.1128/JVI.00017-12
38
LiangQChangBBruloisKFCastroKMinC-KRodgersMAet al. Kaposi’s Sarcoma-Associated Herpesvirus K7 Modulates Rubicon-Mediated Inhibition of Autophagosome Maturation. J Virol (2013) 87:12499–503. doi: 10.1128/JVI.01898-13
39
JacksonWTGiddingsTHJrTaylorMPMulinyaweSRabinovitchMKopitoRRet al. Subversion of Cellular Autophagosomal Machinery by RNA Viruses. PloS Biol (2005) 3:e156. doi: 10.1371/journal.pbio.0030156
40
BerrymanSBrooksEBurmanAHawesPRobertsRNethertonCet al. Foot-and-Mouth Disease Virus Induces Autophagosomes During Cell Entry via a Class III Phosphatidylinositol 3-Kinase-Independent Pathway. J Virol (2012) 86:12940–53. doi: 10.1128/JVI.00846-12
41
RobinsonSMTsuengGSinJMangaleVRahawiSMcIntyreLLet al. Coxsackievirus B Exits the Host Cell in Shed Microvesicles Displaying Autophagosomal Markers. PloS Pathog (2014) 10:e1004045. doi: 10.1371/journal.ppat.1004045
42
GuévinCMannaDBélangerCKonanKVMakPLabontéP. Autophagy Protein ATG5 Interacts Transiently With the Hepatitis C Virus RNA Polymerase (NS5B) Early During Infection. Virology (2010) 405:1–7. doi: 10.1016/j.virol.2010.05.032
43
WangLTianYOuJJ. HCV Induces the Expression of Rubicon and UVRAG to Temporally Regulate the Maturation of Autophagosomes and Viral Replication. PloS Pathog (2015) 11:e1004764. doi: 10.1371/journal.ppat.1004764
44
DingBZhangGYangXZhangSChenLYanQet al. Phosphoprotein of Human Parainfluenza Virus Type 3 Blocks Autophagosome-Lysosome Fusion to Increase Virus Production. Cell Host Microbe (2014) 15:564–77. doi: 10.1016/j.chom.2014.04.004
45
ZhouZJiangXLiuDFanZHuXYanJet al. Autophagy Is Involved in Influenza a Virus Replication. Autophagy (2009) 5:321–8. doi: 10.4161/auto.5.3.7406
46
PlummerMde MartelCVignatJFerlayJBrayFFranceschiS. Global Burden of Cancers Attributable to Infections in 2012: A Synthetic Analysis. Lancet Glob Health (2016) 4:e609–16. doi: 10.1016/S2214-109X(16)30143-7
47
MesriEAFeitelsonMAMungerK. Human Viral Oncogenesis: A Cancer Hallmarks Analysis. Cell Host Microbe (2014) 15:266–82. doi: 10.1016/j.chom.2014.02.011
48
MatsudaYIchidaT. Impact of Hepatitis B Virus X Protein on the DNA Damage Response During Hepatocarcinogenesis. Med Mol Morphol (2009) 42:138–42. doi: 10.1007/s00795-009-0457-8
49
MoodyCALaiminsLA. Human Papillomavirus Oncoproteins: Pathways to Transformation. Nat Rev Cancer (2010) 10:550–60. doi: 10.1038/nrc2886
50
ZaneLYasunagaJMitagamiYYedavalliVTangS-WChenC-Yet al. Wip1 and P53 Contribute to HTLV-1 Tax-Induced Tumorigenesis. Retrovirology (2012) 9:114. doi: 10.1186/1742-4690-9-114
51
RadkovSAKellamPBoshoffC. The Latent Nuclear Antigen of Kaposi Sarcoma-Associated Herpesvirus Targets the Retinoblastoma-E2F Pathway and With the Oncogene Hras Transforms Primary Rat Cells. Nat Med (2000) 6:1121–7. doi: 10.1038/80459
52
FriborgJKongWHottigerMONabelGJ. P53 Inhibition by the LANA Protein of KSHV Protects Against Cell Death. Nature (1999) 402:889–94. doi: 10.1038/47266
53
BorchertSCzech-SioliMNeumannFSchmidtCWimmerPDobnerTet al. High-Affinity Rb Binding, P53 Inhibition, Subcellular Localization, and Transformation by Wild-Type or Tumor-Derived Shortened Merkel Cell Polyomavirus Large T Antigens. J Virol (2014) 88:3144–60. doi: 10.1128/JVI.02916-13
54
ChoiBHChoiMJeonHYRhoHM. Hepatitis B Viral X Protein Overcomes Inhibition of E2F1 Activity by Prb on the Human Rb Gene Promoter. DNA Cell Biol (2001) 20:75–80. doi: 10.1089/104454901750070274
55
HesbacherSPfitzerLWiedorferKAngermeyerSBorstAHaferkampSet al. RB1 Is the Crucial Target of the Merkel Cell Polyomavirus Large T Antigen in Merkel Cell Carcinoma Cells. Oncotarget (2016) 7:32956–68. doi: 10.18632/oncotarget.8793
56
HusainiRAhmadMSoo-Beng KhooA. Epstein-Barr Virus Latent Membrane Protein LMP1 Reduces P53 Protein Levels Independent of the PI3K-Akt Pathway. BMC Res Notes (2011) 4:551. doi: 10.1186/1756-0500-4-551
57
BernardXRobinsonPNominéYMassonMCharbonnierSRamirez-RamosJRet al. Proteasomal Degradation of P53 by Human Papillomavirus E6 Oncoprotein Relies on the Structural Integrity of P53 Core Domain. PloS One (2011) 6:e25981. doi: 10.1371/journal.pone.0025981
58
ParrochePToukaMMansourMBouvardVThépotAAccardiRet al. Human Papillomavirus Type 16 E6 Inhibits P21waf1 Transcription Independently of P53 by Inactivating p150Sal2. Virology (2011) 417:443–8. doi: 10.1016/j.virol.2011.05.016
59
ShinM-KBalsitisSBrakeTLambertPF. Human Papillomavirus E7 Oncoprotein Overrides the Tumor Suppressor Activity of p21Cip1 in Cervical Carcinogenesis. Cancer Res (2009) 69:5656–63. doi: 10.1158/0008-5472.CAN-08-3711
60
YanXShahWJingLChenHWangY. High-Risk Human Papillomavirus Type 18 E7 Caused P27 Elevation and Cytoplasmic Localization. Cancer Biol Ther (2010) 9:728–35. doi: 10.4161/cbt.9.9.11442
61
HuZZhuDWangWLiWJiaWZengXet al. Genome-Wide Profiling of HPV Integration in Cervical Cancer Identifies Clustered Genomic Hot Spots and a Potential Microhomology-Mediated Integration Mechanism. Nat Genet (2015) 47:158–63. doi: 10.1038/ng.3178
62
MutzPMetzPLemppFABenderSQuBSchöneweisKet al. HBV Bypasses the Innate Immune Response and Does Not Protect HCV From Antiviral Activity of Interferon. Gastroenterology (2018) 154:1791–1804.e22. doi: 10.1053/j.gastro.2018.01.044
63
GaraigortaUChisariFV. Hepatitis C Virus Blocks Interferon Effector Function by Inducing Protein Kinase R Phosphorylation. Cell Host Microbe (2009) 6:513–22. doi: 10.1016/j.chom.2009.11.004
64
KangWSungPSParkS-HYoonSChangD-YKimSet al. Hepatitis C Virus Attenuates Interferon-Induced Major Histocompatibility Complex Class I Expression and Decreases CD8+ T Cell Effector Functions. Gastroenterology (2014) 146:1351–60. doi: 10.1053/j.gastro.2014.01.054
65
ChenYChengMTianZ. Hepatitis B Virus Down-Regulates Expressions of MHC Class I Molecules on Hepatoplastoma Cell Line. Cell Mol Immunol (2006) 3:373–8.
66
ParkJSKimEJKwonHJHwangESNamkoongSEUmSJ. Inactivation of Interferon Regulatory Factor-1 Tumor Suppressor Protein by HPV E7 Oncoprotein. Implication for the E7-Mediated Immune Evasion Mechanism in Cervical Carcinogenesis. J Biol Chem (2000) 275:6764–9. doi: 10.1074/jbc.275.10.6764
67
AshrafiGHHaghshenasMRMarchettiBO’BrienPMCampoMS. E5 Protein of Human Papillomavirus Type 16 Selectively Downregulates Surface HLA Class I. Int J Cancer (2005) 113:276–83. doi: 10.1002/ijc.20558
68
PaulsonKGTegederAWillmesCIyerJGAfanasievOKSchramaDet al. Downregulation of MHC-I Expression Is Prevalent But Reversible in Merkel Cell Carcinoma. Cancer Immunol Res (2014) 2:1071–9. doi: 10.1158/2326-6066.CIR-14-0005
69
GriffithsDAAbdul-SadaHKnightLMJacksonBRRichardsKPrescottELet al. Merkel Cell Polyomavirus Small T Antigen Targets the NEMO Adaptor Protein to Disrupt Inflammatory Signaling. J Virol (2013) 87:13853–67. doi: 10.1128/JVI.02159-13
70
ZhangTLinR-TLiYDouglasSDMaxceyCHoCet al. Hepatitis C Virus Inhibits Intracellular Interferon Alpha Expression in Human Hepatic Cell Lines. Hepatol Baltim Md (2005) 42:819–27. doi: 10.1002/hep.20854
71
SathishNYuanY. Evasion and Subversion of Interferon-Mediated Antiviral Immunity by Kaposi’s Sarcoma-Associated Herpesvirus: An Overview. J Virol (2011) 85:10934–44. doi: 10.1128/JVI.00687-11
72
TomescuCLawWKKedesDH. Surface Downregulation of Major Histocompatibility Complex Class I, PE-CAM, and ICAM-1 Following De Novo Infection of Endothelial Cells With Kaposi’s Sarcoma-Associated Herpesvirus. J Virol (2003) 77:9669–84. doi: 10.1128/jvi.77.17.9669-9684.2003
73
GeigerTRMartinJM. The Epstein-Barr Virus-Encoded LMP-1 Oncoprotein Negatively Affects Tyk2 Phosphorylation and Interferon Signaling in Human B Cells. J Virol (2006) 80:11638–50. doi: 10.1128/JVI.01570-06
74
RessingMEHorstDGriffinBDTellamJZuoJKhannaRet al. Epstein-Barr Virus Evasion of CD8(+) and CD4(+) T Cell Immunity via Concerted Actions of Multiple Gene Products. Semin Cancer Biol (2008) 18:397–408. doi: 10.1016/j.semcancer.2008.10.008
75
ChretienA-SLe RoyAVeyNPrebetTBlaiseDFauriatCet al. Cancer-Induced Alterations of NK-Mediated Target Recognition: Current and Investigational Pharmacological Strategies Aiming at Restoring NK-Mediated Anti-Tumor Activity. Front Immunol (2014) 5:122. doi: 10.3389/fimmu.2014.00122
76
KimMSJeongEGAhnCHKimSSLeeSHYooNJ. Frameshift Mutation of UVRAG, an Autophagy-Related Gene, in Gastric Carcinomas With Microsatellite Instability. Hum Pathol (2008) 39:1059–63. doi: 10.1016/j.humpath.2007.11.013
77
HeSZhaoZYangYO’ConnellDZhangXOhSet al. Truncating Mutation in the Autophagy Gene UVRAG Confers Oncogenic Properties and Chemosensitivity in Colorectal Cancers. Nat Commun (2015) 6:7839. doi: 10.1038/ncomms8839
78
KnævelsrudHAhlquistTMerokMANesbakkenAStenmarkHLotheRAet al. UVRAG Mutations Associated With Microsatellite Unstable Colon Cancer do Not Affect Autophagy. Autophagy (2010) 6:863–70. doi: 10.4161/auto.6.7.13033
79
LiangCFengPKuBOhB-HJungJU. UVRAG: A New Player in Autophagy and Tumor Cell Growth. Autophagy (2007) 3:69–71. doi: 10.4161/auto.3437
80
TakamuraAKomatsuMHaraTSakamotoAKishiCWaguriSet al. Autophagy-Deficient Mice Develop Multiple Liver Tumors. Genes Dev (2011) 25:795–800. doi: 10.1101/gad.2016211
81
GalluzziLPietrocolaFBravo-San PedroJMAmaravadiRKBaehreckeEHCecconiFet al. Autophagy in Malignant Transformation and Cancer Progression. EMBO J (2015) 34:856–80. doi: 10.15252/embj.201490784
82
SuaresAMedinaMVCosoO. Autophagy in Viral Development and Progression of Cancer. Front Oncol (2021) 11:603224. doi: 10.3389/fonc.2021.603224
83
VescovoTPagniBPiacentiniMFimiaGMAntonioliM. Regulation of Autophagy in Cells Infected With Oncogenic Human Viruses and its Impact on Cancer Development. Front Cell Dev Biol (2020) 8:47. doi: 10.3389/fcell.2020.00047
84
SurviladzeZSterkRTDeHaroSAOzbunMA. Cellular Entry of Human Papillomavirus Type 16 Involves Activation of the Phosphatidylinositol 3-Kinase/Akt/Mtor Pathway and Inhibition of Autophagy. J Virol (2013) 87:2508–17. doi: 10.1128/JVI.02319-12
85
BelleudiFNanniMRaffaSTorrisiMR. HPV16 E5 Deregulates the Autophagic Process in Human Keratinocytes. Oncotarget (2015) 6:9370–86. doi: 10.18632/oncotarget.3326
86
MattoscioDCasadioCMiccoloCMaffiniFRaimondiATacchettiCet al. Autophagy Regulates UBC9 Levels During Viral-Mediated Tumorigenesis. PloS Pathog (2017) 13:e1006262. doi: 10.1371/journal.ppat.1006262
87
LaiKMatthewsSWilmottJSKillingsworthMCYongJLCaixeiroNJet al. Differences in LC3B Expression and Prognostic Implications in Oropharyngeal and Oral Cavity Squamous Cell Carcinoma Patients. BMC Cancer (2018) 18:624. doi: 10.1186/s12885-018-4536-x
88
CarchmanEHMatkowskyjKAMeskeLLambertPF. Dysregulation of Autophagy Contributes to Anal Carcinogenesis. PloS One (2016) 11:e0164273. doi: 10.1371/journal.pone.0164273
89
KhanMImamHSiddiquiA. Subversion of Cellular Autophagy During Virus Infection: Insights From Hepatitis B and Hepatitis C Viruses. Liver Res (2018) 2:146–56. doi: 10.1016/j.livres.2018.09.002
90
MizuiTYamashinaSTanidaITakeiYUenoTSakamotoNet al. Inhibition of Hepatitis C Virus Replication by Chloroquine Targeting Virus-Associated Autophagy. J Gastroenterol (2010) 45:195–203. doi: 10.1007/s00535-009-0132-9
91
TianYSirDKuoC-FAnnDKOuJ-HJ. Autophagy Required for Hepatitis B Virus Replication in Transgenic Mice. J Virol (2011) 85:13453–6. doi: 10.1128/JVI.06064-11
92
LiuBFangMHuYHuangBLiNChangCet al. Hepatitis B Virus X Protein Inhibits Autophagic Degradation by Impairing Lysosomal Maturation. Autophagy (2014) 10:416–30. doi: 10.4161/auto.27286
93
LanS-HWuS-YZuchiniRLinX-ZSuI-JTsaiT-Fet al. Autophagy Suppresses Tumorigenesis of Hepatitis B Virus-Associated Hepatocellular Carcinoma Through Degradation of Microrna-224. Hepatol Baltim Md (2014) 59:505–17. doi: 10.1002/hep.26659
94
ShinG-CKangHSLeeARKimK-H. Hepatitis B Virus-Triggered Autophagy Targets TNFRSF10B/Death Receptor 5 for Degradation to Limit TNFSF10/TRAIL Response. Autophagy (2016) 12:2451–66. doi: 10.1080/15548627.2016.1239002
95
LuoMXMWongSHChanMTVYuLYuSSBWuFet al. Autophagy Mediates Hbx-Induced Nuclear Factor-κb Activation and Release of IL-6, IL-8, and CXCL2 in Hepatocytes. J Cell Physiol (2015) 230:2382–9. doi: 10.1002/jcp.24967
96
WongVW-SYuJChengAS-LWongGL-HChanH-YChuES-Het al. High Serum Interleukin-6 Level Predicts Future Hepatocellular Carcinoma Development in Patients With Chronic Hepatitis B. Int J Cancer (2009) 124:2766–70. doi: 10.1002/ijc.24281
97
WangLTianYOuJJ. HCV Induces the Expression of Rubicon and UVRAG to Temporally Regulate the Maturation of Autophagosomes and Viral Replication. PloS Pathog (2015) 11:e1004764. doi: 10.1371/journal.ppat.1004764
98
ChuJYKOuJ-HJ. Autophagy in HCV Replication and Protein Trafficking. Int J Mol Sci (2021) 22:1089. doi: 10.3390/ijms22031089
99
FuNDuHLiDLuYLiWWangYet al. Clusterin Contributes to Hepatitis C Virus-Related Hepatocellular Carcinoma by Regulating Autophagy. Life Sci (2020) 256:117911. doi: 10.1016/j.lfs.2020.117911
100
SaitoTIchimuraYTaguchiKSuzukiTMizushimaTTakagiKet al. P62/Sqstm1 Promotes Malignancy of HCV-Positive Hepatocellular Carcinoma Through Nrf2-Dependent Metabolic Reprogramming. Nat Commun (2016) 7:12030. doi: 10.1038/ncomms12030
101
YanLMajerciakVZhengZ-MLanK. Towards Better Understanding of KSHV Life Cycle: From Transcription and Posttranscriptional Regulations to Pathogenesis. Virol Sin (2019) 34:135–61. doi: 10.1007/s12250-019-00114-3
102
YinHQuJPengQGanR. Molecular Mechanisms of EBV-Driven Cell Cycle Progression and Oncogenesis. Med Microbiol Immunol (Berl) (2019) 208:573–83. doi: 10.1007/s00430-018-0570-1
103
LeeJ-SLiQLeeJ-YLeeS-HJeongJHLeeH-Ret al. FLIP-Mediated Autophagy Regulation in Cell Death Control. Nat Cell Biol (2009) 11:1355. doi: 10.1038/ncb1980
104
WhiteE. Autophagy and P53. Cold Spring Harb Perspect Med (2016) 6:a026120. doi: 10.1101/cshperspect.a026120
105
BhattAPDamaniaB. Aktivation of PI3K/AKT/Mtor Signaling Pathway by KSHV. Front Immunol (2012) 3:401. doi: 10.3389/fimmu.2012.00401
106
PattingreSTassaAQuXGarutiRLiangXHMizushimaNet al. Bcl-2 Antiapoptotic Proteins Inhibit Beclin 1-Dependent Autophagy. Cell (2005) 122:927–39. doi: 10.1016/j.cell.2005.07.002
107
ZhangTDongKLiangWXuDXiaHGengJet al. G-Protein-Coupled Receptors Regulate Autophagy by ZBTB16-Mediated Ubiquitination and Proteasomal Degradation of Atg14L. eLife (2015) 4:e06734. doi: 10.7554/eLife.06734
108
LiangQChangBBruloisKFCastroKMinC-KRodgersMAet al. Kaposi’s Sarcoma-Associated Herpesvirus K7 Modulates Rubicon-Mediated Inhibition of Autophagosome Maturation. J Virol (2013) 87:12499–503. doi: 10.1128/JVI.01898-13
109
MengWGaoS-J. Targeting XPO1 Enhances Innate Immune Response and Inhibits KSHV Lytic Replication During Primary Infection by Nuclear Stabilization of the P62 Autophagy Adaptor Protein. Cell Death Dis (2021) 12:29. doi: 10.1038/s41419-020-03303-1
110
LeidalAMCyrDPHillRJLeePWKMcCormickC. Subversion of Autophagy by Kaposi’s Sarcoma-Associated Herpesvirus Impairs Oncogene-Induced Senescence. Cell Host Microbe (2012) 11:167–80. doi: 10.1016/j.chom.2012.01.005
111
MoodyCAScottRSAmirghahariNNathanC-AYoungLSDawsonCWet al. Modulation of the Cell Growth Regulator Mtor by Epstein-Barr Virus-Encoded LMP2A. J Virol (2005) 79:5499. doi: 10.1128/JVI.79.9.5499-5506.2005
112
ShaoZBordeCQuignonFEscargueilAMaréchalV. Epstein–Barr Virus BALF0 and BALF1 Modulate Autophagy. Viruses (2019) 11(12):1099. doi: 10.3390/v11121099
113
GranatoMSantarelliRFarinaAGonnellaRLottiLVFaggioniAet al. Epstein-Barr Virus Blocks the Autophagic Flux and Appropriates the Autophagic Machinery to Enhance Viral Replication. J Virol (2014) 88:12715. doi: 10.1128/JVI.02199-14
114
WangLHowellMEASparks-WallaceAHawkinsCNicksicCAKohneCet al. P62-Mediated Selective Autophagy Endows Virus-Transformed Cells With Insusceptibility to DNA Damage Under Oxidative Stress. PloS Pathog (2019) 15(4):e1007541. doi: 10.1371/journal.ppat.1007541
115
WangWZhangYLiuWZhangXXiaoHZhaoMet al. CXCR4 Induces Cell Autophagy and Maintains EBV Latent Infection in Ebvagc. Theranostics (2020) 10:11549–61. doi: 10.7150/thno.44251
116
DucasaNGrassoDBenencioPPapademetrioDLBiglioneMKashanchiFet al. Autophagy in Human T-Cell Leukemia Virus Type 1 (HTLV-1) Induced Leukemia. Front Oncol (2021) 11:641269. doi: 10.3389/fonc.2021.641269
117
RenTTakahashiYLiuXLoughranTPSunS-CWangH-Get al. HTLV-1 Tax Deregulates Autophagy by Recruiting Autophagic Molecules Into Lipid Raft Microdomains. Oncogene (2015) 34:334–45. doi: 10.1038/onc.2013.552
118
TangS-WChenC-YKlaseZZaneLJeangK-T. The Cellular Autophagy Pathway Modulates Human T-Cell Leukemia Virus Type 1 Replication. J Virol (2013) 87:1699–707. doi: 10.1128/JVI.02147-12
119
MukaiROhshimaT. HTLV-1 HBZ Positively Regulates the Mtor Signaling Pathway via Inhibition of GADD34 Activity in the Cytoplasm. Oncogene (2014) 33:2317–28. doi: 10.1038/onc.2013.181
120
KumarSXieHShiHGaoJJuhlinCCBjörnhagenVet al. Merkel Cell Polyomavirus Oncoproteins Induce Micrornas That Suppress Multiple Autophagy Genes. Int J Cancer (2020) 146:1652–66. doi: 10.1002/ijc.32503
121
MartinNTBellJC. Oncolytic Virus Combination Therapy: Killing One Bird With Two Stones. Mol Ther (2018) 26:1414–22. doi: 10.1016/j.ymthe.2018.04.001
122
RussellSJPengK-W. Oncolytic Virotherapy: A Contest Between Apples and Oranges. Mol Ther (2017) 25:1107–16. doi: 10.1016/j.ymthe.2017.03.026
123
BaiYHuiPDuXSuX. Updates to the Antitumor Mechanism of Oncolytic Virus. Thorac Cancer (2019) 10:1031–5. doi: 10.1111/1759-7714.13043
124
LinLBaehreckeEH. Autophagy, Cell Death, and Cancer. Mol Cell Oncol (2015) 2:e985913. doi: 10.4161/23723556.2014.985913
125
GalluzziLVitaleIAbramsJMAlnemriESBaehreckeEHBlagosklonnyMVet al. Molecular Definitions of Cell Death Subroutines: Recommendations of the Nomenclature Committee on Cell Death 2012. Cell Death Differ (2012) 19:107–20. doi: 10.1038/cdd.2011.96
126
BerryDLBaehreckeEH. Growth Arrest and Autophagy Are Required for Salivary Gland Cell Degradation in Drosophila. Cell (2007) 131:1137–48. doi: 10.1016/j.cell.2007.10.048
127
LinderBKögelD. Autophagy in Cancer Cell Death. Biology (2019) 8(4):82. doi: 10.3390/biology8040082
128
GrekovaSPRaykovZZawatzkyRRommelaereJKochU. Activation of a Glioma-Specific Immune Response by Oncolytic Parvovirus Minute Virus of Mice Infection. Cancer Gene Ther (2012) 19:468–75. doi: 10.1038/cgt.2012.20
129
MoehlerMZeidlerMSchedeJRommelaereJGallePRCornelisJJet al. Oncolytic Parvovirus H1 Induces Release of Heat-Shock Protein HSP72 in Susceptible Human Tumor Cells But may Not Affect Primary Immune Cells. Cancer Gene Ther (2003) 10:477–80. doi: 10.1038/sj.cgt.7700591
130
ElankumaranSRockemannDSamalSK. Newcastle Disease Virus Exerts Oncolysis by Both Intrinsic and Extrinsic Caspase-Dependent Pathways of Cell Death. J Virol (2006) 80:7522–34. doi: 10.1128/JVI.00241-06
131
WhildingLMArchibaldKMKulbeHBalkwillFRÖbergDMcNeishIA. Vaccinia Virus Induces Programmed Necrosis in Ovarian Cancer Cells. Mol Ther (2013) 21:2074–86. doi: 10.1038/mt.2013.195
132
JinK-TTaoX-HFanY-BWangS-B. Crosstalk Between Oncolytic Viruses and Autophagy in Cancer Therapy. BioMed Pharmacother Biomed Pharmacother (2021) 134:110932. doi: 10.1016/j.biopha.2020.110932
133
TazawaHKagawaSFujiwaraT. Oncolytic Adenovirus-Induced Autophagy: Tumor-Suppressive Effect and Molecular Basis. Acta Med Okayama (2013) 67:333–42. doi: 10.18926/AMO/52006
134
ItoHAokiHKühnelFKondoYKubickaSWirthTet al. Autophagic Cell Death of Malignant Glioma Cells Induced by a Conditionally Replicating Adenovirus. JNCI J Natl Cancer Inst (2006) 98:625–36. doi: 10.1093/jnci/djj161
135
TazawaHYanoSYoshidaRYamasakiYSasakiTHashimotoYet al. Genetically Engineered Oncolytic Adenovirus Induces Autophagic Cell Death Through an E2F1-Microrna-7-Epidermal Growth Factor Receptor Axis. Int J Cancer (2012) 131:2939–50. doi: 10.1002/ijc.27589
136
UlasovIVTylerMAZhuZBHanYHeT-CLesniakMS. Oncolytic Adenoviral Vectors Which Employ the Survivin Promoter Induce Glioma Oncolysis via a Process of Beclin-Dependent Autophagy. Int J Oncol (2009) 34:729–42. doi: 10.3892/ijo_00000199
137
TazawaHKurodaSHaseiJKagawaSFujiwaraT. Impact of Autophagy in Oncolytic Adenoviral Therapy for Cancer. Int J Mol Sci (2017) 18(7):1479. doi: 10.3390/ijms18071479
138
Rodriguez-RochaHGomez-GutierrezJGGarcia-GarciaARaoX-MChenLMcMastersKMet al. Adenoviruses Induce Autophagy to Promote Virus Replication and Oncolysis. Virology (2011) 416:9–15. doi: 10.1016/j.virol.2011.04.017
139
FurukawaYTakasuAYuraY. Role of Autophagy in Oncolytic Herpes Simplex Virus Type 1-Induced Cell Death in Squamous Cell Carcinoma Cells. Cancer Gene Ther (2017) 24:393–400. doi: 10.1038/cgt.2017.33
140
BuXZhaoYZhangZWangMLiMYanY. Recombinant Newcastle Disease Virus (Rl-RVG) Triggers Autophagy and Apoptosis in Gastric Carcinoma Cells by Inducing ER Stress. Am J Cancer Res (2016) 6:924–36.
141
MengCZhouZJiangKYuSJiaLWuYet al. Newcastle Disease Virus Triggers Autophagy in U251 Glioma Cells to Enhance Virus Replication. Arch Virol (2012) 157:1011–8. doi: 10.1007/s00705-012-1270-6
142
JiangKLiYZhuQXuJWangYDengWet al. Pharmacological Modulation of Autophagy Enhances Newcastle Disease Virus-Mediated Oncolysis in Drug-Resistant Lung Cancer Cells. BMC Cancer (2014) 14:551. doi: 10.1186/1471-2407-14-551
143
XiaMGonzalezPLiCMengGJiangAWangHet al. Mitophagy Enhances Oncolytic Measles Virus Replication by Mitigating DDX58/RIG-I-Like Receptor Signaling. J Virol (2014) 88:5152–64. doi: 10.1128/JVI.03851-13
144
XiaMMengGJiangAChenADahlhausMGonzalezPet al. Mitophagy Switches Cell Death From Apoptosis to Necrosis in NSCLC Cells Treated With Oncolytic Measles Virus. Oncotarget (2014) 5:3907–18. doi: 10.18632/oncotarget.2028
145
TongYYouLLiuHLiLMengHQianQet al. Potent Antitumor Activity of Oncolytic Adenovirus Expressing Beclin-1 via Induction of Autophagic Cell Death in Leukemia. Oncotarget (2013) 4:860–74. doi: 10.18632/oncotarget.1018
146
LeiWWangSXuNChenYWuGZhangAet al. Enhancing Therapeutic Efficacy of Oncolytic Vaccinia Virus Armed With Beclin-1, an Autophagic Gene in Leukemia and Myeloma. BioMed Pharmacother (2020) 125:110030. doi: 10.1016/j.biopha.2020.110030
147
de MatosALFrancoLSMcFaddenG. Oncolytic Viruses and the Immune System: The Dynamic Duo. Mol Ther - Methods Clin Dev (2020) 17:349–58. doi: 10.1016/j.omtm.2020.01.001
148
KeppOSenovillaLVitaleIVacchelliEAdjemianSAgostinisPet al. Consensus Guidelines for the Detection of Immunogenic Cell Death. OncoImmunology (2014) 3:e955691. doi: 10.4161/21624011.2014.955691
149
DonnellyOGErrington-MaisFSteeleLHadacEJenningsVScottKet al. Measles Virus Causes Immunogenic Cell Death in Human Melanoma. Gene Ther (2013) 20:7–15. doi: 10.1038/gt.2011.205
150
EndoYSakaiROuchiMOnimatsuHHiokiMKagawaSet al. Virus-Mediated Oncolysis Induces Danger Signal and Stimulates Cytotoxic T-Lymphocyte Activity via Proteasome Activator Upregulation. Oncogene (2008) 27:2375–81. doi: 10.1038/sj.onc.1210884
151
GrekovaSPRaykovZZawatzkyRRommelaereJKochU. Activation of a Glioma-Specific Immune Response by Oncolytic Parvovirus Minute Virus of Mice Infection. Cancer Gene Ther (2012) 19:468–75. doi: 10.1038/cgt.2012.20
152
MiyamotoSInoueHNakamuraTYamadaMSakamotoCUrataYet al. Coxsackievirus B3 Is an Oncolytic Virus With Immunostimulatory Properties That Is Active Against Lung Adenocarcinoma. Cancer Res (2012) 72:2609–21. doi: 10.1158/0008-5472.CAN-11-3185
153
ZhangYChirmuleNGaoGQianRCroyleMJoshiBet al. Acute Cytokine Response to Systemic Adenoviral Vectors in Mice Is Mediated by Dendritic Cells and Macrophages. Mol Ther (2001) 3:697–707. doi: 10.1006/mthe.2001.0329
154
QuXZouZSunQLuby-PhelpsKChengPHoganRNet al. Autophagy Gene-Dependent Clearance of Apoptotic Cells During Embryonic Development. Cell (2007) 128:931–46. doi: 10.1016/j.cell.2006.12.044
155
MichaudMMartinsISukkurwalaAQAdjemianSMaYPellegattiPet al. Autophagy-Dependent Anticancer Immune Responses Induced by Chemotherapeutic Agents in Mice. Science (2011) 334:1573–7. doi: 10.1126/science.1208347
156
KoAKanehisaAMartinsISenovillaLChargariCDugueDet al. Autophagy Inhibition Radiosensitizes In Vitro, Yet Reduces Radioresponses In Vivo Due to Deficient Immunogenic Signalling. Cell Death Differ (2014) 21:92–9. doi: 10.1038/cdd.2013.124
157
ThorburnJHoritaHRedzicJHansenKFrankelAEThorburnA. Autophagy Regulates Selective HMGB1 Release in Tumor Cells That Are Destined to Die. Cell Death Differ (2009) 16:175–83. doi: 10.1038/cdd.2008.143
158
YouLJinSZhuLQianW. Autophagy, Autophagy-Associated Adaptive Immune Responses and its Role in Hematologic Malignancies. Oncotarget (2016) 8:12374–88. doi: 10.18632/oncotarget.13583
159
CrotzerVLBlumJS. Autophagy and its Role in MHC-Mediated Antigen Presentation. J Immunol Baltim Md 1950 (2009) 182:3335–41. doi: 10.4049/jimmunol.0803458
160
LiYWangL-XYangGHaoFUrbaWJHuH-M. Efficient Cross-Presentation Depends on Autophagy in Tumor Cells. Cancer Res (2008) 68:6889–95. doi: 10.1158/0008-5472.CAN-08-0161
161
LiikanenIAhtiainenLHirvinenMLBramanteSCerulloVNokisalmiPet al. Oncolytic Adenovirus With Temozolomide Induces Autophagy and Antitumor Immune Responses in Cancer Patients. Mol Ther (2013) 21:1212–23. doi: 10.1038/mt.2013.51
162
KleinSRJiangHHossainMBFanXGuminJDongAet al. Critical Role of Autophagy in the Processing of Adenovirus Capsid-Incorporated Cancer-Specific Antigens. PloS One (2016) 11:e0153814. doi: 10.1371/journal.pone.0153814
163
KeshavarzMSolaymani-MohammadiFMiriSMGhaemiA. Oncolytic Paramyxoviruses-Induced Autophagy; A Prudent Weapon for Cancer Therapy. J BioMed Sci (2019) 26:48. doi: 10.1186/s12929-019-0542-9
164
KoksCAGargADEhrhardtMRivaMVandenberkLBoonLet al. Newcastle Disease Virotherapy Induces Long-Term Survival and Tumor-Specific Immune Memory in Orthotopic Glioma Through the Induction of Immunogenic Cell Death. Int J Cancer (2015) 136:E313–325. doi: 10.1002/ijc.29202
165
YeTJiangKWeiLBarrMPXuQZhangGet al. Oncolytic Newcastle Disease Virus Induces Autophagy-Dependent Immunogenic Cell Death in Lung Cancer Cells. Am J Cancer Res (2018) 8:1514–27.
166
BollinoDColungaALiBAurelianL. ΔPK Oncolytic Activity Includes Modulation of the Tumour Cell Milieu. J Gen Virol (2016) 97:496–508. doi: 10.1099/jgv.0.000353
167
WhiteEMehnertJMChanCS. Autophagy, Metabolism, and Cancer. Clin Cancer Res Off J Am Assoc Cancer Res (2015) 21:5037–46. doi: 10.1158/1078-0432.CCR-15-0490
168
DaskalakiIGkikasITavernarakisN. Hypoxia and Selective Autophagy in Cancer Development and Therapy. Front Cell Dev Biol (2018) 6:104. doi: 10.3389/fcell.2018.00104
169
MasoudGNLiW. Hif-1α Pathway: Role, Regulation and Intervention for Cancer Therapy. Acta Pharm Sin B (2015) 5:378–89. doi: 10.1016/j.apsb.2015.05.007
170
SchmuklerEKloogYPinkas-KramarskiR. Ras and Autophagy in Cancer Development and Therapy. Oncotarget (2014) 5:577–86. doi: 10.18632/oncotarget.1775
171
MariñoGNiso-SantanoMBaehreckeEHKroemerG. Self-Consumption: The Interplay of Autophagy and Apoptosis. Nat Rev Mol Cell Biol (2014) 15:81–94. doi: 10.1038/nrm3735
172
DatanERoySGGermainGZaliNMcLeanJEGolshanGet al. Dengue-Induced Autophagy, Virus Replication and Protection From Cell Death Require ER Stress (PERK) Pathway Activation. Cell Death Dis (2016) 7:e2127–7. doi: 10.1038/cddis.2015.409
173
McLeanJEWudzinskaADatanEQuaglinoDZakeriZ. Flavivirus NS4A-Induced Autophagy Protects Cells Against Death and Enhances Virus Replication *. J Biol Chem (2011) 286:22147–59. doi: 10.1074/jbc.M110.192500
174
MaoYDaLTangHYangJLeiYTiollaisPet al. Hepatitis B Virus X Protein Reduces Starvation-Induced Cell Death Through Activation of Autophagy and Inhibition of Mitochondrial Apoptotic Pathway. Biochem Biophys Res Commun (2011) 415:68–74. doi: 10.1016/j.bbrc.2011.10.013
175
QuanMLiuSZhouLFengSZhangYChengJ. Hepatitis C Virus Nonstructural 5A Protein Inhibits the Starvation−Induced Apoptosis of Hepatoblastoma Cells by Increasing Beclin 1 Expression. Oncol Rep (2019) 41:3051–9. doi: 10.3892/or.2019.7060
176
WangWZhouJShiJZhangYLiuSLiuYet al. Human T-Cell Leukemia Virus Type 1 Tax-Deregulated Autophagy Pathway and C-FLIP Expression Contribute to Resistance Against Death Receptor-Mediated Apoptosis. J Virol (2014) 88:2786–98. doi: 10.1128/JVI.03025-13
177
LiMLiJZengRYangJLiuJZhangZet al. Respiratory Syncytial Virus Replication Is Promoted by Autophagy-Mediated Inhibition of Apoptosis. J Virol (2018) 92(8):e02193-17. doi: 10.1128/JVI.02193-17
178
NakashimaATanakaNTamaiKKyuumaMIshikawaYSatoHet al. Survival of Parvovirus B19-Infected Cells by Cellular Autophagy. Virology (2006) 349:254–63. doi: 10.1016/j.virol.2006.03.029
179
PengJZhuSHuLYePWangYTianQet al. Wild-Type Rabies Virus Induces Autophagy in Human and Mouse Neuroblastoma Cell Lines. Autophagy (2016) 12:1704–20. doi: 10.1080/15548627.2016.1196315
180
MengGXiaMWangDChenAWangYWangHet al. Mitophagy Promotes Replication of Oncolytic Newcastle Disease Virus by Blocking Intrinsic Apoptosis in Lung Cancer Cells. Oncotarget (2014) 5:6365–74. doi: 10.18632/oncotarget.2219
181
NomanMZJanjiBKaminskaBMoerKVPiersonSPrzanowskiPet al. Blocking Hypoxia-Induced Autophagy in Tumors Restores Cytotoxic T-Cell Activity and Promotes Regression. Cancer Res (2011) 71:5976–86. doi: 10.1158/0008-5472.CAN-11-1094
182
ViryEBaginskaJBerchemGNomanMZMedvesSChouaibSet al. Autophagic Degradation of GZMB/Granzyme B. Autophagy (2014) 10:173–5. doi: 10.4161/auto.26924
183
GongGWarisGTanveerRSiddiquiA. Human Hepatitis C Virus NS5A Protein Alters Intracellular Calcium Levels, Induces Oxidative Stress, and Activates STAT-3 and NF-κb. Proc Natl Acad Sci (2001) 98:9599–604. doi: 10.1073/pnas.171311298
184
KenificCMThorburnADebnathJ. Autophagy and Metastasis: Another Double-Edged Sword. Curr Opin Cell Biol (2010) 22:241–5. doi: 10.1016/j.ceb.2009.10.008
185
CatalanoMD’AlessandroGLeporeFCorazzariMCaldarolaSValaccaCet al. Autophagy Induction Impairs Migration and Invasion by Reversing EMT in Glioblastoma Cells. Mol Oncol (2015) 9:1612–25. doi: 10.1016/j.molonc.2015.04.016
186
BellESCoelhoPPRatcliffeCDHRajaduraiCVPeschardPVaillancourtRet al. LC3C-Mediated Autophagy Selectively Regulates the Met RTK and HGF-Stimulated Migration and Invasion. Cell Rep (2019) 29:4053–4068.e6. doi: 10.1016/j.celrep.2019.11.063
187
GuadamillasMCCerezoA. Pozo MA Del. Overcoming Anoikis – Pathways to Anchorage-Independent Growth in Cancer. J Cell Sci (2011) 124:3189–97. doi: 10.1242/jcs.072165
188
PengY-FShiY-HDingZ-BKeA-WGuC-YHuiBet al. Autophagy Inhibition Suppresses Pulmonary Metastasis of HCC in mice via impairing anoikis resistance and colonization of HCC cells. Autophagy (2013) 9:2056–68. doi: 10.4161/auto.26398
189
SharifTMartellEDaiCKennedyBEMurphyPClementsDRet al. Autophagic Homeostasis Is Required for the Pluripotency of Cancer Stem Cells. Autophagy (2017) 13:264–84. doi: 10.1080/15548627.2016.1260808
190
MowersEESharifiMNMacleodKF. Autophagy in Cancer Metastasis. Oncogene (2017) 36:1619–30. doi: 10.1038/onc.2016.333
191
MaLDengXWuMZhangGHuangJ. Down-Regulation of Mirna-204 by LMP-1 Enhances CDC42 Activity and Facilitates Invasion of EBV-Associated Nasopharyngeal Carcinoma Cells. FEBS Lett (2014) 588:1562–70. doi: 10.1016/j.febslet.2014.02.039
192
CaiL-MLyuX-MLuoW-RCuiX-FYeY-FYuanC-Cet al. EBV-MiR-BART7-3p Promotes the EMT and Metastasis of Nasopharyngeal Carcinoma Cells by Suppressing the Tumor Suppressor PTEN. Oncogene (2015) 34:2156–66. doi: 10.1038/onc.2014.341
193
YanQZengZGongZZhangWLiXHeBet al. EBV-Mir-BART10-3p Facilitates Epithelial-Mesenchymal Transition and Promotes Metastasis of Nasopharyngeal Carcinoma by Targeting BTRC. Oncotarget (2015) 6:41766–82. doi: 10.18632/oncotarget.6155
194
LiGWuZPengYLiuXLuJWangLet al. Microrna-10b Induced by Epstein-Barr Virus-Encoded Latent Membrane Protein-1 Promotes the Metastasis of Human Nasopharyngeal Carcinoma Cells. Cancer Lett (2010) 299:29–36. doi: 10.1016/j.canlet.2010.07.021
195
ZhuXWangYSunYZhengJZhuD. MiR-155 Up-Regulation by LMP1 DNA Contributes to Increased Nasopharyngeal Carcinoma Cell Proliferation and Migration. Eur Arch Otorhinolaryngol (2014) 271:1939–45. doi: 10.1007/s00405-013-2818-0
196
WangQSongRZhaoCLiuHYangYGuSet al. HPV16 E6 Promotes Cervical Cancer Cell Migration and Invasion by Downregulation of NHERF1. Int J Cancer (2019) 144:1619–32. doi: 10.1002/ijc.31876
197
MileoAMPiombinoESeverinoATritarelliAPaggiMGLombardiD. Multiple Interference of the Human Papillomavirus-16 E7 Oncoprotein With the Functional Role of the Metastasis Suppressor Nm23-H1 Protein. J Bioenerg Biomembr (2006) 38:215. doi: 10.1007/s10863-006-9037-y
198
KheraLPaulCKaulR. Hepatitis C Virus E1 Protein Promotes Cell Migration and Invasion by Modulating Cellular Metastasis Suppressor Nm23-H1. Virology (2017) 506:110–20. doi: 10.1016/j.virol.2017.03.014
199
WangXLiuSZhouZYanHXiaoJ. A Herpes Simplex Virus Type 2–Encoded Microrna Promotes Tumor Cell Metastasis by Targeting Suppressor of Cytokine Signaling 2 in Lung Cancer. Tumor Biol (2017) 39(5):1010428317701633. doi: 10.1177/1010428317701633 1010428317701633.
200
VomaskeJVarnumSMelnychukRSmithPPasa-TolicLShutthanandanJIet al. HCMV Pus28 Initiates Pro-Migratory Signaling via Activation of Pyk2 Kinase. Herpesviridae (2010) 1:2. doi: 10.1186/2042-4280-1-2
201
ShengYLiJZouCWangSCaoYZhangJet al. Downregulation of Mir-101-3p by Hepatitis B Virus Promotes Proliferation and Migration of Hepatocellular Carcinoma Cells by Targeting Rab5a. Arch Virol (2014) 159:2397–410. doi: 10.1007/s00705-014-2084-5
202
BelaidACerezoMCharguiACorcelle–TermeauEPedeutourFGiulianoSet al. Autophagy Plays a Critical Role in the Degradation of Active RHOA, the Control of Cell Cytokinesis and Genomic Stability. Cancer Res (2013) 73:4311–22. doi: 10.1158/0008-5472.CAN-12-4142
203
ZhangYLiJWangSYangFZhouYLiuYet al. Hbx−Associated Long Non−Coding RNA Activated by TGF−β Promotes Cell Invasion and Migration by Inducing Autophagy in Primary Liver Cancer. Int J Oncol (2020) 56:337–47. doi: 10.3892/ijo.2019.4908
204
BaoLJaramilloMCZhangZZhengYYaoMZhangDDet al. Induction of Autophagy Contributes to Cisplatin Resistance in Human Ovarian Cancer Cells. Mol Med Rep (2015) 11:91–8. doi: 10.3892/mmr.2014.2671
205
ChenZJiangQZhuPChenYXieXDuZet al. NPRL2 Enhances Autophagy and the Resistance to Everolimus in Castration-Resistant Prostate Cancer. Prostate (2019) 79:44–53. doi: 10.1002/pros.23709
206
SuiXKongNWangXFangYHuXXuYet al. JNK Confers 5-Fluorouracil Resistance in P53-Deficient and Mutant P53-Expressing Colon Cancer Cells by Inducing Survival Autophagy. Sci Rep (2014) 4:4694. doi: 10.1038/srep04694
207
WangJWuGS. Role of Autophagy in Cisplatin Resistance in Ovarian Cancer Cells. J Biol Chem (2014) 289:17163–73. doi: 10.1074/jbc.M114.558288
208
XiaoXWangWLiYYangDLiXShenCet al. HSP90AA1-Mediated Autophagy Promotes Drug Resistance in Osteosarcoma. J Exp Clin Cancer Res (2018) 37:201. doi: 10.1186/s13046-018-0880-6
209
ChenXWangPGuoFWangXWangJXuJet al. Autophagy Enhanced the Radioresistance of Non-Small Cell Lung Cancer by Regulating ROS Level Under Hypoxia Condition. Int J Radiat Biol (2017) 93:764–70. doi: 10.1080/09553002.2017.1325025
210
HuJLHeGYLanXLZengZCGuanJDingYet al. Inhibition of ATG12-Mediated Autophagy by Mir-214 Enhances Radiosensitivity in Colorectal Cancer. Oncogenesis (2018) 7:1–12. doi: 10.1038/s41389-018-0028-8
211
LomonacoSLFinnissSXiangCDeCarvalhoAUmanskyFKalkanisSNet al. The Induction of Autophagy by γ-Radiation Contributes to the Radioresistance of Glioma Stem Cells. Int J Cancer (2009) 125:717–22. doi: 10.1002/ijc.24402
212
WangPZhangJZhangLZhuZFanJChenLet al. Microrna 23b Regulates Autophagy Associated With Radioresistance of Pancreatic Cancer Cells. Gastroenterology (2013) 145:1133–1143.e12. doi: 10.1053/j.gastro.2013.07.048
213
ChenYLiXGuoLWuXHeCZhangSet al. Combining Radiation With Autophagy Inhibition Enhances Suppression of Tumor Growth and Angiogenesis in Esophageal Cancer. Mol Med Rep (2015) 12:1645–52. doi: 10.3892/mmr.2015.3623
214
ChengCYLiuJCWangJJLiYHPanJZhangYR. Autophagy Inhibition Increased the Anti-Tumor Effect of Cisplatin on Drug-Resistant Esophageal Cancer Cells. J Biol Regul Homeost Agents (2017) 31:645–52.
215
ChingRHHSzeKMFLauEYTChiuY-TLeeJMFNgIOL. Lee TKW. C-Terminal Truncated Hepatitis B Virus X Protein Regulates Tumorigenicity, Self-Renewal and Drug Resistance via STAT3/Nanog Signaling Pathway. Oncotarget (2017) 8:23507–16. doi: 10.18632/oncotarget.15183
216
SuK-JYuY-L. Downregulation of SHIP2 by Hepatitis B Virus X Promotes the Metastasis and Chemoresistance of Hepatocellular Carcinoma Through SKP2. Cancers (2019) 11:1065. doi: 10.3390/cancers11081065
217
TanYLiY. HCV Core Protein Promotes Hepatocyte Proliferation and Chemoresistance by Inhibiting NR4A1. Biochem Biophys Res Commun (2015) 466:592–8. doi: 10.1016/j.bbrc.2015.09.091
218
WangCWangMChengPHuangHDongWZhangWet al. Hepatitis B Virus X Protein Promotes the Stem-Like Properties of OV6 + Cancer Cells in Hepatocellular Carcinoma. Cell Death Dis (2018) 8:e2560–0. doi: 10.1038/cddis.2016.493
219
BourguignonLYWEarleCShiinaM. Hyaluronan-CD44 Interaction Promotes HPV 16 E6 Oncogene-Mediated Oropharyngeal Cell Carcinoma Survival and Chemoresistance. Matrix Biol (2019) 78–79:180–200. doi: 10.1016/j.matbio.2018.07.008
220
JiaQYanCZhengXPanXCaoXCaoL. Upregulation of MTA1 Expression by Human Papillomavirus Infection Promotes CDDP Resistance in Cervical Cancer Cells via Modulation of NF-κb/APOBEC3B Cascade. Cancer Chemother Pharmacol (2019) 83:625–37. doi: 10.1007/s00280-018-03766-2
221
KimHChoiHLeeSK. Epstein–Barr Virus Mir-BART20-5p Regulates Cell Proliferation and Apoptosis by Targeting BAD. Cancer Lett (2015) 356:733–42. doi: 10.1016/j.canlet.2014.10.023
222
YangG-DHuangT-JPengL-XYangC-FLiuR-YHuangH-Bet al. Epstein-Barr Virus_Encoded LMP1 Upregulates Microrna-21 to Promote the Resistance of Nasopharyngeal Carcinoma Cells to Cisplatin-Induced Apoptosis by Suppressing PDCD4 and Fas-L. PloS One (2013) 8:e78355. doi: 10.1371/journal.pone.0078355
223
SeoJSKimT-GHongYSChenJ-YLeeSK. Contribution of Epstein-Barr Virus Infection to Chemoresistance of Gastric Carcinoma Cells to 5-Fluorouracil. Arch Pharm Res (2011) 34:635–43. doi: 10.1007/s12272-011-0414-7
224
WuQHanTShengXZhangNWangP. Downregulation of EB Virus Mir-BART4 Inhibits Proliferation and Aggressiveness While Promoting Radiosensitivity of Nasopharyngeal Carcinoma. BioMed Pharmacother (2018) 108:741–51. doi: 10.1016/j.biopha.2018.08.146
225
ZhouXZhengJTangYlinYWangLLiYet al. EBV Encoded miRNA BART8-3p Promotes Radioresistance in Nasopharyngeal Carcinoma by Regulating ATM/ATR Signaling Pathway. Biosci Rep (2019) 39(9):BSR20190415. doi: 10.1042/BSR20190415
226
LuJTangMLiHXuZWengXLiJet al. EBV-LMP1 Suppresses the DNA Damage Response Through DNA-PK/AMPK Signaling to Promote Radioresistance in Nasopharyngeal Carcinoma. Cancer Lett (2016) 380:191–200. doi: 10.1016/j.canlet.2016.05.032
227
XuSZhouZPengXTaoXZhouPZhangKet al. EBV-LMP1 Promotes Radioresistance by Inducing Protective Autophagy Through BNIP3 in Nasopharyngeal Carcinoma. Cell Death Dis (2021) 12:1–12. doi: 10.1038/s41419-021-03639-2
228
AntonioliMPagniBVescovoTEllisRCoswayBRolloFet al. HPV Sensitizes OPSCC Cells to Cisplatin-Induced Apoptosis by Inhibiting Autophagy Through E7-Mediated Degradation of AMBRA1. Autophagy (2020) 11:1–14. doi: 10.1080/15548627.2020.1847444
229
BoukhaledGMHardingSBrooksDG. Opposing Roles of Type I Interferons in Cancer Immunity. Annu Rev Pathol (2021) 16:167–98. doi: 10.1146/annurev-pathol-031920-093932
230
TalMCSasaiMLeeHKYordyBShadelGSIwasakiA. Absence of Autophagy Results in Reactive Oxygen Species-Dependent Amplification of RLR Signaling. Proc Natl Acad Sci (2009) 106(8):2770–5. doi: 10.1073/pnas.0807694106
231
ShiC-SQiH-YBoularanCHuangN-NAbu-AsabMShelhamerJHet al. SARS-Coronavirus Open Reading Frame-9b Suppresses Innate Immunity by Targeting Mitochondria and the MAVS/TRAF3/TRAF6 Signalosome. J Immunol (2014) 193(6):3080–9. doi: 10.4049/jimmunol.1303196
232
DingBZhangLLiZZhongYTangQQinYet al. The Matrix Protein of Human Parainfluenza Virus Type 3 Induces Mitophagy That Suppresses Interferon Responses. Cell Host Microbe (2017) 21:538–547.e4. doi: 10.1016/j.chom.2017.03.004
233
XiaMGonzalezPLiCMengGJiangAWangHet al. Mitophagy Enhances Oncolytic Measles Virus Replication by Mitigating DDX58/RIG-I-Like Receptor Signaling. J Virol (2014) 88:5152–64. doi: 10.1128/JVI.03851-13
234
WangRZhuYRenCYangSTianSChenHet al. Influenza a Virus Protein PB1-F2 Impairs Innate Immunity by Inducing Mitophagy. Autophagy (2021) 17:496–511. doi: 10.1080/15548627.2020.1725375
235
YuJ-WLeeM-S. Mitochondria and the NLRP3 Inflammasome: Physiological and Pathological Relevance. Arch Pharm Res (2016) 39:1503–18. doi: 10.1007/s12272-016-0827-4
236
ZhouRYazdiASMenuPTschoppJ. A Role for Mitochondria in NLRP3 Inflammasome Activation. Nature (2011) 469:221–5. doi: 10.1038/nature09663
237
LupferCThomasPGAnandPKVogelPMilastaSMartinezJet al. Receptor Interacting Protein Kinase 2–Mediated Mitophagy Regulates Inflammasome Activation During Virus Infection. Nat Immunol (2013) 14:480–8. doi: 10.1038/ni.2563
238
KomuneNIchinoheTItoMYanagiY. Measles Virus V Protein Inhibits Nlrp3 Inflammasome-Mediated Interleukin-1β Secretion(2011) (Accessed June 3, 2021). undefined.
239
LuoXDonnellyCRGongWHeathBRHaoYDonnellyLAet al. HPV16 Drives Cancer Immune Escape via NLRX1-Mediated Degradation of STING. J Clin Invest (2020) 130:1635–52. doi: 10.1172/JCI129497
240
AviaMRojasJMMiorinLPascualEVan RijnPAMartínVet al. Virus-Induced Autophagic Degradation of STAT2 as a Mechanism for Interferon Signaling Blockade. EMBO Rep (2019) 20:e48766. doi: 10.15252/embr.201948766
241
ShiodeYHikitaHTanakaSShiraiKDoiASakaneSet al. Hepatitis C Virus Enhances Rubicon Expression, Leading to Autophagy Inhibition and Intracellular Innate Immune Activation. Sci Rep (2020) 10:15290. doi: 10.1038/s41598-020-72294-y
242
MuscolinoESchmitzRLorochSCaraglianoESchneiderCRizzatoMet al. Herpesviruses Induce Aggregation and Selective Autophagy of Host Signalling Proteins NEMO and RIPK1 as an Immune-Evasion Mechanism. Nat Microbiol (2020) 5:331–42. doi: 10.1038/s41564-019-0624-1
243
FlissPMJowersTPBrinkmannMMHolstermannBMackCDickinsonPet al. Viral Mediated Redirection of NEMO/Ikkγ to Autophagosomes Curtails the Inflammatory Cascade. PloS Pathog (2012) 8:e1002517. doi: 10.1371/journal.ppat.1002517
244
HansenTHBouvierM. MHC Class I Antigen Presentation: Learning From Viral Evasion Strategies. Nat Rev Immunol (2009) 9:503–13. doi: 10.1038/nri2575
245
MorrowGSlobedmanBCunninghamALAbendrothA. Varicella-Zoster Virus Productively Infects Mature Dendritic Cells and Alters Their Immune Function. J Virol (2003) 77:4950–9. doi: 10.1128/jvi.77.8.4950-4959.2003
246
LoiMMüllerASteinbachKNivenJBarreira da SilvaRPaulPet al. Macroautophagy Proteins Control MHC Class I Levels on Dendritic Cells and Shape Anti-Viral CD8(+) T Cell Responses. Cell Rep (2016) 15:1076–87. doi: 10.1016/j.celrep.2016.04.002
247
YamamotoKVenidaAYanoJBiancurDEKakiuchiMGuptaSet al. Autophagy Promotes Immune Evasion of Pancreatic Cancer by Degrading MHC-I. Nature (2020) 581:100–5. doi: 10.1038/s41586-020-2229-5
Summary
Keywords
tumor development and progression, autophagy, viral infection, oncolytic virus, oncogenic virus, immunity, tumor resistance, tumorigenesis
Citation
Leonardi L, Sibéril S, Alifano M, Cremer I and Joubert P-E (2021) Autophagy Modulation by Viral Infections Influences Tumor Development. Front. Oncol. 11:743780. doi: 10.3389/fonc.2021.743780
Received
19 July 2021
Accepted
27 September 2021
Published
22 October 2021
Volume
11 - 2021
Edited by
Chris Albanese, Georgetown University, United States
Reviewed by
Manuela Antonioli, Istituto Nazionale per le Malattie Infettive Lazzaro Spallanzani (IRCCS), Italy; Susana Romero-Garcia, Universidad Nacional Autónoma de México, Mexico
Updates
Copyright
© 2021 Leonardi, Sibéril, Alifano, Cremer and Joubert.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Pierre-Emmanuel Joubert, pierre-emmanuel.joubert@sorbonne-universite.fr
This article was submitted to Cancer Metabolism, a section of the journal Frontiers in Oncology
Disclaimer
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.