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. 2019 Apr 18;9:95. doi: 10.3389/fcimb.2019.00095

Virus Control of Cell Metabolism for Replication and Evasion of Host Immune Responses

María Maximina B Moreno-Altamirano 1,*, Simon E Kolstoe 2, Francisco Javier Sánchez-García 1,*
PMCID: PMC6482253  PMID: 31058096

Abstract

Over the last decade, there has been significant advances in the understanding of the cross-talk between metabolism and immune responses. It is now evident that immune cell effector function strongly depends on the metabolic pathway in which cells are engaged in at a particular point in time, the activation conditions, and the cell microenvironment. It is also clear that some metabolic intermediates have signaling as well as effector properties and, hence, topics such as immunometabolism, metabolic reprograming, and metabolic symbiosis (among others) have emerged. Viruses completely rely on their host's cell energy and molecular machinery to enter, multiply, and exit for a new round of infection. This review explores how viruses mimic, exploit or interfere with host cell metabolic pathways and how, in doing so, they may evade immune responses. It offers a brief outline of key metabolic pathways, mitochondrial function and metabolism-related signaling pathways, followed by examples of the mechanisms by which several viral proteins regulate host cell metabolic activity.

Keywords: viruses, cell metabolism, mitochondria, immune response, viral evasion

Introduction

Several recent comprehensive reviews have highlighted the key role of eukaryotic cell metabolism in immunity (Ganeshan and Chawla, 2014; O'Neill and Pearce, 2016; O'Neill et al., 2016). Six main and interconnected metabolic pathways have a role in the immune response: glycolysis; the pentose phosphate pathway (PPP); the tricarboxylic acid cycle (TCA), also known as Krebs cycle; the fatty acid oxidation (FAO), also known as β-oxidation; as well as the fatty acid and amino acid synthesis pathways (Figure 1).

Figure 1.

Figure 1

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Eukaryotic cell metabolism. Bioenergetic and biosynthetic pathways interconnect glycolysis, glutaminolysis, PPP (pentose phospahate pathway), TCA (tricarboxylic acid cycle), FAO (fatty acid oxidation), fatty acid synthesis, aminoacid synthesis, metabolic sensors such as the AMPK, mTORC1, and mTORC2 pathways, and are also dependent on calcium homeostasis, mitochondrial membrane potential and mitochondrial dynamics. All together they influence cell function and may be the targets of several viruses.

Mitochondria take central stage in cellular metabolism since TCA, FAO, oxidative phosphorylation (OXPHOS), calcium buffering, and heme biosynthesis take place within this organelle (Mishra and Chan, 2016).

Energetic and biosynthetic metabolism is fueled by carbon sources, including glucose and glutamine (DeBerardinis and Cheng, 2010), which are taken up by the cells by glucose and glutamine transporters, respectively (Bhutia and Ganapathy, 2016; Navale and Paranjape, 2016).

Once in the cytosol, glucose is converted to pyruvate, via glycolysis, yielding two molecules of ATP and two molecules of NADH (which acts as a cofactor in several enzymatic reactions) per unit of glucose. The glycolysis pathway is also the source of biosynthetic intermediates that serve the purpose of ribose and nucleotides synthesis (glucose-6-phosphate into ribulose 5-phosphate), amino acids (3-phosphoglycerate enters the serine biosynthetic pathway), and fatty acids (by the sequential conversion of glycolysis-derived pyruvate into the TCA intermediate citrate that may be exported from the mitochondria to the cytosol, where it is converted into acetyl-coA).

Glycolysis-derived pyruvate is either converted to lactate, which is exported out of the cells, or converted into acetyl-CoA that enters the TCA cycle through the aldol condensation with oxaloacetate to form citrate (O'Neill et al., 2016). Citrate is then sequentially converted to isocitrate, α-ketoglutarate, succinyl CoA, succinate, fumarate, malate, and oxaloacetate, which starts a new round of the TCA cycle by its reaction with pyruvate-derived acetyl CoA. Fatty acids can also be converted into acetyl CoA through FAO, linking this metabolic pathway with the TCA cycle. Two major products of both the TCA cycle and FAO are NADH and FADH2, which can transfer electrons to the mitochondrial electron transport chain coupled with OXPHOS and the generation of ATP (O'Neill et al., 2016). In addition, succinate, an intermediate in the TCA cycle, is also an electron donor for the mitochondrial respiratory chain at complex II (succinate dehydrogenase) (Rich and Maréchal, 2010).

The pentose phosphate pathway involves a non-oxidative as well as an oxidative branch; the first allows for the diversion from glycolysis intermediates toward the synthesis of nucleotide and amino acid precursors, while the second generates reducing equivalents of nicotinamide adenine dinucleotide phosphate hydrogen (NADPH), which maintain a favorable cellular redox environment and allows fatty acid synthesis (O'Neill et al., 2016).

Fatty acid synthesis uses glycolysis, TCA cycle, and pentose phosphate pathway metabolic intermediates. TCA cycle-derived citrate may be exported from the mitochondria to the cytosol and then ATP citrate lyase converts citrate to acetyl-coA, which in turn may be carboxylated by acetyl-CoA carboxylase (ACC) producing malonyl-CoA. Furthermore, fatty acid synthase and NADPH elongate fatty acid chains (O'Neill et al., 2016).

Glutamine is also a primary source of energy as it is converted to glutamate and then to α-ketoglutarate, which enters the TCA cycle (DeBerardinis and Cheng, 2010).

Immune system cells preferentially follow one or other metabolic pathway, depending on cell type, differentiation status, activation conditions, and microenvironment. Resting T lymphocytes rely mostly on OXPHOS, whereas activated and proliferating T lymphocytes upregulate the expression of the glucose transporter glut-1 and key glycolytic enzymes, relying mostly on glycolysis (Frauwirth et al., 2002; Pearce and Pearce, 2013).

Memory T lymphocytes use OXPHOS (Pearce and Pearce, 2013), “classically activated” macrophages (stimulated with LPS plus IFN-γ)—also referred to as M1 macrophages—engage in glycolysis, whereas alternatively activated macrophages (stimulated with IL-4)—also referred to as M2 macrophages—use OXPHOS and FAO to generate energy (Rodríguez-Prados et al., 2010). Stimulated macrophages and dendritic cells engage in glycolysis after activation through pattern recognition receptors (PRRs) (O'Neill and Pearce, 2016).

Neutrophils rely mostly on glycolysis (Pearce and Pearce, 2013) and the release of neutrophil extracellular traps (NETs) is dependent on the increase in cell membrane glut-1, glucose uptake, and the glycolytic rate (Rodriguez-Espinosa et al., 2015).

Activated B lymphocytes undergo metabolic reprogramming in response to changing energetic and biosynthetic demands, and long-lived plasma cells uptake glucose and glutamine at a higher rate; glucose is used to generate pyruvate for spare respiratory capacity, and glutamine is used as a carbon source for mitochondrial anaplerotic reactions and respiration, promoting cell survival (Jellusova and Rickert, 2016; Lam et al., 2018).

Switching metabolic pathways (metabolic reprograming) leads to changes in cell function (Buck et al., 2017) and the metabolic microenvironment, i.e., tissue O2 tension, or the concentration of metabolites such as lactate determines cell immune responses (Romero-Garcia et al., 2016).

Interestingly, viral infections such as ocular infection with herpes simplex virus-1 (HSV-1) may change blood glucose levels in the course of infection (Varanasi et al., 2017). Moreover, if glucose utilization is pharmacologically limited in vivo in the inflammatory phase, lesions diminish but, if glucose utilization is limited in the acute phase of infection when the replicating virus is still present in the eye, infected mice become susceptible to the lethal effects of HSV-1 infection as the virus spreads to the brain, causing encephalitis (Varanasi et al., 2017). This highlights the fundamental relationship between cell metabolism, immune response, and viral pathogenesis.

Anti-Viral Immune Responses

Among the most effective antiviral immune responses is the production of several type I interferons (Figure 2); interferon-α (IFN-α) subtypes and interferon-β (IFN-β), which along with IFN-ε, IFN-τ, IFN-κ, IFN-ω, IFN-δ, and IFN-ζ, are collectively referred to as type I interferons; most cells can produce IFN-α and IFN-β following cell activation through the recognition of viral nucleic acids (McNab et al., 2015).

Figure 2.

Figure 2

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Antiviral immune responses. Type I interferons, cell cytotoxicity, neutrophil extracellular traps and neutralizing antibodies protect against viral infections, each type of response has a metabolic hallmark. Viruses may target specific metabolic pathways for immune evasion.?, not known.

The RIG-I-MDA5-mitochondrial antiviral-signaling protein (MAVS) axis is the major sensing pathway for RNA viruses, while the axis composed of the cyclic guanosine monophosphate (cGMP)-adenosine monophosphate (AMP) synthase (cGAS) and the stimulator of interferon genes (STING) is the major sensing pathway for DNA viruses (Wu and Chen, 2014). However, there is recent evidence that the cGAS-STING pathway may also restrict the infection by RNA viruses, thus suggesting a connection between the sensing of cytosolic DNA and RNA (Ni et al., 2018).

Both anti-viral pathways converge in the activation of two main transcription factors that regulate the expression of type-I interferons, nuclear factor kappa B (NFκB) and interferon regulatory factor 3 (IRF3). In the case of the RIG-I-MDA5-MAVS pathway, their activation depends on mitochondrial function (Seth et al., 2005; Koshiba, 2013).

Both IFN-α and IFN-β activate the expression of interferon-stimulated genes (ISGs) through the Janus kinase-signal transducer and activator of transcription (JAK-STAT) signaling pathway, leading to the inhibition of viral replication and assembly (Darnell et al., 1994; Seth et al., 2005).

Cytotoxic T lymphocytes (CTL) play an important role in the clearance of viral infections (Figure 2); memory CTL can be activated by low concentrations of antigen, readily producing cytokines and the lysis of infected cells, thus preventing dissemination (Veiga-Fernandes et al., 2000).

Upon acute viral infection, virus-specific memory CTL quickly produce IFN-γ. However, around 18 h after infection the number of IFN-γ producing CTL drops concomitantly with the upregulation of inhibitory receptors. It has been suggested that the decrease in the synthesis of IFN-γ by CTL is an active regulatory process (Hosking et al., 2013) reminiscent of T cell exhaustion, a process also known to take place during chronic viral infections (Yi et al., 2010; Wherry, 2011).

A hallmark of T cell exhaustion is the upregulation of inhibitory receptors such as programmed death-1 (PD-1), T cell immunoglobulin mucin-3 (Tim-3), and lymphocyte activation gene-3 (Lag-3) (Freeman et al., 2000; Barber et al., 2006). Interestingly, PD-1 negatively regulates glycolysis, represses the transcriptional co-activator peroxisome proliferator-activated receptor-gamma co-activator (PGC)-1alpha (PGC-1α), which plays an important role in the regulation of carbohydrate and lipid metabolism, and impairs CTL responses (Bengsch et al., 2016).

Other anti-viral cell-mediated immune responses include NK cell cytotoxicity (Hammer et al., 2018) and neutrophil extracellular traps (NETs) (Schönrich and Raftery, 2016) (Figure 2).

Natural killer (NK) cells have anti-viral activities as they exert direct cytotoxicity on virus infected-cells, and readily produce IFN-γ. NK cells increase their glycolytic rate upon activation (Gardiner and Finlay, 2017), and disruption of glycolysis impairs NK cell-mediated responses to Cytomegalovirus (CMV), for instance (Mah et al., 2017).

Neutrophils are considered a first line of defense against pathogens. However, their role in the control of viral infections is not as clear as for other pathogens (Galani and Andreakos, 2015). It has recently been recognized that viruses can induce the release of neutrophil extracellular traps (NETs), and the mechanisms by which NETs could contribute to anti-viral immunity are emerging (Hammer et al., 2018).

Several viruses, including Hantaan virus (HTNV), H1N1 Influenza A virus (IAV), human immunodeficiency virus (HIV-1), and Respiratory Syncytial virus (RSV), directly stimulate neutrophils to release NETs (Raftery et al., 2014; Delgado-Rizo et al., 2017), and both IFN-α and IFN-γ can prime mature neutrophils to release NETs upon further stimulation (Martinelli et al., 2004; Hammer et al., 2018).

HIV-1 may also prevent the release of NETs by inducing dendritic cells to produce IL-10, which in turn suppresses the reactive oxygen species (ROS)-dependent release of NETs (Saitoh et al., 2012; Hammer et al., 2018).

The Dengue virus serotype-2 (DENV-2) down-modulates the phorbol 12- myristate 13- acetate-(PMA) induced release of NETs, and it has been proposed that one of the mechanisms for this is the interference with the mobilization of the glucose transporter glut-1 to the cell membrane and consequently with the glucose uptake (Moreno-Altamirano et al., 2015).

NETs may prevent virus spreading by being trapped by electrostatic attraction or be inactivated by molecules associated with NETs, such as myeloperoxidase and α-defensins (Saitoh et al., 2012; Hammer et al., 2018).

Antibodies are also important anti-viral effectors (Figure 2), and whereas cytotoxic lymphocytes can eliminate infected cells, antibodies are capable of both eliminating infected cells and neutralizing viruses, thereby preventing cell infection. The production of protective antibodies over prolonged periods constitutes a first line of defense against reinfection and, therefore, survival of antibody-producing plasma cells is determinant (Dörner and Radbruch, 2007). It is now known that plasma cell longevity is dependent on enhanced glut-1 expression and glucose uptake, mitochondria pyruvate import and spare respiratory capacity, and that nutrient uptake and catabolism distinguish plasma cell subsets with different lifespans and rates of secreted antibodies (Lam et al., 2016, 2018).

Taken together, it emerges that the activity of immune system cells is dependent on cell metabolism and that viruses could target cell metabolism to evade anti-viral immune responses. The next sections explore some specific mechanisms by which viruses may interfere with cell metabolism.

Mitochondrial Anti-Viral Signaling (MAVS) and Virus Subversion of MAVS

Mitochondria constitute a metabolic hub, so if a virus is to take control of host metabolism, targeting mitochondria is perhaps the best way.

In 2005 Seth et al. reported the identification of a new protein essential for the activation of the transcription factors NFκB and IRF3 by RNA viruses. They named the protein MAVS and showed that this contains a C-terminal transmembrane domain that targets the mitochondrial outer membrane. Strikingly, they found that this transmembrane domain and the targeting to mitochondria are essential for MAVS signaling, opening a new avenue of research in which mitochondria took center stage in antiviral immunity (Seth et al., 2005).

In non-stimulated cells, NFκB is located in the cytoplasm, associated with its inhibitor IκBα. Upon stimulation with viruses, other pathogens or cytokines, the IκB kinase (IKK) is activated, leading to the phosphorylation of IκBα and its subsequent ubiquitination and proteasomal degradation. NFκB is then released and translocated to the nucleus, where it activates immune and inflammatory genes (Silverman and Maniatis, 2001; Seth et al., 2005).

IRF3 is located in the cytoplasm of non-stimulated cells, and following viral or other pathogen infection it becomes phosphorylated by TANK-binding kinase 1 (TBK1) and IKK kinases, allowing the formation of homodimers that can translocate into the nucleus and activate the synthesis of IFN-β, acting in synergy with NFκB (Yoneyama et al., 2002; Fitzgerald et al., 2003; Hiscott et al., 2003; Seth et al., 2005).

IRF7 can also be phosphorylated by TBK1 and IKK (tenOever et al., 2004), leading to the production of interferon-α (Honda et al., 2005; Seth et al., 2005). NFκB and IRFs are activated by RNA viruses as well as by other pathogens.

The entry of RNA viruses to the cells produces double-stranded RNA intermediates, which can be recognized by host cell pathogen recognition receptors (PRRs) including TLR -3, -7, -8, and -9 (Akira and Takeda, 2004; Seth et al., 2005).

The receptor Retinoic Acid-Induced Gene I (RIG-1) recognizes intracellular dsRNA and the interaction of viral RNA with RIG-1 leads to a change in its conformation, which then activates NFκB and IRF3 (Yoneyama et al., 2002; Sumpter et al., 2005).

The melanoma differentiation-associated gene 5 (MDA5) is a RIG-I-like protein involved in dsRNA signaling and apoptosis (Kovacsovics et al., 2002; Seth et al., 2005).

In 2011, Koshiba (Koshiba, 2013) demonstrated that mitochondrial fusion and mitochondrial membrane potential (Δψm) are required for MAVS-mediated signaling. They showed that the deletion-targeting of mitofusin 1 (Mfn1) and mitofusin 2 (Mfn2), two molecules involved in mitochondrial fusion, prevented cells from producing interferons and pro-inflammatory cytokines in response to viral infection. This resulted in increased viral replication along with a reduced Δψm, correlating with a reduced antiviral response. Interestingly, the reduction in Δψm did not affect the activation of IRF3, which acts downstream of MAVS, suggesting that Δψm and MAVS are coupled at the same stage in the RIG-1-like Receptor (RLR) signaling pathway (Koshiba, 2013).

In addition to mitochondria, MAVS are also found in peroxisomes and mitochondrial-associated membranes (MAMs) (Seth et al., 2005; Vazquez and Horner, 2015).

A natural target for the subversion of IFN type I-mediated antiviral response is the MAVS protein (Table 1). As an example, the influenza A virus encodes a protein called PB1-F2, which inhibits the induction of type I interferon at the level of the MAVS (Varga et al., 2012). PB1-F2 is an 87–90-amino-acid-long protein with a serine at position 66 (66S), which accounted for the virulence of the Spanish and avian flu pandemic viruses (H1N1 and H5N1, respectively). Interestingly, PB1-F2 66S has a higher affinity for MAVS than PB1-F2 66N, and more efficiently affects the Δψm than the wild-type PB1-F2 (Conenello et al., 2007).

Table 1.

Viruses that subvert MAVS.

Virus Viral proteins Effect References
Influenza A virus (IAV) PB1-F2 Inhibition of type I IFN at the level of MAVS Conenello et al., 2007
Influenza A virus H1N1(1918) and H5N1 PB1-F2 66S, PB1-F2 66N Disruption of mitochondrial membrane potential and type I IFN response Conenello et al., 2007
Hepatitis C virus (HCV) NS3/4A Inhibition of type I IFN response by cleaving of MAVS Meylan et al., 2005
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Other viruses, such as hepatitis C virus (HCV), induce the cleavage of MAVS from the outer membrane of mitochondria, reducing the interferon-producing response. In this case, the NS3/4A protein cleaves MAVS at cysteine 508 (Meylan et al., 2005; Bender et al., 2015; Vazquez and Horner, 2015).

Another family of pattern recognition receptors contain a nucleotide-binding and oligomerization domain (NOD) and is called the NLR (NOD-like receptor) family. NOD2 facilitates the activation of IRF3 and the synthesis of type I IFN in response to single-stranded RNA. Interestingly, the activation of NOD2 is dependent on MAVS (Sabbah et al., 2009; Moreira and Zamboni, 2012).

Recently, NLRX1 (also known as NOD5, NOD9, or NOD26), a member of the NLR family that localizes to the outer mitochondrial membrane, was shown to mediate MAVS degradation, allowing HCV to evade type I IFN-mediated antiviral response (Qin et al., 2017).

cGAS-STING Anti-Viral Pathway and Its Subversion by Viruses

The cyclic guanosine monophosphate (cGMP)-adenosine monophosphate (AMP) synthase (cGAS) recognizes viral as well as bacterial double-stranded DNA (dsDNA) (Wu and Chen, 2014; Ni et al., 2018). After binding to dsDNA, cGAS catalyzes the synthesis of the second messenger cyclic guanosine monophosphate-adenosine monophosphate (cGAMP), which then binds to the stimulator of interferon genes (STING) adaptor protein on the endoplasmic reticulum (ER); STING, as a dimer, translocates from the endoplasmic reticulum to the Golgi complex, where it recruits TANK-binding kinase 1 (TBK1) which activates the transcription factors NFκB and IRF3, both of which translocate to the nucleus and induce the synthesis of type I interferons (Barber, 2015; Ni et al., 2018).

While the activation of the RIG-1-MDA5-MAVS antiviral signaling pathway clearly requires mitochondrial activity, in the form of mitochondrial dynamics and Δψm, a metabolism-related component in the cGAS-STING antiviral signaling pathway has not been explicitly identified. However, several lines of research suggest crosstalk between cGAS-STING and metabolism. Firstly, the ER has been regarded as a separate metabolic compartment on the basis that the ER luminal micro-environment is different from the cytosol, that it contains its own pool of pyridine nucleotides, and that several metabolic pathways related to carbohydrate and steroid metabolism, biotransformation, and protein processing take place in the ER (Csalaa et al., 2006); viral infections may lead to ER stress and to the unfolded protein response (UPR) (Zhang and Wang, 2012); and the mitochondrial function in cells undergoing ER stress is compromised, particularly at the level of mitochondrial membrane potential, oxygen consumption, and ATP production (Wang et al., 2011). The ER stress and UPR synergy with the cGAS-STING antiviral signaling pathway still needs to be fully elucidated (Smith, 2014).

Among the DNA viruses that activate the cGAS-STING pathway are herpes simplex virus 1 (HSV-1), vaccinia virus (VV), and murine gamma herpesvirus 68 (MHV68). Interestingly, RNA viruses such as HIV-1 generate RNA: DNA hybrids as well as dsDNA that may activate the cGAS-STING pathway (Ma and Damania, 2016; Ni et al., 2018).

Of note, dengue virus (DENV)-induced mitochondrial damage leads to mitochondrial DNA release to the cytosol, and the activation of the cGAS-STING pathway (Sun et al., 2007). Since other viruses may cause mitochondrial damage (see below) it is plausible that other RNA viruses may activate cGAS-STING through mitochondrial DNA release.

Several DNA virus-associated proteins are known to interfere with the cGAS-STING pathway, as reviewed by Ni et al. (2018), either by interfering with DNA binding to cGAS, as is the case of Kaposi's sarcoma-associated herpesvirus (KSHV), Epstein Barr virus (EBV), and murine gammaherpesvirus-68 (MHV68,γHV68) tegument protein open reading frame 52 (ORF52), and the KSHV latency-associated nuclear antigen (LANA) protein which interact with cGAS (Wu et al., 2015; Zhang et al., 2016), or by targeting STING, as is the case for the HSV-1-infected cell protein 27 (ICP27) and the UL46 protein, the KSHV viral interferon regulatory factor 1 (vIRF1), the human papillomavirus 18 (HPV18) E7 oncoprotein, the human adenovirus 5 (hAd5) E1A oncoprotein, and the Hepatitis B virus (HBV) polymerase (Lau et al., 2015; Liu et al., 2015; Ma et al., 2015; Christensen et al., 2016;Deschamps and Kalamvoki, 2017).

A more recent development in the field is the finding that some RNA viruses are also capable to interfere with the cGAS-STING pathway, subverting its anti-viral effect (Ni et al., 2018).

Finally, it has been shown that single- or double-stranded DNA may attenuate glucose metabolism, leading to ATP depletion and so constitute a metabolic barrier for viral replication. However, the mechanism seems to be dependent on the activation of adenosine monophosphate (AMP)-activated protein kinase (AMPK) and the activation of mechanistic target of rapamycin complex 1 (mTORC1) (see below), but independent of the cGAS-STING anti-viral pathway (Zheng et al., 2015).

Mitochondrial Proteins Other than MAVS as Targets of Viral Infection

Some viruses encode mitochondrial proteins, which allow them a direct functional intervention on host cells mitochondria (Table 2). In this regard, the Acanthamoeba polyphaga mimivirus (APMV), one of the largest known viruses (400 nm in its capside diameter) (La Scola et al., 2003; Monné et al., 2007), encodes a mitochondrial transport protein called VMC1 (viral mitochondrial carrier), whose function is to transport dATP and other nucleotide triphosphates (dTTP, TTP, UTP, and ADP). VMC1 can support the replication of the APMV genome by acquiring additional nucleotide triphosphates from the mitochondrial pool in exchange for cytosolic ADP (Monné et al., 2007). The APMV genome additionally encodes other five putative mitochondrial proteins (Monné et al., 2007).

Table 2.

Viruses that target other mitochondrial proteins.

Virus Viral proteins Effect References
Acantthamoeba polyphaga mimivirus (APMV) Virus mitochondrial carrier 1 (VMC1) Increase of viral replication by transporting dATP from the motochondrial pool Monné et al., 2007
Epstein Barr virus (EBV) BHRF1, BZLF1, BALF1, early Zta Increase of viral replication, prevention of B cell apoptosis, blockage of mDNA replication Cavallari et al., 2018
Hepatitis C virus (HCV) p7, NS3/4A, NS5A Disruption of mitochondrial function, cleaveage of MAVS Cavallari et al., 2018
Hepatitis C virus (HCV) Core Mitochondria depolarization, increased production of mitochondrial ROS Cavallari et al., 2018
Influenza virus (IV) PB1-F2, PB2, NS1 Modulation of viral replication, viral mRNA synthesis Cavallari et al., 2018
Herpes simplex virus-1 (HSV-1) UL 12.5 Degradation of mitochondrial DNA early during infection Cavallari et al., 2018
Herpes simplex virus-1 (HSV-1) UL 12 Generation of mature viral genomes Cavallari et al., 2018
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The Human T-cell leukemia virus type 1 (HTLV-1) causes adult T-cell leukemia/lymphoma (ATLL) and encodes an 87-amino acid protein (p13) that helps this virus to establish a persistent infection. This protein primarily accumulates in the inner mitochondrial membrane of host cells and alters mitochondrial morphology toward a more rounded shape, fragments mitochondria (mitochondrial fission), and reduces mitochondrial Ca2+ uptake (Biasiotto et al., 2010; Cavallari et al., 2018).

Several proteins encoded by Epstein Barr virus (EBV) target mitochondria, such as BHRF1 (BamHI-H right reading frame), BZLF1 (also known as Zebra protein), BALF1 (BamHI-A left frame transcript), LMP2A (Latent membrane protein), and immediate early Zta protein. BHRF1 accumulates in the outer mitochondrial membrane (OMM) of B lymphocytes, preventing apoptosis and promoting survival of EBV-infected cells, viral persistence, and replication; BHRF presents homology with the transmembrane domains of some eukaryotic Bcl-2 family members (Kvansakul et al., 2017; Cavallari et al., 2018); and BZLF1 has the capacity to interact with mtSSB (mitochondrial single-stranded DNA-binding protein), which is required for the replication of the mitochondrial genome, and partially redirects mtSSB from mitochondria to the nucleus (LaJeunesse et al., 2005; Cavallari et al., 2018). BALF1 also shares homology with Bcl-2 family members and modulates apoptosis and promotes transformation (Hsu et al., 2012; Cavallari et al., 2018). LMP2A induces mitochondrial fission by a Drp1-dependent mechanism (Pal et al., 2014; Cavallari et al., 2018), and finally, the immediate early Zta protein can also bind mtSSB in the cytoplasm, inducing its re-location to the nuclei, blocking mitochondrial DNA replication and facilitating viral replication (Wiedmer et al., 2008).

Many other viruses encode mitochondrial proteins capable of regulating a broad spectrum of mitochondrial activities, as reviewed by Cavallari et al. (2018), including the control of intracellular Ca2+, apoptosis, mitochondrial dynamics, the levels of cytochrome c oxidase III (COXIII) and COX activity, as well as cellular ROS production, and the aggregation of mitochondria near the nucleus. Others promote mitophagy and interfere with the antiviral interferon response (Wu et al., 2007; Wang and Ryu, 2010). Proteins such as KS-Bcl-2 localize in mitochondria (Gallo et al., 2017), and others such as the KSHV-encoded K7 protein localize in mitochondria as well as in the ER and nucleus (Feng et al., 2002).

The non-structural proteins p7 of HCV can modify the mitochondrial function. The p7 protein is determinant for the assembly and later release of infectious virions, it is capable to form membrane-associated hexameric ion channels, induces mitochondrial membrane depolarization, and binds to the interferon inducible protein 6–16 (IFI6-16) (Nieva et al., 2012; Madan and Bartenschlager, 2015; Qi et al., 2017); HepG2 cells that express HCV core protein have increased levels of prohibitin, a protein that regulates mitochondrial function and apoptosis (Peng et al., 2015), by reducing the levels of COX subunits I and II. Therefore, the interaction between the HCV core protein and prohibitin may interfere with the assembly of the respiratory chain, which could lead to increased production of mitochondrial ROS and viral replication (Tsutsumi et al., 2009; Ren et al., 2016). Other molecular partners for viral-encoded mitochondrial proteins are voltage-dependent anion channel 3 (VDAC3) (Rahmani et al., 2000), and heat shock protein 60 (HSP60) (Tanaka et al., 2004).

Three influenza virus proteins are known to localize into mitochondria: PB1-F2, PB2, and NS1 (Chen et al., 2001; Yamada et al., 2004; Carr et al., 2006; Tsai et al., 2017). Although PB1-F2 is dispensable for viral replication, at least in some host cells, its expression accelerates influenza virus-induced apoptosis in human monocytes through mitochondrial ANT3 (adenine nucleotide translocator 3) and VDAC1 (voltage dependent anion channel 1) (Chen et al., 2001; Zamarin et al., 2005). The PB2 protein has a key role in viral mRNA synthesis and localizes in mitochondria, where it can regulate the viability of mitochondria during infection (Carr et al., 2006). The NS1 protein is highly expressed in Influenza A virus-infected cells, and predominantly localizes in the nucleus, although it may also be found in the cytoplasm at later stages of infection (Melén et al., 2007). Although NS1 does not harbor mitochondria-targeting sequences, it has also been found in mitochondria at early times (1.5 h) post-infection (Tsai et al., 2017).

The UL12 gene of herpes simplex virus type 1 (HSV-1) encodes two distinct but related alkaline DNases through two separately promoted 3' co-terminal mRNAs, producing full-length (UL12) and amino-terminal truncated (UL12.5) proteins. UL12 localizes to the nucleus while UL12.5 is predominantly located in mitochondria, where it degrades mitochondrial DNA early during infection. Whereas nuclear-targeted UL12 produces mature viral genomes from larger genome precursors (Draper et al., 1986; Saffran et al., 2007; Corcoran et al., 2009), the role of UL12.5 is not well-defined since mitochondrial DNA degradation is not required for HSV-1 replication (Duguay et al., 2014).

Mitochondrial Dynamics and Viruses

Mitochondria constantly undergo fusion and fission depending on the cell metabolic requirements, a process that has been dubbed as mitochondrial dynamics (Mishra and Chan, 2016).

Along with being the “powerhouse” of eukaryotic cells, mitochondria are also involved in cellular innate antiviral immunity (Seth et al., 2005). Mitochondrial fusion and fission processes depend on the activity of mitofusin 1 (Mfn1), mitofusin 2 (Mfn2), and optic atrophy protein 1 (OPA1)—which promotes fusion—in addition to Dynamin-related protein 1 (Drp1)—which promotes mitochondrial fission (Mishra and Chan, 2016). There is evidence that antiviral immune responses can be regulated by mitochondrial dynamics (Arnoult et al., 2011; West et al., 2011). The close association between mitochondrial dynamics and several mitochondrial and cellular functions may suggest that mitochondrial dynamics could be a target for viruses to interfere with immune responses (Table 3). Likewise, the non-structural protein 4A (NS4A) from HCV, either alone or associated with the non-structural protein 3 (NS3), accumulates in mitochondria, altering the mitochondrial dynamics (Nomura-Takigawa et al., 2006). Infection with HIV-1 re-shapes mitochondrial distribution within the cells (Radovanović et al., 1999), while African swine fever virus (ASFV) induces the clustering of mitochondria around virus factories within infected cells, providing the local energy required for the release of virus (Rojo et al., 1998). The DENV NS2b3 protein partially cleaves Mfn1 and Mfn2, attenuating interferon responses (Yu et al., 2015), and induces mitochondrial fusion by inhibiting Drp1 activation and in turn the activation of the interferon response (Chatel-Chaix et al., 2016).

Table 3.

Viruses that disrupt mitochondrial dynamics.

Virus Viral proteins Effect References
Hepatitis C virus (HCV) NS4A, NS3 Change of mitochondria distribution Nomura-Takigawa et al., 2006
Human immunodeficiency virus-1 (HIV-1) Clustering of mitochondria Radovanović et al., 1999
African swine fever virus (ASFV) Cluster of mitochondria around virus factories, providing ATP for virus release Rojo et al., 1998
Dengue virus (DENV) NS2b3 Cleavege of Mfn1 and Mfn2, attenuation of IFN responses Yu et al., 2015
Mitochondrial fusion by inhibition of Drp1 Chatel-Chaix et al., 2016
Hepatitis B virus (HBV) HBx Mitochondrial fission, and mitochondrial injury Kim et al., 2013
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Excessive mitochondrial fission may lead to mitochondrial damage, and this may have a role in hepatitis B virus (HBV)-induced liver disease (Kim et al., 2013).

Hepatitis B virus, through its HBx protein, triggers the translocation of Drp1 to the mitochondria by stimulating the phosphorylation of Drp1 at the Ser616 residue, and on the other hand, contributes to the degradation of Mfn2, favoring mitochondrial fission and mitophagy, attenuating the virus-induced apoptosis in the process (Kim et al., 2013).

Intracellular calcium concentrations also regulate mitochondrial dynamics since the calcium-dependent phosphatase calcineurin dephosphorylates Drp1 at S637, facilitating the recruitment of Drp1 to the mitochondria and the consequent mitochondrial fission (Cereghetti et al., 2008).

Intracellular Calcium Homeostasis and Viral Infections

Intracellular calcium participates in cell signaling, mitochondrial function, and cell death (Duchen, 2000; Contreras et al., 2010), and Ca2+ uptake by mitochondria activates Krebs cycle enzymes and oxidative phosphorylation, leading to higher ATP production (Nasr et al., 2003).

Several viruses regulate host cell calcium concentrations in the cytoplasm as well as in mitochondria, allowing viral gene expression, virus replication, and the control of host cell viability (Table 4). HSV1 downregulates the uptake of Ca2+ by mitochondria along its lytic cycle, modulating virus replication (Lund and Ziola, 1985). Other viruses such as HCV target mitochondria, increasing Ca2+ concentration (Li et al., 2007; Campbell et al., 2009). Among the HCV proteins known to interfere with Ca2+ homeostasis, are the core protein, the NS5A, and the p7 protein (Gong et al., 2001; Griffin et al., 2004; Kalamvoki and Mavromara, 2004; Dionisio et al., 2009).

Table 4.

Viruses that disrupt calcium homeostasis.

Virus Viral proteins Effect References
Human T leukemia virus (HTLV-1) p13 p13 accumulates in the inner mitochondrial membrane, reduces Dym and mCa2+ uptake Biasiotto et al., 2010
Herpes simplex virus 1 (HSV1) ? Modulation of viral replication by down-regulation of Ca2+ uptake by mitochondria Lund and Ziola, 1985
Hepatitis C virus (HCV) NS5A, p7 Increase of Ca2+ concentration Gong et al., 2001; Griffin et al., 2004
Hepatitis B virus (HBV) HBx Ca2+ release from mitochondria and ER Bouchard et al., 2001
Human immunodeficiency virus-1 (HIV-1) Nef Increase in viral replication by IP3R-dependent increase of cytosolic Ca2+ Foti et al., 1999
Rotavirus NSP4 virus release by decreasing Ca2+ concentration Tian et al., 1995; Ruiz et al., 2007
Poliovirus 2BC Increase in viral gene expression and apoptosis by increse in Ca2+ concentration Aldabe et al., 1997
Coxsackievirus B3 2B Control of apoptosis and virus release by regulation of Ca2+ concentration Campanella et al., 2004
Human cytomegalovirus (HCMV) pUL37x1 Increased viral replication by mitochondria Ca2+ uptake and increased ATP Sharon-Friling et al., 2006; Bozidis et al., 2010
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?, not known.

HBV induces the mobilization of Ca2+ from mitochondria and endoplasmic reticulum to the cytoplasm through the interaction of the HBV protein X with voltage-dependent anion channels (VDAC) (Bouchard et al., 2001; Choi et al., 2005). The HIV-1 protein Nef (nuclear elongation factor) interacts with the Inositol 1,4,5-trisphosphate receptor (IP3Rs), increasing cytosolic Ca2+ concentration, promoting the transcription of virus-encoded genes and viral replication (Kinoshita et al., 1997; Foti et al., 1999). Rotavirus, through its NSP4 protein, activates phospholipase C (PLC) and the release of Ca2+ from the endoplasmic reticulum to the cytosol. However, by the end of its life cycle there is a decrease in cellular Ca2+ concentrations enabling rotavirus release (Tian et al., 1995; Ruiz et al., 2007; Díaz et al., 2008).

Poliovirus increases intracellular Ca2+ concentrations shortly after infection, increasing viral gene expression (Irurzun et al., 1995; Aldabe et al., 1997). By the end of the virus life cycle Ca2+ accumulates within mitochondria at the expense of ER stores in a mitochondrial calcium uniporter (MCU) and voltage-dependent anion channel (VDAC)-dependent process, leading to mitochondrial dysfunction and apoptosis (Brisac et al., 2010).

Enteroviruses control apoptosis through Ca2+ regulation; in this way, low levels of cytosolic Ca2+ provide the conditions for viral replication while high concentrations of cytosolic Ca2+ lead to the formation of vesicles which allow virus release (Campanella et al., 2004; Van Kuppeveld et al., 2005).

Human cytomegalovirus (HCMV) protein pUL37 × 1, also known as viral mitochondrion-localized inhibitor of apoptosis (vMIA) localizes into mitochondria and induces the transfer of ER Ca2+ into mitochondria, increasing the production of ATP and virus replication (Sharon-Friling et al., 2006; Bozidis et al., 2010).

The maturation of viral glycoproteins is dependent on both pH and intracellular Ca2+ concentrations. Ca2+ acts as a cofactor for several enzymes including glycosyl- and sulfo-transferases (Vanoevelen et al., 2007). Measles virus (MV), Dengue virus (DENV), West Nile virus (WNV), Zika virus (ZIKV), and Chikungunya virus (CHIKV) use the host calcium pump secretory pathway calcium ATPase 1 (SPCA1) for Ca2+ loading into the trans Golgi network, which activates glycosyl transferases and proteases allowing viral maturation and spreading (Hoffmann et al., 2017).

mTOR and AMPK as Metabolic Hubs and Viral Targets for Evasion

The mechanistic target of rapamycin (mTOR) and the adenosine monophosphate-activated protein kinase (AMPK) constitute an integrated metabolic sensor. High levels of ATP (high ATP/AMP ratio) activate mTORC1, resulting in enhanced nutrient-dependent protein synthesis, cell growth and proliferation, whereas low levels of ATP (low ATP/AMP and ATP/ADP ratios), a hallmark of metabolic stress (starvation, hypoxia or viral infection), lead to AMPK-mediated inhibition of mTORC1 and activation of mTORC2, which restores energy homeostasis by switching the ATP-consuming biosynthetic pathways off and the ATP-producing catabolic pathways on (Hardie et al., 2012; Saxton and Sabatini, 2017).

MTOR acts as the catalytic subunit of either of two molecular complexes known as mTOR complex 1 (mTORC1) and mTOR complex 2 (mTORC2); mTORC1 is bound to the protein Raptor (Hara et al., 2002; Kim et al., 2002) and mTORC2 is bound to the protein Rictor (Hresko and Mueckler, 2005).

MTORC1 induces metabolic reprograming from OXPHOS to glycolysis by upregulating the transcription factor hypoxia-induced factor 1α (HIF1α) and, as a result, increases the expression of several glycolytic enzymes including phospho-fructo kinase (PFK). On the other hand, mTORC2 regulates cell proliferation and survival by activating the PI3K-Akt pathway (Düvel et al., 2010; Thomanetz et al., 2013; Saxton and Sabatini, 2017). The mTORC1 complex acts downstream of Akt and, as a way of regulation, the mTORC1 substrate p70S6K suppresses mTORC2, and the mTORC1 substrate Grb10 suppresses PI3K signaling (Hsu et al., 2011; Yu et al., 2011; Saxton and Sabatini, 2017), establishing a negative feedback that balances mTORC1 and mTORC2 activities (Meade et al., 2018).

Extracellular growth factors, the cell energy status, and different stressors such as viral infection are integrated into the mTOR pathway. Not surprisingly, viruses can modulate mTOR signaling to their advantage (Le Sage et al., 2016; Saxton and Sabatini, 2017) (Table 5). HSV-1 can enhance mTORC1 activity; whereas Poliovirus, HIV-1, Sindbis virus, and CHIKV can inhibit this same complex (Martin et al., 2012).

Table 5.

Viruses that target mTOR or AMPK.

Virus Viral proteins Effect References
Herpes simplex virus 1 (HSV1) viral kinase Us3 Enhancement of mTORC1 activity Martin et al., 2012
Poliovirus (PV) Inhibition of mTORC1 activity
Human immunodeficiency virus-1 (HIV-1) Env Activation of mTORC1 activity Le Sage et al., 2016
Sindbis virus (SINV) Activation of mTORC Le Sage et al., 2016
Chikungunya virus (CHIKV) ? Controversial activation/Inhibition of mTOR Le Sage et al., 2016
Influenza A virus (IAV) NS1 Differential activation of mTORC1 and mTORC2, supports viral replication Kuss-Duerkop et al., 2017
Andes virus (ANDV) glycoprotein Gn Activation of mTOR, supports viral protein expression and replication McNulty et al., 2013
Hepatitis C virus (HCV) NS5A Activation of mTORC1 supports viral protein expression and replication Stohr et al., 2016
Poxviruses F17 Evasion of cytosolic sensing by disruption of the mTORC1-mTORC2 circuit Meade et al., 2018
Dengue virus (DENV) ? Viral replication by activation of AMPK and inhibition of mTORC1 Jordan and Randall, 2017
Zika virus (ZIKV) ? AMPK activation evokes antiviral innate responses and restricts virus replication Kumar et al., 2018
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?, not known.

Activation of mTORC1 supports viral protein expression and replication of Influenza A virus, Andes virus (ANDV), and HCV (McNulty et al., 2013; Stohr et al., 2016; Kuss-Duerkop et al., 2017). On the other hand, poxviruses are capable of evading their cytosolic sensing by means of a conserved structural protein that disrupts the mTORC1-mTORC2 regulatory circuit while maintaining the metabolic benefits of mTOR activity (Meade et al., 2018).

DENV activates AMPK, decreases the activity of mTORC1, and induces lipophagy, a process that is required for the robust DENV replication; the autophagic-mediated mobilization of lipids increases the β-oxidation in DENV-infected cells (Jordan and Randall, 2017) whereas AMPK activation evokes antiviral innate responses and restricts ZIKV replication (Kumar et al., 2018).

Can Viruses Replicate within Mitochondria?

In addition to the interaction of viral proteins with mitochondria, which modify mitochondrial function, the Alphanodavirus flock house virus (FHV) can infect yeast, insect, plant, and mammalian cells, and replicates its RNA in the mitochondrial outer membrane. Miller et al. showed that the FHV RNA-dependent RNA polymerase, required for FHV RNA replication, localizes to the outer mitochondrial membrane and by electron microscopy these authors identified 40–60 nm membrane-bound spherical structures, similar to other virus-induced membrane structures, within the mitochondrial intermembrane space of infected cells from Drosophila (Miller et al., 2001).

Concluding Remarks

This review explores how viruses may subvert immune responses by controlling host cell metabolism.

Viruses may target MAVS (RIG-I-MDA5-MAVS anti-viral pathway) interfering with RNA virus-induced type 1 interferon responses and target other mitochondrial-associated proteins, disrupting mitochondrial dynamics, mitochondrial membrane potential, and calcium handling—all of which may affect anti-viral immunity. They may also regulate the production of ATP to their advantage by interfering with mitochondrial calcium mobilization, mitochondrial enzymatic activities, and key metabolic sensors such as mTORC1, mTORC2, and AMPK. They may also induce cytotoxic T lymphocyte exhaustion, which implies metabolic reprogramming.

Viruses may also target the cGAS-STING anti-viral pathway, interfering with DNA virus-induced type I IFN responses. Since this anti-viral pathway is not directly connected with host cell metabolism (at least not in the way the RIG-I-MDA5-MAVS is), one key outstanding question is why anti-RNA viruses IFN responses are more “metabolically directed” compared to anti-DNA virus responses. Moreover, why do some RNA viruses induce the release of mitochondrial DNA and in this way recruit the RIG-I-MDA5-MAVS pathway?

In the context of HCV infection, there are at least two mechanisms accounting for the degradation of MAVS, direct cleaving by the HCV-encoded NS3/4A protein, and the NLRX1-induced proteosomal degradation. As both MAVS and NLRX1 localize in the outer mitochondrial membrane, and MAVS signaling is dependent on mitochondrial function, it remains to be determined whether NLRX1 activity is also dependent on mitochondrial function. However, it is currently known that NLRX1 regulates OXPHOS and cell integrity in a model of ischemia-reperfusion injury, and that loss of NLRX1 increases oxygen consumption and oxidative stress in epithelial cells (Stokman et al., 2017).

The role of glycolysis, β-oxidation, and oxidative phosphorylation on viral infections is continuing to emerge, but there are still outstanding questions on the role and mechanism that some metabolic intermediates may play in viral infection. For instance, dimethyl fumarate enhances the infection of cancer cell lines and human tumor biopsies with several oncolytic viruses (Selman et al., 2018), whereas ZIKV infection upregulates the enzyme cis-aconitate descarboxylase, which converts the TCA intermediate cis-aconitate to itaconate, an endogenous inhibitor of succinate dehydrogenase, inhibiting the conversion of succinate to fumarate and generating a metabolic state that restricts ZIKV replication in neurons (Daniels et al., 2019). These topics require further exploration.

On the other hand, the success of anti-viral antibody responses as well as of antibody-mediated anti-viral vaccine protection depends on plasma cell lifespan, which ultimately relies on plasma cell metabolism; something that differs from B lymphocyte metabolism (Lam et al., 2018). It would therefore be interesting to determine whether there are viruses that specifically target plasma cell metabolism, and in which case whether protecting plasma cell metabolism could be therapeutically useful in helping to support long-lasting anti-viral immune responses.

Author Contributions

MM-A and FS-G conceived and designed the review, wrote the paper, edited, and approved the final draft. SK contributed to discussions on the paper, edited, and approved the final draft.

Conflict of Interest Statement

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.

Acknowledgments

We thank Bruno Aguilar-Lopez for help with the figures. While we have tried to include all key references, we apologize to authors for not including all references due to space constraints. Current work in the Immunoregulation laboratory is being funded by Consejo Nacional de Ciencia y Tecnología (grant 284602). FS-G and MM-A are EDI, COFAA, and SNI fellows.

Glossary

Abbreviations

ACC

Acetyil-CoA carboxylase

Akt

Akt/Protein kinase B

AMP

Adenosine monophosphate

AMPK

Adenosine monophosphate-activated protein kinase

ATP

Adenosine three phosphate

2B

2B protein

2BC

2BC protein

ANT3

Adenine nucleotide translocator 3

ATLL

Adult T-cell leukemia/lymphoma

BALF1

BamH1-A left frame transcript

BHRF1

BamH1-Hright reading frame

BZLF1

Zebra protein

cGAS

cyclic guanosin monophosphate-adenosin monophosphate synthase

cGMP

cyclic guanosine monophosphate

CoA

Coenzyme A

CTL

Cytotoxic T lymphocytes

COXIII

Cytochrome c oxidase III

Δψm

Mitochondrial membrane potential

Drp1

Dynamin-related protein

dTTP

Deoxythymidine triphosphate

early Zta

early Zta protein

Env

Envelope

ER

Endoplasmic reticulum

FADH2

reduced Flavin adenin dinucleotide

FAO

Fatty acid oxidation

FHV

Flock house virus

F17

F17 protein

Grb10

Growth factor receptor bound protein 10

HBx

Hepatitis B virus x protein

HIF1α

Hypoxia-induced factor 1α

HPV 18

Human papillomavirus 18

KSHV

Kaposi's sarcoma-associated herpesvirus

HSP60

Heat shock protein 60

IFI6-16

Interferon inducible protein 6-16

IFNs

Interferons

IκBα, nuclear factor of kappa light polypeptide gene enhancer in B-cells inhibitor

alpha

IKK

IκB kinase

IL-4

Interleukin-4

IP3Rs

Inositol 1,4,5-triphosphate receptors

IRF3

Interferon regulatory factor 3

ISGs

Interferon-stimulator genes

JAK-STAT

Janus kinase-Signal transductor and activator of transcription

Lag-3

Lymphocyte activation gene-3

LANA

Latency-associated nuclear antigen

LMP2A

Latent membrane protein 2A

LPS

Lypopolysacharide

M1

Macrophage type1

M2

Macrophage type 2

MAMs

Mitochondria-associated membranes

MAVS

Mitochondrial antiviral-signaling protein

MCU

Mitochondrial calcium uniporter

MDA-5

Melanoma differentiation-associated gene 5

Mfn1

Mitofusin 1

MHV68γHV68

Murine gammaherpesvirus-68

mTORC1

mechanistic target of rapamycin complex 1

mTORC2

mechanistic target of rapamycin complex 2

mtSSB

Mitochondrial single-stranded DNA binding protein

NADPH

reduced Nicotinamide adenine dinucleotide phosphate

Nef

Nuclear elongation factor

NS

Non-structural Proteins

NETs

Neutrophyl extracellular traps

NFκB

Nuclear factor kappa B

NK

Natural killer

NLR

NOD-like receptor

NOD

Nucleotide-binding and oligomerization domain

NS1

Non-structural protein 1

NS2b3

Non-structural protein 2b3

OMM

outer mitochondrial membrane

OPA1

Optic atrophy protein 1

ORF52

Open reading frame 52

OXPHOS

Oxidative phosphorylation

PB1-F2

PB1-F2 protein

PB1-F2 66S, PB1-F2 protein, serine 66 PB1-F2 66N, PB1-F2 protein

asparagine 66

PB2

PB2 protein

PD-1

Programmed death-1

PFK

Phosphofructokinase

PGC-1a

Peroxisome proliferator-activated receptor-gamma coactivator-1alpha

PI3K

phosphatidylinositol 3-kinase

PLC

Phospholipase C

PMA

Phorbol 12-myristate 13-acetate

PPP

pentose phosphate pathway

PRRs

Pattern recognition receptors

p7

protein 7

p13

protein 13

P70S6K

Ribosomal protein S6 kinase beta-1

RIG-1

Retinoic acid-induced gene 1

RLR

RIG-1-like Receptor

ROS

Reactive Oxygen Species

SPCA 1

Secretory pathway calcium ATPase 1

STING

Stimulator of interferon genes

TBK1

TANK binding kinase 1

TCA

Tricarboxylic acid

Tim-3

T cell immunoglobulin mucin-3

TLRs

Toll like receptors

TTP

thymidine triphosphate

UL 12

full length UL 12 protein

UL 12. 5

N-terminally truncated UL 12 protein

UPR

Unfolded protein response

UTP

Uridine triphosphate

VV

Vaccinia virus

VDAC3, Voltage dependent anion channel 3;VMC1

Viral mitochondrial carrier 1

vIRF1

viral Interferon regulatory factor 1

vMIA

viral mitochondrial-localized inhibitor of apoptosis. Note: Other viruses abbreviations are indicated in Tables 15.

References

  1. Akira S., Takeda K. (2004). Toll-like receptor signalling. Nat. Rev. Immunol. 4,499–511. 10.1038/nri1391 [DOI] [PubMed] [Google Scholar]
  2. Aldabe R., Irurzun A., Carrasco L. (1997). Poliovirus protein 2BC increase cytosolic free calcium concentrations. J. Virol. 71, 6214–6217. [DOI] [PMC free article] [PubMed] [Google Scholar]
  3. Arnoult D., Soares F., Tattoli S., Girardin S. E. (2011). Mitochondria in innate immunology. EMBO Rep. 12, 901–910. 10.1038/embor.2011.157 [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Barber D. L., Wherry E. J., Masopust D., Zhu B., Allison J. P., Sharpe A. H., et al. (2006). Restoring function in exhausted CD8 T cells during chronic viral infection. Nature 439, 682–687. 10.1038/nature04444 [DOI] [PubMed] [Google Scholar]
  5. Barber G. N. (2015). STING: infection, inflammation and cancer. Nat. Rev. Immunol. 15, 760–770. 10.1038/nri3921 [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Bender S., Reuter A., Eberle F., Einhorn E., Binder M., Bartenschlager R. (2015). Activation of type I and III interferon response by mitochondrial and peroxisomal MAVS and inhibition by hepatitis C virus. PLoS Pathog. 11:e1005264. 10.1371/journal.ppat.1005264 [DOI] [PMC free article] [PubMed] [Google Scholar]
  7. Bengsch B., Johnson A. L., Kurachi M., Odorizzi P. M., Pauken K. E., Atanasio J., et al. (2016). Bioenergetic insufficiencies due to metabolic alterations regulated by PD-1 are an early driver of CD8+ T Cell Exhaustion. Immunity 45,358–373. 10.1016/j.immuni.2016.07.008 [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Bhutia Y. D., Ganapathy V. (2016). Glutamine transporters in mammalian cells and their functions in physiology and cancer. Biochim. Biophys. Acta 1863, 2531–2539. 10.1016/j.bbamcr.2015.12.017 [DOI] [PMC free article] [PubMed] [Google Scholar]
  9. Biasiotto R., Aguiari P., Rizzuto R., Pinton P., D'Agostino D. M., Ciminale V. (2010). The p13 protein of human T cell leukemia virus type 1 (HTLV-1) modulates mitochondrial membrane potential and calcium uptake. Biochim. Biophys. Acta 1797, 945–951. 10.1016/j.bbabio.2010.02.023 [DOI] [PubMed] [Google Scholar]
  10. Bouchard M. J., Wang L. H., Schneider R. J. (2001). Calcium signaling by HBx protein in hepatitis B virus DNA replication. Science 294, 2376–2378. 10.1126/science.294.5550.2376 [DOI] [PubMed] [Google Scholar]
  11. Bozidis P., Williamson C. D., Wong D. S., Colberg-Poley A. M. (2010). Trafficking of UL37 proteins into mitochondrion-associated membranes during permissive human cytomegalovirus infection. J. Virol. 84, 7898–7903. 10.1128/JVI.00885-10 [DOI] [PMC free article] [PubMed] [Google Scholar]
  12. Brisac C., Téoul,é F, Autret A., Pelletier I., Colbère-Garapin F., Brenner C., et al. (2010). Calcium flux between the endoplasmatic reticulum and mitochondrion contributes to poliovirus-induced apoptosis. J. Virol. 84, 12226–12235. 10.1128/JVI.00994-10 [DOI] [PMC free article] [PubMed] [Google Scholar]
  13. Buck M. D., Sowell R. T., Kaech S. M., Pearce E. L. (2017). Metabolic instruction of immunity. Cell 169, 570–586. 10.1016/j.cell.2017.04.004 [DOI] [PMC free article] [PubMed] [Google Scholar]
  14. Campanella M., de Jong A. S., Lanke K. W., Melchers W. J., Willems P. H., Pinton P., et al. (2004). The coxsackievirus 2B protein suppresses apoptotic host cell responses by manipulating intracellular Ca2+ homeostasis. J. Biol. Chem. 279, 18440–18450. 10.1074/jbc.M309494200 [DOI] [PubMed] [Google Scholar]
  15. Campbell R. V., Yang Y., Wang T., Rachamallu A., Li Y., Watowich S. J., et al. (2009). Effects of hepatitis C core protein on mitochondrial electron transport and production of reactives oxygen species. Methods Enzymol. 456, 363–380. 10.1016/S0076-6879(08)04420-0 [DOI] [PMC free article] [PubMed] [Google Scholar]
  16. Carr S. M., Carnero E., Garcia-Sastre A., Brownlee G. G., Fodor E. (2006). Characterization of a mitocondrial-targeting signal in the PB2 protein of influenza viruses. Virology 344, 492–508. 10.1016/j.virol.2005.08.041 [DOI] [PubMed] [Google Scholar]
  17. Cavallari I., Scattolin G., Silic-Benussi M., Raimondi V., D'Agostino D. M., Ciminale V. (2018). Mitochondrial proteins coded by human tumor viruses. Front Microbiol. 9:81. 10.3389/fmicb.2018.00081 [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Cereghetti G. M., Stangherlin A., Martins de Brito O., Chang C. R., Blackstone C., Bernardi P., et al. (2008). Dephosphorylation by calcineurin regulates translocation of Drp1 to mitochondria. Proc. Natl. Acad. Sci. U.S.A. 105, 15803–15808. 10.1073/pnas.0808249105 [DOI] [PMC free article] [PubMed] [Google Scholar]
  19. Chatel-Chaix L., Cortese M., Romero-Brey I., Bender S., Neufeldt C. J., Fischl W., et al. (2016). Dengue virus perturbs mitochondrial morphodynamics to dampen innate immune responses. Cell Host Microbe 14, 342–356. 10.1016/j.chom.2016.07.008 [DOI] [PMC free article] [PubMed] [Google Scholar]
  20. Chen W., Calvo P. A., Malide D., Gibbs J., Schubert U., Bacik I., et al. (2001). A novel influenza A virus mitochondrial protein that induces cell death. Nat. Med. 7, 1306–1312. 10.1038/nm1201-1306 [DOI] [PubMed] [Google Scholar]
  21. Choi Y., Park S. G., Yoo J. H., Jung G. (2005). Calcium ions affect the hepatitis B virus core assembly. Virology 332, 454–463. 10.1016/j.virol.2004.11.019 [DOI] [PubMed] [Google Scholar]
  22. Christensen M. H., Jensen S. B., Miettinen J. J, Luecke S., Prabakaran T., Reinert L. S., et al. (2016). HSV-1 ICP27 targets the TBK1-activated STING signalsome to inhibit virus-induced type I IFN expression. EMBO J. 35, 1385–1399. 10.15252/embj.201593458 [DOI] [PMC free article] [PubMed] [Google Scholar]
  23. Conenello G. M., Zamarin D., Perrone L. A., Tumpey T., Palese P. (2007). A single mutation in the PB1-F2 of H5N1 (HK/97) and 1918 influenza A viruses contributes to increased virulence. PLoS Pathog. 4, 1414–1421. 10.1371/journal.ppat.0030141 [DOI] [PMC free article] [PubMed] [Google Scholar]
  24. Contreras L., Drago I., Zampese E., Pozzan T. (2010). Mitochondria: the calcium connection. Biochim. Biophys. Acta 1797, 607–618. 10.1016/j.bbabio.2010.05.005 [DOI] [PubMed] [Google Scholar]
  25. Corcoran J. A., Saffran H. A., Duguay B. A., Smiley J. R. (2009). Herpes simplex virus UL12.5 targets mitochondria through a mitochondrial localization sequence proximal to the N terminus. J. Virol. 83, 2601–2610. 10.1128/JVI.02087-08 [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Csalaa M., Bánhegyib G., Benedettib A. (2006). Endoplasmic reticulum: a metabolic compartment. FEBS Lett. 580, 2160–2165. 10.1016/j.febslet.2006.03.050 [DOI] [PubMed] [Google Scholar]
  27. Daniels B. P., Kofman S. B., Smith J. R., Norris G. T., Snyder A. G., Kolb J. P., et al. (2019). The nucleotide sensor ZBP1 and kinase RIPK3 induce the enzyme IRG1 to promote an antiviral metabolic state in neurons. Immunity 50, 64–76.e4. 10.1016/j.immuni.2018.11.017 [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Darnell J. E., Jr., Kerr I. M., Stark G. R. (1994). Jak-STAT pathways and transcriptional activation in response to IFNs and other extracellular signaling proteins. Science 264, 1415–1421. 10.1126/science.8197455 [DOI] [PubMed] [Google Scholar]
  29. DeBerardinis R. J., Cheng T. (2010). Q's next: the diverse functions of glutamine in metabolism, cell biology and cancer. Oncogene 29, 313–324. 10.1038/onc.2009.358 [DOI] [PMC free article] [PubMed] [Google Scholar]
  30. Delgado-Rizo V., Martínez-Guzmán M. A., I-iguez-Gutierrez L., García-Orozco A., Alvarado-Navarro A., Fafutis-Morris M. (2017). Neutrophil extracellular traps and its implications in inflammation: an overview. Front. Immunol 8:81. 10.3389/fimmu.2017.00081 [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Deschamps T., Kalamvoki M. (2017). Evasion of the STING DNA-sensing pathway by VP11/12 of herpes simplex virus 1. J. Virol. 91, e00535–e00517. 10.1128/JVI.00535-17 [DOI] [PMC free article] [PubMed] [Google Scholar]
  32. Díaz Y., Chemello M. E., Pe-a F., Aristimu-o O. C, Zambrano J. L., Rojas H., et al. (2008). Expression of nonstructural rotavirus protein NSP4 Mimics Ca2+ homeostasis changes induced by rotavirus infection in cultured cells. J. Virol. 82, 11331–11343. 10.1128/JVI.00577-08 [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Dionisio N., Garcia-Mediavilla M. V., Sanchez-Campos S., Majano P. L., Benedicto I., Rosado J. A., et al. (2009). Hepatitis C virus NS5A and core proteins induce oxidative stress-mediated calcium signaling alterations in hepatocytes. J. Hepatol. 50, 872–882. 10.1016/j.jhep.2008.12.026 [DOI] [PubMed] [Google Scholar]
  34. Dörner T., Radbruch A. (2007). Antibodies and B cell memory in viral immunity. Immunity 27, 384–392. 10.1016/j.immuni.2007.09.002 [DOI] [PubMed] [Google Scholar]
  35. Draper K. G., Devi-Rao G., Costa R. H., Blair E. D., Thompson R. L., Wagner E. K. (1986). Characterization of the genes encoding herpes simplex virus type 1 and type 2 alkaline exonucleases and overlapping proteins. J. Virol. 57, 1023–1036. [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. Duchen M. R. (2000). Mitochondria and calcium: from cell signalling to cell death. J. Physiol. 529, 57–68. 10.1111/j.1469-7793.2000.00057.x [DOI] [PMC free article] [PubMed] [Google Scholar]
  37. Duguay B. A., Saffran H. A., Ponomarev A., Duley S. A., Eaton H. E., Smiley J. R. (2014). Elimination of mitochondrial DNA is not required for herpes simplex virus 1 replication. J. Virol. 88, 2967–2976. 10.1128/JVI.03129-13 [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Düvel K., Yecies J. L., Menon S., Raman P., Lipovsky A. I., Souza A. L., et al. (2010). Activation of a metabolic gene regulatory network downstream of mTOR complex 1. Mol. Cell. 39, 171–183. 10.1016/j.molcel.2010.06.022 [DOI] [PMC free article] [PubMed] [Google Scholar]
  39. Feng P., Park J., Lee B. S., Lee B. S. H., Bram R. J., Jung J. U. (2002). Kaposi's sarcoma-associated herpesvirus mitochondrial K7 protein targets a cellular calcium-modulating cyclophilin ligand to modulate intracellular calcium concentration and inhibit apoptosis. J. Virol. 76, 11491–11504. 10.1128/JVI.76.22.11491-11504.2002 [DOI] [PMC free article] [PubMed] [Google Scholar]
  40. Fitzgerald K. A., McWhirter S. M., Faia K. L., Rowe D. C., Latz E., Golenbock D. T., et al. (2003). IKKepsilon and TBK1 are essential components of the IRF3 signaling pathway. Nat. Immunol. 4, 491–496. 10.1038/ni921 [DOI] [PubMed] [Google Scholar]
  41. Foti M., Cartier L., Piguet V., Lew D. P., Carpentier J. L., Trono D., et al. (1999). The HIV Nef protein alters Ca2+ signaling in myelomonocytic cells through SH3- mediated protein-protein interactions. J. Biol. Chem. 274, 34765–34772. 10.1074/jbc.274.49.34765 [DOI] [PubMed] [Google Scholar]
  42. Frauwirth K. A., Riley J. L., Harris M. H., Parry R. V., Rathmell J. C., Plas D. R., et al. (2002). The CD28 signaling pathway regulates glucose metabolism. Immunity 16, 769–777. 10.1016/S1074-7613(02)00323-0 [DOI] [PubMed] [Google Scholar]
  43. Freeman G. J., Long A. J., Iwai Y., Bourque K., Chernova T., Nishimura H., et al. (2000). Engagement of the Pd-1 immunoinhibitory receptor by a novel B7 family member leads to negative regulation of lymphocyte activation. J. Exp. Med. 192, 1027–1034. 10.1084/jem.192.7.1027 [DOI] [PMC free article] [PubMed] [Google Scholar]
  44. Galani I. E., Andreakos E. (2015). Neutrophils in viral infections: current concepts and caveats. J. Leukoc. Biol. 98, 557–564. 10.1189/jlb.4VMR1114-555R [DOI] [PubMed] [Google Scholar]
  45. Gallo A., Lampe M., Günther T., Brune W. (2017). The viral Bcl-2 homologs of kaposi's sarcoma-associated herpesvirus and rhesus rhadinovirus share an essential Role for viral replication. J. Virol. 91, e01875–e01816. 10.1128/JVI.01875-16 [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Ganeshan K., Chawla A. (2014). Metabolic regulation of immune responses. Annu Rev Immunol. 32, 609–634. 10.1146/annurev-immunol-032713-120236 [DOI] [PMC free article] [PubMed] [Google Scholar]
  47. Gardiner C. M., Finlay D. K. (2017). What fuels natural killers? metabolism and NK cell responses. Front. Immunol. 8:367. 10.3389/fimmu.2017.00367 [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. Gong G., Waris G., Tanveer R., Siddiqui A. (2001). Human hepatitis C virus NS5A protein alters intracellular calcium levels, induces oxidative stress, and activates STAT-3 and NF- B. Proc. Natl. Acad. Sci. U.S.A. 98, 9599–9604. 10.1073/pnas.171311298 [DOI] [PMC free article] [PubMed] [Google Scholar]
  49. Griffin S. D. C., Harvey R., Clarke D. S., Barclay W. S., Harris M., Rowlands D. J. (2004). A conserved basic loop in hepatitis C virus p7 protein is required for amantadine-sensitive ion channel activity in mammalian cells but is dispensable for localization to mitochondria. J. Gen. Virol. 85, 451–461. 10.1099/vir.0.19634-0 [DOI] [PubMed] [Google Scholar]
  50. Hammer Q., Rückert T., Romagnani C. (2018). Natural killer cell specificity for viral infections. Nat. Immunol. 19, 800–808. 10.1038/s41590-018-0163-6 [DOI] [PubMed] [Google Scholar]
  51. Hara K., Maruki Y., Long X., Yoshino K., Oshiro N., Hidayat S., et al. (2002). Raptor, a binding partner of target of rapamycin (TOR), mediates TOR action. Cell 110, 177–189. 10.1016/S0092-8674(02)00833-4 [DOI] [PubMed] [Google Scholar]
  52. Hardie D. G., Ross F. A., Hawley S. A. (2012). AMPK: a nutrient and energy sensor that maintains energy homeostasis. Nat. Rev. Mol. Cell Biol. 13, 251–262. 10.1038/nrm3311 [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Hiscott J., Grandvaux N., Sharma S., Tenoever B. R., Servant M. J., Lin R. (2003). Convergence of the NF-kappaB and interferon signaling pathways in the regulation of antiviral defense and apoptosis. Ann. N. Y. Acad. Sci. 1010, 237–248. 10.1196/annals.1299.042 [DOI] [PubMed] [Google Scholar]
  54. Hoffmann H. H., Schneider W. M., Blomen V. A., Scull M. A., Hovnanian A., Brummelkamp T. R., et al. (2017). Diverse viruses require the calcium transporter SPCA1 for maturation and spread. Cell Host Microbe 22, 460–470. 10.1016/j.chom.2017.09.002 [DOI] [PMC free article] [PubMed] [Google Scholar]
  55. Honda K., Yanai H., Negishi H., Asagiri M., Sato M., Mizutani T., et al. (2005). IRF-7 is the master regulator of type-I interferon-dependent immune responses. Nature 434, 772–777. 10.1038/nature03464 [DOI] [PubMed] [Google Scholar]
  56. Hosking M. P., Flynn C. T., Botten J., Whitton J. L. (2013). CD8+ memory T cells appear exhausted within hours of acute virus infection. J. Immunol. 191, 4211–4222. 10.4049/jimmunol.1300920 [DOI] [PMC free article] [PubMed] [Google Scholar]
  57. Hresko R. C., Mueckler M. (2005). mTOR.RICTOR is the Ser473 kinase for Akt/protein kinase B in 3T3-L1 adipocytes. J. Biol. Chem. 280, 40406–40416. 10.1074/jbc.M508361200 [DOI] [PubMed] [Google Scholar]
  58. Hsu P. P., Kang S. A., Rameseder J., Zhang Y., Ottina K. A., Lim D., et al. (2011). The mTOR-regulated phosphoproteome reveals a mechanism of mTORC1 mediated inhibition of growth factor signaling. Science 332, 1317–1322. 10.1126/science.1199498 [DOI] [PMC free article] [PubMed] [Google Scholar]
  59. Hsu W. L., Chung P. J., Tsai M. H., Chang C. L., Liang C. L. (2012). A role for Epstein-Barr viral BALF1 in facilitating tumor formation and metastasis potential. Virus Res. 163, 617–627 10.1016/j.virusres.2011.12.017 [DOI] [PubMed] [Google Scholar]
  60. Irurzun A., Arroyo J., Alvarez A., Carrasco L. (1995). Enhanced intracellular calcium concentration during poliovirus infection. J. Virol. 69, 5142–5146. [DOI] [PMC free article] [PubMed] [Google Scholar]
  61. Jellusova J., Rickert R. C. (2016). The PI3K pathway in B cell metabolism. Crit. Rev. Biochem. Mol. Biol. 51, 359–378. 10.1080/10409238.2016.1215288 [DOI] [PMC free article] [PubMed] [Google Scholar]
  62. Jordan T. X., Randall G. (2017). Dengue virus activates the AMP kinase-mTOR axis to stimulate a proviral lipophagy. J. Virol. 91, e02020–e02016. 10.1128/JVI.02020-16 [DOI] [PMC free article] [PubMed] [Google Scholar]
  63. Kalamvoki M., Mavromara P. (2004). Calcium-dependent calpain proteases are implicated in processing of the hepatitis C virus NS5A protein. J. Virol. 78, 11865– 11878. 10.1128/JVI.78.21.11865-11878.2004 [DOI] [PMC free article] [PubMed] [Google Scholar]
  64. Kim D. H., Sarbassov D. D., Ali S. M., King J. E., Latek R. R., Erdjument-Bromage H., et al. (2002). mTOR interacts with raptor to form a nutrient-sensitive complex that signals to the cell growth machinery. Cell 110, 163–175. 10.1016/S0092-8674(02)00808-5 [DOI] [PubMed] [Google Scholar]
  65. Kim S. J., Khan M., Quan J., Till A., Subramani S., Siddiqui A. (2013). Hepatitis B virus disrupts mitochondrial dynamics: induces fission and mitophagy to attenuate apoptosis. PLoS Pathog. 9:e1003722. 10.1371/journal.ppat.1003722 [DOI] [PMC free article] [PubMed] [Google Scholar]
  66. Kinoshita S., Su L., Amano M., Timmerman L. A., Kaneshima H., Nolan G. P. (1997). The T cCell activation factor NFATc positively regulates HIV-1 replication and gene expression in T cells. Immunity 6, 235–244. 10.1016/S1074-7613(00)80326-X [DOI] [PubMed] [Google Scholar]
  67. Koshiba T. (2013). Mitochondrial-mediated antiviral immunity. Biochim. Biophys. Acta 1833, 225–232. 10.1016/j.bbamcr.2012.03.005 [DOI] [PubMed] [Google Scholar]
  68. Kovacsovics M., Martinon F., Micheau O., Bodmer J. L., Hofmann K., Tschopp J., et al. (2002). Overexpression of Helicard, a CARD-containing helicase cleaved during apoptosis, accelerates DNA degradation. Curr Biol. 12, 838–843. 10.1016/S0960-9822(02)00842-4 [DOI] [PubMed] [Google Scholar]
  69. Kumar A., Kumar Singh P., Giri S. (2018). AMP-activated kinase (AMPK) promotes innate immunity and antiviral defense against Zika virus induced ocular infection. J. Immunol. 200(Suppl.), 50.14. [Google Scholar]
  70. Kuss-Duerkop S. K., Wang J., Mena I., White K., Metreveli G., Sakthivel R., et al. (2017). Influenza virus differentially activates mTORC1 and mTORC2 signaling to maximize late stage replication. PLoS Pathog. 13:e1006635. 10.1371/journal.ppat.1006635 [DOI] [PMC free article] [PubMed] [Google Scholar]
  71. Kvansakul M., Caria S., Hinds M. G. (2017). The Bcl-2 family in host-virus interactions. Viruses 9:E290. 10.3390/v9100290 [DOI] [PMC free article] [PubMed] [Google Scholar]
  72. La Scola B., Audic S., Robert C., Jungang L., de Lamballerie X., Drancourt M., et al. (2003). A giant virus in amoebae. Science 299:2033. 10.1126/science.1081867 [DOI] [PubMed] [Google Scholar]
  73. LaJeunesse D. R., Brooks K., Adamson A. L. (2005). Epstein-Barr virus immediate-early proteins BZLF1 and BRLF1 alter mitochondrial morphology during lytic replication. Biochem. Biophys. Res. Commun. 333, 438–442. 10.1016/j.bbrc.2005.05.120 [DOI] [PubMed] [Google Scholar]
  74. Lam W. Y., Becker A. M., Kennerly K. M., et al. (2016). Mitochondrial pyruvate import promotes long-term survival of antibody-secreting plasma cells. Immunity 45, 60–73. 10.1016/j.immuni.2016.06.011 [DOI] [PMC free article] [PubMed] [Google Scholar]
  75. Lam W. Y., Jash A., Yao C. H., D'Souza L., Wong R., Nunley R. M., et al. (2018). Metabolic and transcriptional modules independently diversify plasma cell lifespan and function. Cell Rep. 24, 2479–2492.e6. 10.1016/j.celrep.2018.07.084 [DOI] [PMC free article] [PubMed] [Google Scholar]
  76. Lau L., Gray E. E., Brunette R. L., Stetson D. B. (2015). DNA tumor virus oncogenes antagonize the cGAS-STING DNA-sensing pathway. Science 350, 568–571. 10.1126/science.aab3291 [DOI] [PubMed] [Google Scholar]
  77. Le Sage V., Cinti A., Amorim R., Mouland A. J. (2016). Adapting the stress response: viral subversion of the mTOR signaling pathway. Viruses 8:152. 10.3390/v8060152 [DOI] [PMC free article] [PubMed] [Google Scholar]
  78. Li Y., Boehning D. F., Qian T., Popov V. L., Weinman S. A. (2007). Hepatitis C virus core protein increases mitochondrial ROS production by stimulation of Ca2+ uniporter activity. FASEB J. 21, 2474–2485. 10.1096/fj.06-7345com [DOI] [PubMed] [Google Scholar]
  79. Liu Y., Li J., Chen J., Li Y., Wang W., Du X., et al. (2015). Hepatitis B virus polymerase disrupts K63-linked ubiquitination of STING to block innate cytosolic DNA-sensing pathways. J. Virol. 89, 2287–2300. 10.1128/JVI.02760-14 [DOI] [PMC free article] [PubMed] [Google Scholar]
  80. Lund K., Ziola B. (1985). Cell sonicates used in the analysis of how measles and herpes simplex type 1 virus infections influence Vero cell mitochondrial calcium uptake. Can. J. Biochem. Cell Biol. 63, 1194–1197. 10.1139/o85-149 [DOI] [PubMed] [Google Scholar]
  81. Ma Z., Damania B. (2016). The cGAS-STING defense pathway and its counteraction by viruses. Cell Host Microbe 19,150–158. 10.1016/j.chom.2016.01.010 [DOI] [PMC free article] [PubMed] [Google Scholar]
  82. Ma Z., Jacobs S. R., West J. A., Stopford C., Zhang Z., Davis Z., et al. (2015). Modulation of the cGAS-STING DNA sensing pathway by gammaherpesviruses. Proc. Natl. Acad. Sci. U.S.A. 112, E4306–E4315. 10.1073/pnas.1503831112 [DOI] [PMC free article] [PubMed] [Google Scholar]
  83. Madan V., Bartenschlager R. (2015). Structural and functional properties of the hepatitis C virus p7 viroporin. Viruses 7, 4461–4481. 10.3390/v7082826 [DOI] [PMC free article] [PubMed] [Google Scholar]
  84. Mah A. Y., Rashidi A., Keppel M. P., Saucier N., Moore E. K., Alinger J. B., et al. (2017). Glycolytic requirement for NK cell cytotoxicity and cytomegalovirus control. JCI Insight 2:e95128. 10.1172/jci.insight.95128 [DOI] [PMC free article] [PubMed] [Google Scholar]
  85. Martin S., Saha B., Riley J. L. (2012). The battle over mTOR: an emerging theatre in host–pathogen immunity. PLoS Pathog. 8, e1002894–e1002895. 10.1371/journal.ppat.1002894 [DOI] [PMC free article] [PubMed] [Google Scholar]
  86. Martinelli S., Urosevic M., Daryadel A., Oberholzer P. A., Baumann C., Fey M. F., et al. (2004). Induction of genes mediating interferon-dependent extracellular trap formation during neutrophil differentiation. J. Biol. Chem. 279, 44123–44132. 10.1074/jbc.M405883200 [DOI] [PubMed] [Google Scholar]
  87. McNab F., Mayer-Barber K., Sher A., Wack A., O'Garra A. (2015). Type I interferons in infectious disease. Nat. Rev. Immunol. 15, 87–103. 10.1038/nri3787 [DOI] [PMC free article] [PubMed] [Google Scholar]
  88. McNulty S., Flint M., Nichol S. T., Spiropoulou C. F. (2013). Host mTORC1 signaling regulates andes virus replication. J. Virol. 87, 912–922. 10.1128/JVI.02415-12 [DOI] [PMC free article] [PubMed] [Google Scholar]
  89. Meade N., Furey C., Li H., Verma R., Chai Q., Rollins M. G., et al. (2018). Poxviruses evade cytosolic sensing through disruption of an mTORC1-mTORC2. Cell 174, 1143–1157.e17. 10.1016/j.cell.2018.06.053 [DOI] [PMC free article] [PubMed] [Google Scholar]
  90. Melén K., Kinnunen L., Fagerlund R., Ikonen N., Twu K. Y., Krug R. M., et al. (2007). Nuclear and nucleolar targeting of influenza A virus NS1 protein: striking differences between different virus subtypes. J. Virol. 81, 5995–6006. 10.1128/JVI.01714-06 [DOI] [PMC free article] [PubMed] [Google Scholar]
  91. Meylan E., Curran J., Hofmann K., Moradpour D., Binder M., Bartenschlager R., et al. (2005). Cardif is an adaptor protein in the RIG-I antiviral pathway and is targeted by hepatitis C virus. Nature 437, 1167–1172. 10.1038/nature04193 [DOI] [PubMed] [Google Scholar]
  92. Miller D. J., Schwartz M. D., Ahlquist P. (2001). Flock house virus RNA replicates on outer mitochondrial membranes in drosophila cells. J. Virol. 75, 11664–11676. 10.1128/JVI.75.23.11664-11676.2001 [DOI] [PMC free article] [PubMed] [Google Scholar]
  93. Mishra P., Chan D. C. (2016). Metabolic regulation of mitochondrial dynamics. J. Cell. Biol. 212, 379–387. 10.1083/jcb.201511036 [DOI] [PMC free article] [PubMed] [Google Scholar]
  94. Monné M., Robinson A. J., Boes C., Harbour M. E., Fearnley I. M., Kunji E. R. S. (2007). The mimivirus genome encodes a mitochondrial carrier that ransports dATP and dTTP. J. Virol. 81, 3181–3186. 10.1128/JVI.02386-06 [DOI] [PMC free article] [PubMed] [Google Scholar]
  95. Moreira L. O., Zamboni D. S. (2012). NOD1 and NOD2 signaling in infection and inflammation. Front. Immunol. 3:328. 10.3389/fimmu.2012.00328 [DOI] [PMC free article] [PubMed] [Google Scholar]
  96. Moreno-Altamirano M. M., Rodriguez-Espinosa O., Rojas-Espinosa O., Pliego-Rivero B., Sanchez-Garcia F. J. (2015). Dengue virus serotype-2 Interferes with the formation of neutrophil extracellular traps. Intervirology 58, 250–259. 10.1159/000440723 [DOI] [PubMed] [Google Scholar]
  97. Nasr P., Gursahani H. I., Pang Z., Bondada V., Lee J., Hadley R. W., et al. (2003). Influence of cytosolic and mitochondrial Ca2+, ATP, mitochondrial membrane potential, and calpain activity on the mechanism of neuron death induced by 3-nitropropionic acid. Neurochem. Int. 43, 89–99. 10.1016/S0197-0186(02)00229-2 [DOI] [PubMed] [Google Scholar]
  98. Navale A. M., Paranjape A. N. (2016). Glucose transporters: physiological and pathological roles. Biophys. Rev. 8, 5–9. 10.1007/s12551-015-0186-2 [DOI] [PMC free article] [PubMed] [Google Scholar]
  99. Ni G., Ma Z., Damania B. (2018). cGAS and STING: at the intersection of DNA and RNA virus- sensing networks. PLoS Pathog. 14:e1007148. 10.1371/journal.ppat.1007148 [DOI] [PMC free article] [PubMed] [Google Scholar]
  100. Nieva J. L., Madan V., Carrasco L. (2012). Viroporins: structure and biological functions. Nat. Rev. Microbiol. 10, 563–574. 10.1038/nrmicro2820 [DOI] [PMC free article] [PubMed] [Google Scholar]
  101. Nomura-Takigawa Y., Nagano-Fujii M., Deng L., Kitazawa S., Ishido S., Sada K., et al. (2006). Non-structural protein 4A of Hepatitis C virus accumulates on mitochondria and renders the cells prone to undergoing mitochondria-mediated apoptosis. J. Gen. Virol. 87,1935–1945. 10.1099/vir.0.81701-0 [DOI] [PubMed] [Google Scholar]
  102. O'Neill L. A., Pearce E. J. (2016). Immunometabolism governs dendritic cell and macrophage function. J. Exp. Med. 213,15–23. 10.1084/jem.20151570 [DOI] [PMC free article] [PubMed] [Google Scholar]
  103. O'Neill L. A. J., Rigel J. K., Rathmell J. (2016). A guide to immunometabolism for immunologists. Nat. Rev. Immunol. 16, 553–565. 10.1038/nri.2016.70 [DOI] [PMC free article] [PubMed] [Google Scholar]
  104. Pal A. D., Basak N. P., Banerjee A. S., Banerjee S. (2014). Epstein-Barr virus latent membrane protein-2A alters mitochondrial dynamics promoting cellular migration mediated by Notch signaling pathway. Carcinogenesis 35, 1592–1601. 10.1093/carcin/bgu069 [DOI] [PubMed] [Google Scholar]
  105. Pearce E. L., Pearce E. J. (2013). Metabolic pathways in immune cell activation and quiescence. Immunity 38, 633–643. 10.1016/j.immuni.2013.04.005 [DOI] [PMC free article] [PubMed] [Google Scholar]
  106. Peng Y. T., Chen P., Ouyang R. Y., Song L. (2015). Multifaceted role of prohibitin in cell survival and apoptosis. Apoptosis 20, 1135–49. 10.1007/s10495-015-1143-z [DOI] [PMC free article] [PubMed] [Google Scholar]
  107. Qi H., Chu V., Wu N. C., Chen Z., Truong S., Brar G., et al. (2017). Systematic identification of anti-interferon function on hepatitis C virus genome reveals p7 as an immune evasion protein. Proc. Natl. Acad. Sci. U.S.A. 114, 2018–2023. 10.1073/pnas.1614623114 [DOI] [PMC free article] [PubMed] [Google Scholar]
  108. Qin Y., Xue B., Liu C., Wang X., Tian R., Xie Q., et al. (2017). NLRX1 mediates MAVS degradation to attenuate the hepatitis C virus-induced innate immune response through PCBP2. J. Virol. 91, e01264–e01217. 10.1128/JVI.01264-17 [DOI] [PMC free article] [PubMed] [Google Scholar]
  109. Radovanović,ć J. S., Todorovi,ć V., Borici,ć I. M, Janković-Hladni M., Korać A. (1999). Comparative ultrastructural studies on mitochondrial pathology in the liver of AIDS patients: clusters of mitochondria, protuberances, “minimitochondria,” vacuoles, and virus-like particles. Ultrastruct. Pathol. 23, 19–24. 10.1080/019131299281798 [DOI] [PubMed] [Google Scholar]
  110. Raftery M. J., Lalwani P., Krautkrämer E., Peters T., Scharffetter-Kochanek K., Kruger R., et al. (2014). β2 integrin mediates hantavirus-induced release of neutrophil extracellular traps. J. Exp. Med. 211, 1485–1497. 10.1084/jem.20131092 [DOI] [PMC free article] [PubMed] [Google Scholar]
  111. Rahmani Z., Huh K. W., Lasher R., Siddiqui A. (2000). Hepatitis B virus X protein colocalizes to mitochondria with a human voltage-dependent anion channel, HVDAC3, and alters its transmembrane potential. J. Virol. 74, 2840–2846. 10.1128/JVI.74.6.2840-2846.2000 [DOI] [PMC free article] [PubMed] [Google Scholar]
  112. Ren J. H., Chen X., Zhou L., Tao N. N., Zhou H. Z., Liu B., et al. (2016). Protective role of sirtuin3 (SIRT3) in oxidative stress mediated by hepatitis B virus X protein expression. PLoS ONE. 11:e0150961. 10.1371/journal.pone.0150961 [DOI] [PMC free article] [PubMed] [Google Scholar]
  113. Rich P. R., Maréchal A. (2010). The mitochondrial respiratory chain. Essays Biochem. 47, 1–23. 10.1042/bse0470001 [DOI] [PubMed] [Google Scholar]
  114. Rodriguez-Espinosa O., Rojas-Espinosa O., Moreno-Altamirano M. M., López-Villegas E. O., Sánchez-García F. J. (2015). Metabolic requirements for neutrophil extracellular traps formation. Immunology 145, 213–224. 10.1111/imm.12437 [DOI] [PMC free article] [PubMed] [Google Scholar]
  115. Rodríguez-Prados J. C., Través P. G., Cuenca J., Rico D., Aragonés J., Martín-Sanz P., et al. (2010). Substrate fate in activated macrophages: a comparison between innate, classic, and alternative activation. J. Immunol. 185, 605–614. 10.4049/jimmunol.0901698 [DOI] [PubMed] [Google Scholar]
  116. Rojo G., Chamorro M., Salas M. L., Vi-uela E., Cuezva J. M., Salas J. (1998). Migration of mitochondria to viral assembly sites in African swine fever virus-infected cells. J. Virol. 72, 7583–7588. [DOI] [PMC free article] [PubMed] [Google Scholar]
  117. Romero-Garcia S., Moreno-Altamirano M. M., Prado-Garcia H., Sánchez-García F. J. (2016). Lactate contribution to the tumor microenvironment: mechanisms, effects on immune cells and therapeutic relevance. Front. Immunol. 7:52. 10.3389/fimmu.2016.00052 [DOI] [PMC free article] [PubMed] [Google Scholar]
  118. Ruiz M. C., Aristimu-o O. C., Díaz Y., Pe-a F., Chemello M. E., Rojas H., et al. (2007). Intracellular disassembly of infectious rotavirus particles by depletion of Ca2+ sequestered in the endoplasmic reticulum at the end of virus cycle. Virus Res. 130, 140–150. 10.1016/j.virusres.2007.06.005 [DOI] [PubMed] [Google Scholar]
  119. Sabbah A., Chang T. H., Harnack R., Frohlich V., Tominaga K., Dube P. H., et al. (2009). Activation of innate immune antiviral responses by Nod2. Nat. Immunol. 10, 1073–1080. 10.1038/ni.1782 [DOI] [PMC free article] [PubMed] [Google Scholar]
  120. Saffran H. A., Pare J. M., Corcoran J. A., Weller S. K., Smiley J. R. (2007). Herpes simplex virus eliminates host mitochondrial DNA. EMBO Rep. 8, 188–193. 10.1038/sj.embor.7400878 [DOI] [PMC free article] [PubMed] [Google Scholar]
  121. Saitoh T., Komano J., Saitoh Y., Misawa T., Takahama M., Kozaki T, et al. (2012). Neutrophil extracellular traps mediate a host defense response to human immunodeficiency virus-1. Cell Host Microbe 12, 109–116. 10.1016/j.chom.2012.05.015 [DOI] [PubMed] [Google Scholar]
  122. Saxton R. A., Sabatini D. M. (2017). mTOR signaling in growth, metabolism and disease. Cell 168, 960–976. 10.1016/j.cell.2017.02.004 [DOI] [PMC free article] [PubMed] [Google Scholar]
  123. Schönrich G., Raftery M. J. (2016). Neutrophil extracellular traps go viral. Front. Immunol. 7:366. 10.3389/fimmu.2016.00366 [DOI] [PMC free article] [PubMed] [Google Scholar]
  124. Selman M., Ou P., Rousso C., Bergeron A., Krishnan R., Pikor L., et al. (2018). Dimethyl fumarate potentiates oncolytic virotherapy through NF-κB inhibition. Sci. Transl. Med. 10:425. 10.1126/scitranslmed.aao1613 [DOI] [PubMed] [Google Scholar]
  125. Seth R. B., Sun L., Ea C. K., Chen Z. J. (2005). Identification and characterization of MAVS, a mitochondrial antiviral signaling protein that activates NF-kappaB and IRF 3. Cell 122, 669–682. 10.1016/j.cell.2005.08.012 [DOI] [PubMed] [Google Scholar]
  126. Sharon-Friling R., Goodhouse J., Colberg-Poley A. M., Anamaris M., Shenk T. (2006). Human cytomegalovirus pUL37x1 induces the release of endoplasmic reticulum calcium stores. Proc Natl Acad Sci U. S. A. 103, 19117–19122. 10.1073/pnas.0609353103 [DOI] [PMC free article] [PubMed] [Google Scholar]
  127. Silverman N., Maniatis T. (2001). NF-kappaB signaling pathways in mammalian and insect innate immunity. Genes Dev. 15, 2321–2342. 10.1101/gad.909001 [DOI] [PubMed] [Google Scholar]
  128. Smith J. A. (2014). A new paradigm: innate immune sensing of viruses via the unfolded protein response. Front. Microbiol. 5:222. 10.3389/fmicb.2014.00222 [DOI] [PMC free article] [PubMed] [Google Scholar]
  129. Stohr S., Costa R., Sandmann L., Westhaus S., Pfaender S., Anggakusuma, et al. (2016). Host cell mTORC1 is required for HCV RNA replication. Gut 65, 2017–2028. 10.1136/gutjnl-2014-308971 [DOI] [PMC free article] [PubMed] [Google Scholar]
  130. Stokman G., Kors L., Bakker P. J., Rampanelli E., Claessen N., Teske G. J. D., et al. (2017). NLRX1 dampens oxidative stress and apoptosis in tissue injury via control of mitochondrial activity. J. Exp. Med. 214, 2405–2420. 10.1084/jem.20161031 [DOI] [PMC free article] [PubMed] [Google Scholar]
  131. Sumpter R., Jr., Loo Y. M., Foy E., Li K., Yoneyama M., Fujita T., et al. (2005). Regulating intracellular antiviral defense and permissiveness to hepatitis C virus RNA replication through a cellular RNA helicase, RIG-I. J Virol. 79, 2689–2699. 10.1128/JVI.79.5.2689-2699.2005 [DOI] [PMC free article] [PubMed] [Google Scholar]
  132. Sun B., Sundstrom K. B., Chew J. J., Bist P., Gan E. S., Tan H. C., et al. (2007). Dengue virus activates cGAS through the release of mitochondrial DNA. Sci. Rep. 7:3594. 10.1038/s41598-017-03932-1 [DOI] [PMC free article] [PubMed] [Google Scholar]
  133. Tanaka Y., Kanai F., Kawakami T., Tateishi K., Ijichi H., Kawabe T., et al. (2004). Interaction of the hepatitis B virus X protein (HBx) with heat shock protein 60 enhances HBx-mediated apoptosis. Biochem. Biophys. Res. Commun. 318, 461–9. 10.1016/j.bbrc.2004.04.046 [DOI] [PubMed] [Google Scholar]
  134. tenOever B. R., Sharma S., Zou W., Sun Q., Grandvaux N., Julkunen I., et al. (2004). Activation of TBK1 and IKKvarepsilon kinases by vesicular stomatitis virus infection and the role of viral ribonucleoprotein in the development of interferon antiviral immunity. J. Virol. 78, 10636–10649. 10.1128/JVI.78.19.10636-10649.2004 [DOI] [PMC free article] [PubMed] [Google Scholar]
  135. Thomanetz V., Angliker N., Cloetta D., Regula M., Lustenberger R. M., Schweighauser M., et al. (2013). Ablation of the mTORC2 component rictor in brain or Purkinje cells affects size and neuron morphology. J Cell Biol. 201, 293–308. 10.1083/jcb.201205030 [DOI] [PMC free article] [PubMed] [Google Scholar]
  136. Tian P., Estes M. K., Hu Y., Ball J. M., Zeng C. Q., Schilling W. P. (1995). The rotavirus nonstructural glycoprotein NSP4 mobilizes Ca2+ from the endoplasmic reticulum. J Virol. 69, 5763–5772. [DOI] [PMC free article] [PubMed] [Google Scholar]
  137. Tsai C.-F., Lin H.-Y., Hsu W.-L., Tsai C.-H. (2017). The novel mitochondria localization of influenza A virus NS1 visualized by FlAsH labeling. FEBS Open Bio. 7, 1960–1971. 10.1002/2211-5463.12336 [DOI] [PMC free article] [PubMed] [Google Scholar]
  138. Tsutsumi T., Matsuda M., Aizaki H., Moriya K., Miyoshi H., Fujie H., et al. (2009). Proteomics analysis of mitochondrial proteins reveals overexpression of a mitochondrial protein chaperon, prohibitin, in cells expressing hepatitis C virus core protein. Hepatology 50, 378–86. 10.1002/hep.22998 [DOI] [PubMed] [Google Scholar]
  139. Van Kuppeveld F. J., de Jong A. S., Melchers W. J., Willems P. H. (2005). Enterovirus protein 2B po(u)res out the calcium: a viral strategy to survive? Trends Microbiol. 13, 41–44. 10.1016/j.tim.2004.12.005 [DOI] [PubMed] [Google Scholar]
  140. Vanoevelen J., Dode L., Raeymaekers L., Wuytack F., Missiaen L. (2007). Diseases involving the Golgi calcium pump. Subcell Biochem. 45, 385–404. 10.1007/978-1-4020-6191-2_14 [DOI] [PubMed] [Google Scholar]
  141. Varanasi S. K., Donohoe D., Jaggi U., Rouse B. T. (2017). Manipulating glucose metabolism during different stages of viral pathogenesis can have either detrimental or beneficial effects. J. Immunol. 199, 1748–1761. 10.4049/jimmunol.1700472 [DOI] [PMC free article] [PubMed] [Google Scholar]
  142. Varga S. T., Grant A., Manicassamy B., Palesea P. (2012). Influenza virus protein PB1-F2 inhibits the induction of type I interferon by binding to MAVS and decreasing mitochondrial membrane potential. J Virol. 86, 8359–8366. 10.1128/JVI.01122-12 [DOI] [PMC free article] [PubMed] [Google Scholar]
  143. Vazquez C., Horner S. M. (2015). MAVS coordination of antiviral innate immunity. J Virol. 89, 6974 −6977. 10.1128/JVI.01918-14 [DOI] [PMC free article] [PubMed] [Google Scholar]
  144. Veiga-Fernandes H., Walter U., Bourgeois C., McLean A., Rocha B. (2000). Response of naïve and memory CD8+ T cells to antigen stimulation in vivo. Nat Immunol. 1, 47–53. 10.1038/76907 [DOI] [PubMed] [Google Scholar]
  145. Wang H., Ryu W. S. (2010). Hepatitis B virus polymerase blocks pattern recognition receptor signaling via interaction with DDX3: implications for immune evasion. PLoS Pathog. 6:e1000986. 10.1371/journal.ppat.1000986 [DOI] [PMC free article] [PubMed] [Google Scholar]
  146. Wang X., Eno C. O., Altman B. J., Zhu Y., Zhao G., Olberding K. E., et al. (2011). ER stress modulates cellular metabolism. Biochem. J. 435, 285–296. 10.1042/BJ20101864 [DOI] [PMC free article] [PubMed] [Google Scholar]
  147. West A. P., Shadel G. S., Ghosh S. (2011). Mitochondria in innate immune responses. Nat. Rev Immunol. 11, 389–402. 10.1038/nri2975 [DOI] [PMC free article] [PubMed] [Google Scholar]
  148. Wherry E. J. (2011). T cell exhaustion. Nat. Immunol. 12, 492–499. 10.1038/ni.2035 [DOI] [PubMed] [Google Scholar]
  149. Wiedmer A., Wang P., Zhou J., Rennekamp A. J., Tiranti V., Zeviani M., et al. (2008). Epstein-barr virus immediate-early protein Zta Co-Opts mitochondrial single-stranded DNA binding protein to promote viral and inhibit mitochondrial DNA replication. J. Virol. 82, 4647–4655. 10.1128/JVI.02198-07 [DOI] [PMC free article] [PubMed] [Google Scholar]
  150. Wu J., Chen Z. J. (2014). Innate immune sensing and signaling of cytosolic nucleic acids. Annu. Rev. Immunol. 32, 461–488. 10.1146/annurev-immunol-032713-120156 [DOI] [PubMed] [Google Scholar]
  151. Wu J. J., Li W., Shao Y., Avey D., Fu B., Gillen J., et al. (2015). Inhibition of cGAS DNA sensing by a herpesvirus virion protein. Cell Host Microbe 18, 333–344. 10.1016/j.chom.2015.07.015 [DOI] [PMC free article] [PubMed] [Google Scholar]
  152. Wu M., Xu Y., Lin S., Zhang X., Xiang L., Yuan Z. (2007). Hepatitis B virus polymerase inhibits the interferon-inducible MyD88 promoter by blocking nuclear translocation of Stat1. J. Gen. Virol. 88, 3260–3269. 10.1099/vir.0.82959-0 [DOI] [PubMed] [Google Scholar]
  153. Yamada H., Chounan R., Higashi Y., Kurihara N., Kido H. (2004). Mitochondrial targeting sequence of the influenza A virus PB1-F2 protein and its function in mitochondria. FEBS Lett. 578, 331–336. 10.1016/j.febslet.2004.11.017 [DOI] [PubMed] [Google Scholar]
  154. Yi J. S., Cox M. A., Zajac A. J. (2010). T-cell exhaustion: characteristics, causes and conversion. Immunology 129, 474–481. 10.1111/j.1365-2567.2010.03255.x [DOI] [PMC free article] [PubMed] [Google Scholar]
  155. Yoneyama M., Suhara W., Fujita T. (2002). Control of IRF-3 activation by phosphorylation. J. Interferon Cytokine Res. 22, 73–76. 10.1089/107999002753452674 [DOI] [PubMed] [Google Scholar]
  156. Yu C. Y., Liang J. J., Li J. K., Lee Y. L., Chang B. L., Su C. I., et al. (2015). Dengue virus impairs mitochondrial fusion by cleaving mitofusins. PLoS Pathog. 11:e1005350. 10.1371/journal.ppat.1005350 [DOI] [PMC free article] [PubMed] [Google Scholar]
  157. Yu Y., Yoon S. O., Poulogiannis G., Yang Q., Ma X. M., Ville'n J., et al. (2011). Phosphoproteomic analysis identifies Grb10 as an mTORC1 substrate that negatively regulates insulin signaling. Science 332, 1322–1326. 10.1126/science.1199484 [DOI] [PMC free article] [PubMed] [Google Scholar]
  158. Zamarin D., Garcia-Sastre A., Xiao X., Wang R., Palese P. (2005). Influenza virus PB1-F2 protein induces cell death through mitochondrial ANT3 and VDAC1. PLoS Pathog. 1:e4. 10.1371/journal.ppat.0010004 [DOI] [PMC free article] [PubMed] [Google Scholar]
  159. Zhang G., Chan B., Samarina N., Abere B., Weidner-Glunde M., Buch A., et al. (2016). Cytoplasmic isoforms of Kaposi sarcoma herpesvirus LANA recruit and antagonize the innate immune DNA sensor cGAS. Proc. Natl. Acad. Sci. USA. 113, E1034–E1043. 10.1073/pnas.1516812113 [DOI] [PMC free article] [PubMed] [Google Scholar]
  160. Zhang L., Wang A. (2012). Virus-induced ER stress and the unfolded protein response. Front. Plant Sci. 3:293. 10.3389/fpls.2012.00293 [DOI] [PMC free article] [PubMed] [Google Scholar]
  161. Zheng M., Xie L., Liang Y., Wu S., Xu H., Zhang Y., et al. (2015). Recognition of cytosolic DNA attenuates glucose metabolism and induces AMPK mediated energy stress response. Int. J. Biol. Sci. 11, 587–594. 10.7150/ijbs.10945 [DOI] [PMC free article] [PubMed] [Google Scholar]

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