key: cord-1050722-w8ch2gvu authors: Ebrahimi, Kourosh H.; Gilbert‐Jaramillo, Javier; James, William S.; McCullagh, James S.O. title: Interferon‐stimulated gene products as regulators of central carbon metabolism date: 2020-12-01 journal: FEBS J DOI: 10.1111/febs.15625 sha: 7e4f15d797b3b981d525ac91ac8f28259a7e481d doc_id: 1050722 cord_uid: w8ch2gvu In response to viral infections, the innate immune system rapidly activates expression of several interferon‐stimulated genes (ISGs), whose protein and metabolic products are believed to directly interfere with the viral life cycle. Here, we argue that biochemical reactions performed by two specific protein products of ISGs modulate central carbon metabolism to support a broad‐spectrum antiviral response. We demonstrate that the metabolites generated by metalloenzymes nitric oxide synthase and the radical S‐adenosylmethionine (SAM) enzyme RSAD2 inhibit the activity of the housekeeping and glycolytic enzyme glyceraldehyde 3‐phosphate dehydrogenase (GAPDH). We discuss that this inhibition is likely to stimulate a range of metabolic and signalling processes to support a broad‐spectrum immune response. Based on these analyses, we propose that inhibiting GAPDH in individuals with deteriorated cellular innate immune response like elderly might help in treating viral diseases such as COVID‐19. Central carbon metabolism converts sugars into a range of metabolic precursors that are used to generate biomass and energy required for the cellular function [1] (Fig. 1A) . Consequently, remodelling of central carbon metabolism occurs in many human diseases such as cancer [2] and is at the forefront of the host-pathogen interactions. Pathogens like bacteria or viruses are dependent on host cellular metabolites and proteins to support their reproduction. To fight viral infections, all cells are equipped with a nonspecific response consisting of the expression of several proteins and enzymes, induced by different types of interferons, and thus, are referred to as interferon-stimulated gene (ISG) products. Most previous studies have led to the conclusion that the protein products of these genes directly act on the viral life cycles to restrict their replication [3, 4] . On the contrary, we propose a new model based on available data in the literature and an analogy from a system engineering perspective (Fig. 1B) : A cell can be considered as a factory and central carbon metabolism as the main process for converting a raw material to products and energy for the factory to function (Fig. 1B) . When an infectious agent enters the factory, it will highjack the main process and use the products for its reproduction. Under this circumstance, the first response of the control room would be to use some of the available products in a second reaction (analogous to the function of ISGs) to directly block viral replication and to inhibit the main process. This would limit the nutrients for the reproduction of the infectious agent, while redirecting the materials and energy to a third process that can eliminate the invading agent. Accordingly, we suggest that the metabolites generated by some ISG proteins contribute to the remodelling of the central carbon metabolism in support of a broad-spectrum antiviral immune response. We discuss emerging evidence that supports this model. We show how the early metabolites generated by the biochemical reactions of two ISG metalloenzymes, namely nitric oxide synthase (NOS) and the radical-SAM enzyme RSAD2, inhibit the glycolytic enzyme glyceraldehyde 3-phosphate dehydrogenase (GAPDH) and how this inhibition is likely to support a broad-spectrum antiviral immune response. GAPDH is a housekeeping protein catalysing a critical step in glycolysis, with additional functions in DNA repair [5] , cytoskeletal dynamics and vesicular trafficking between cellular compartments [6] and redox signalling and apoptosis [7] . As a glycolytic enzyme, it catalyses the NAD + -dependent transformation of glyceraldehyde 3-phosphate (G3P or GAP) to 1,3-biphosphoglycerate (1,3-BPG) (Fig. 1A) . Metabolomic analysis together with computational studies have revealed that flux through GAPDH is a rate-limiting step in glycolysis [8] . Here, we discuss mechanisms adopted by the cellular innate immune response to inhibit NAD + -dependent conversion of G3P by converts sugars to the building blocks of DNA and RNA, proteins and lipids. Additionally, it generates energy in the form of ATP and redox cofactors NAD + /NADH and NADP + /NADPH. Abbreviations: LDs, lipid droplets; G6P, glucose 6-phosphate; F6P, fructose 6-phosphate; FBP, fructose 1,6-biphosphate; G3P, glyceraldehyde 3-phosphate; DHAP, dihydroxyacetone phosphate; 1,3-BPG, 1,3-biphosphoglycerate; 3PG, 3phosphoglycerate; 2PG, 2-phosphoglycerate; PEP, phosphoenolpyruvate; 2-OG, 2-oxoglutarate. (b) A systems engineering analogy describing function of the protein products of ISGs as (1) direct effectors of viral replication and (2) in the remodelling of central carbon metabolism to support broad-spectrum immune response. The cell is like a factory and central carbon metabolism is the process 1. If an infectious agent enters the factory, the first response of the control room would be to use some of the available products and energy (process 2) to either directly inhibit viral replication (path 1) or to inhibit the production process (path 2). The outcomes of path 2 will be (i) reduction in formation of products and energy to limit access of pathogen to these resources and (ii) support of process 3, which restricts replication of the infectious agent. Inhibition of GAPDH by ddhCTP or S-nitrosylation will likely result in an increase in the cellular availability of NAD + . This will support protein ADP-ribosylation and biosynthesis of cyclic ADP-ribose (cADPR) [39,40] (Fig. 3) , both of which require NAD + as a substrate. Consistently, it is shown that S-nitrosylation of GAPDH and inhibition of its activity increases endogenous protein ADP-ribosylation [34]. ADP-ribosylation is shown to increase proteasomal activity [41, 42] . cADPR on the other hand, is a second messenger metabolite involved in modulation of Ca 2+ signalling and homeostasis [43-45] (Fig. 3A) . cADPR binds to ryanodine receptor (RyRs), which is expressed in many cell types including macrophages and T cells [46] , and initiates the release of Ca 2+ from the intracellular store (Fig. 3 ) [47] [48] [49] . Aligned with these observations, it has been shown that the cellular level of NAD + controls Ca 2+ store and release [50] . Inhibition of GAPDH can also increase the cellular availability of G3P. Consistently, macrophages expressing RSAD2, which can produce ddhCTP, show a higher intracellular level of G3P as compared to RSAD2-KO macrophages [25] . Increase in the cellular availability of G3P supports biosynthesis of triacylglycerols (TAGs) and phosphatidylcholine (PC), which are the building blocks of lipid droplets (LDs) [51,52]. G3P is converted to dihydroxyacetone phosphate (DHAP) by the catalytic activity of triosephosphate isomerase (Fig. 3) . Subsequently, DHAP is converted by the NADH-dependent activity of glycerol-3-phosphate dehydrogenase (GPDH) to glycerol-3-phosphate Stimulation of proteasome activity by ADP-ribosylation, cADPR-dependent stimulation of Ca 2+ release from the cellular stores, and an increase in biosynthesis of TAGs and PC, is likely to support a systemic immune response in cells in at least four ways (Fig. 4) [60] [61] [62] [63] [64] . Characterization of lipid droplets in different cells has revealed that enzymes involved in catalytic conversion of AA to eicosanoid like PGE 2 , namely cyclooxygenase 1 and 2 (COX1 and COX2), are localized to the LDs [65] . These data strongly suggest that LDs are at least partially involved in synthesis of inflammatory eicosanoids from AA and their downstream signalling pathways. Inhibition of GAPDH is likely to support LDs-mediated eicosanoids biosynthesis in at least two ways: (i) increase in the cellular availability of G3P for biosynthesis of TAGs and PC and formation of LDs (Fig. 4A) and (ii) increase in the cellular availability of NAD + and induction of cADPR-dependent release of Ca 2+ from cellular stores to support activity of the Ca 2+ -dependent phospholipases PLA 2 and liberation of AA (Fig. 4A) . b. Antigen cross-presentation via major histocompatibility class I: This process requires proteasomal LDs. An increase in proteasomal activity increases the rate of formation of peptide antigens for cross-presentation via major histocompatibility class I (MHC-I) [66] [67] [68] . In many cell types including macrophages and DCs, a major path of antigen cross-presentation involves transfer of peptide antigen into the endoplasmic reticulum (ER) lumen by the ATP-dependent function of the TAP system (Fig. 4A ) [69, 70] . In the ER lumen, peptide antigens bind to MHC-1 and the complex is transported to the cell surface for presentation to CD8 + T cells. A mechanism of transportation to the cell surface is through LDs [56]. In dendritic cells (DCs), the immune-related GTPs protein, namely Irgm3, localizes to the LDs [71] . When the gene expressing Irgm3 or adipose differentiation-related protein (ADRP, also known as ADFP), which regulates LD biogenesis and dynamics [72, 73] , was inactivated, formation of LDs was impaired and cross-presentation of antigen to CD8 + T cells was abrogated [71] . Additionally, saponin-based adjuvants (SBAs), which are used in cancer vaccines, induce formation of LDs in CD11b + DCs and this increase causes a saponin-dependent increase in antigen cross-presentation and T-cell activation [74] . Therefore, a concomitant increase in the cellular availability of G3P and NAD + due to inhibition of GAPDH will ensure formation of LDs as carriers of the MHC-I/antigen complex, and increase proteasomal activity via an ADP-ribosylation pathway to provide the peptide antigens (Fig. 4A) . Consistent with this mechanism, the cellular activity of RSAD2 (viperin), which generates the ddhCTP metabolite and inhibits GAPDH, stimulates degradation of Zika virus and tick-borne encephalitis virus nonstructural protein NS3 via a proteasomedependent manner [75] . c. NFAT-and NF-jB-mediated immune regulation. In innate immune cells like macrophages or T cells release of Ca 2+ activates a range of immune defence mechanisms (Fig. 3B) . Ca 2+ binds to calmodulin (CaM) and the complex activates the phosphatase calcineurin (CaN) [76, 77] . In turn, CaN dephosphorylates and activates nuclear factor of activated T cells (NFAT) [78] . Additionally, CaN plays a role in LPS-induced nuclear factor-jB (NF-jB) activation in macrophages [79] [80] [81] . NFAT-and NF-jB regulate expression of several genes involved in immune cell response and function including IL-10, IL-6, IL-8, IFN-1, IFN-2, TNF-a and multiple TLR-inducible genes including iNOS [82] [83] [84] [85] [86] [87] [88] [89] [90] . Thus, inhibition of GAPDH by ddhCTP or NO, and the likely increase in the cellular availability of NAD + , will modulate NFAT-or NF-jB-dependent expression of inflammatory genes. In summary, inhibition of GAPDH and an increase in the cellular level of NAD + are likely to induce stimulation of cADPR and release of Ca 2+ . This will modulate activity of NFAT-and NF-jB for a balanced and effective antiviral immune response. There is growing evidence in support of this mechanism. Firstly, when RSAD2 (viperin) gene was knocked out, thereby abrogating the inhibition of GAPDH by ddhCTP, the mRNA level of genes whose expression is regulated by NFAT or NF-jB including iNOS and TNF-a was affected in macrophages [91] . Secondly, NFAT and NF-jB regulate Th2 response [92] and cellular activity of RSAD2 modulates activity of NF-jB and AP1, which interact with NFAT, for optimal Th2 response [93] . Finally, overexpression of viperin upregulates expression of a wide range of immune-related genes including IL-8, IFN-1 and IFN-2 [27], whose expression is regulated by NFAT. d. Nitric oxide and immune response. In many cells, nitric oxide (NO) is an important product of the innate immune response and has broad-spectrum antiviral and antibacterial activity [94] [95] [96] [97] . It can contribute to viral restriction via different mechanisms. NO causes S-nitrosylation of different viral proteins, abolishes their activity and reduces viral replication [98] (Fig. 4B ). Viral components, including proteases [99] [100] [101] [102] , RNA-dependent RNA polymerases (RdRps) [103] , and transcriptase [104] , are known to be inhibited by NO-mediated S-nitrosylation. Replication of a number of viruses is restricted by NO including herpes simplex virus type 1 [105] , Japanese encephalitis virus [106] , coxsackievirus [101] , dengue virus type 2 (DNGV-2) [103] , influenza virus [107] and HIV-1 [102, 104] . Additionally, NO can modulate mitochondrial metabolism to induce formation of inflammatory macrophages [108] . Therefore, inhibition of GAPDH and an increase in the cellular availability of NAD + , which will induce cADPR-dependent Ca 2+ release, will induce activity of iNOS via CaM binding (Fig. 4B) . The resulting NO can support a broad-spectrum antiviral response via S-nitrosylation of viral protein or by further modulating the metabolism in immune cells like macrophages. In summary, we demonstrate that the glycolytic and housekeeping enzyme GAPDH is inhibited or modified by the metabolites, namely ddhCTP and NO, produced by two ISG protein products, RSAD2 and nitric oxide synthase, respectively. Inhibition of the NAD + -dependent conversion of G3P by GAPDH supports several downstream metabolic and signalling pathways, specifically biosynthesis of TAGs and PC, which are precursors of LDs, protein ADP-ribosylation and synthesis of cADPR. Together, these metabolites stimulate a balanced immune response via inflammatory eicosanoids, antigen cross-presentation, activation of NFAT and NF-jB and stimulation of formation of NO. This immunometabolic regulation of central carbon metabolism to stimulate a broad-spectrum immune response provides an explanation for the wide range of effects observed due to expression of RSAD2 (viperin) in many cell types: these include the broad-spectrum antiviral response [19] , optimal Th2 cytokine production [93] , which requires NFAT function [109] , modulation of cellular lipid metabolism during human cytomegalovirus and influenza virus infections [110, 111] , induction of type-1 interferon production in plasmacytoid dendritic cells via a Toll-like receptor-mediated mechanism [112] , interference with glucose homeostasis [26] and regulation of macrophage polarization [91] . Our analyses suggest that inhibition of GAPDH by the cellular innate immune response primes a broadspectrum immune response to viral infection. This is in opposed to recent reports [113, 114] suggesting that inhibition of GAPDH reduces immune response and thus, is a potential therapeutic approach for treating inflammatory diseases. These studies are based on use of small molecules such as the drug dimethyl fumarate (DMF) [113] , which is used to treat autoimmune diseases, or 4-octyl itaconate [114] . These molecules were suggested to directly modify Cys150 or Cys22, respectively, in GAPDH, and inhibit its activity. This inhibition was linked to a reduction in synthesis of inflammatory cytokines such as TNF-a in T cells and macrophages with the assumption that no other protein in the cell was modified [113, 114] . In contrast to this assumption, analysis of global proteome in T cells reveals more than 2400 cysteine residues that could potentially be modified by DMF [115] . It was shown that two cysteine residues in protein kinase Ch are target of modification by DMF and these modifications interfere with T-cell activation [115] . Because the cellular innate immune response adopts mechanism that leads to inhibition of GAPDH, which as we discussed is likely to induce a broad-spectrum immune response, we propose that in individuals with weakened cellular innate immune system inhibition of GAPDH might be a therapeutic approach to help prime the innate immune response via at least four Targeting viperin improves diet-induced glucose intolerance but not adipose tissue inflammation. 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KHE is grateful to Professor Fraser Armstrong (University of Oxford, UK) and Professor The authors declare no conflict of interest. KHE conceived the study and wrote the manuscript with contribution from all the authors.