Can Activation of NRF2 Be a Strategy against COVID-19?

Abstract

Acute respiratory distress syndrome (ARDS) caused by SARS-CoV-2 is largely the result of a dysregulated host response, followed by damage to alveolar cells and lung fibrosis. Exacerbated proinflammatory cytokines release (cytokine storm) and loss of T lymphocytes (leukopenia) characterize the most aggressive presentation. We propose that a multifaceted anti-inflammatory strategy based on pharmacological activation of nuclear factor erythroid 2 p45-related factor 2 (NRF2) can be deployed against the virus. The strategy provides robust cytoprotection by restoring redox and protein homeostasis, promoting resolution of inflammation, and facilitating repair. NRF2 activators such as sulforaphane and bardoxolone methyl are already in clinical trials. The safety and efficacy information of these modulators in humans, together with their well-documented cytoprotective and anti-inflammatory effects in preclinical models, highlight the potential of this armamentarium for deployment to the battlefield against COVID-19.

Exacerbated Inflammation in Severe COVID-19 Pathology

Numerous clinical observations during the outbreaks of coronaviruses – severe acute respiratory syndrome coronavirus (SARS-CoV), Middle East respiratory syndrome-related coronavirus (MERS-CoV), and most recently SARS-CoV-2 – convincingly show that, in addition to virus propagation, the host inflammatory response is a crucial determinant of disease outcome [1]. A parallel can be drawn with influenza, for which lethality is not associated with the cytolytic action of the pathogen but instead with the inflammatory response orchestrated by the host immune system [2]. In the most severe cases of the disease, a cytokine storm (excess production of cytokines) [3] is associated with T cell depletion, pulmonary inflammation, and lung damage. Patients showing acute respiratory distress syndrome (ARDS; see Glossary) and other types of virus-induced pneumonia also present features of macrophage activation syndrome (MAS) [3]. There is also evidence of leukopenia, with a ~twofold decrease in T cell number [4], which may be the result of pyroptosis, a form of cell death that mainly affects cells of the immune system [5]. On the other hand, granulocytosis might be partly responsible for the strong burst of superoxide [2], a type of reactive oxygen species (ROS) [6], and the additional production of proinflammatory cytokines [7].

To comprehensively manage the symptoms of COVID-19 (the disease caused by SARS-CoV-2), it is crucial to understand the most appropriate context for introducing an anti-inflammatory therapy to complement an antiviral therapy. Such therapy must control inflammation without altering the ability of the host to mount an efficient adaptive immune response against the virus. We propose that boosting endogenous cellular defenses by targeting the cytoprotective transcription factor NRF2 (gene name NFE2L2) will promote the resolution of COVID-19 associated inflammation and also restore redox homeostasis and facilitate tissue repair. It should be noted that the protein under discussion is distinctly separate from the identically abbreviated nuclear respiratory factor 2 (also known as GA binding protein transcription factor subunit β, gene name GABPB1), a completely different transcription factor involved in mitochondrial biogenesis [8].

Overview of NRF2 and Its Anti-Inflammatory Roles

NRF2 is a cap'n'collar (CNC) transcription factor that heterodimerizes with small musculoaponeurotic fibrosarcoma (sMAF) proteins, K, G, or F [9], or with transcription factors C-JUN and JUND [10], to bind to antioxidant response elements (AREs), and regulates the transcription of target genes, including those encoding proteins involved in cellular redox homeostasis, detoxification, macromolecular damage repair, and metabolic balance [11]. Under basal conditions, NRF2 interacts with the E3 ligase substrate adapter Kelch-like ECH-associated protein 1 (KEAP1) that targets the transcription factor for ubiquitination and proteasomal degradation [11., 12., 13.] (Figure 1 , Key Figure). Electrophiles and ROS (collectively termed inducers) inactivate KEAP1 by modifying specific sensor cysteine residues [14], resulting in NRF2 accumulation and enhanced target gene transcription.

Figure 1.

Key Figure. Putative Viral Cycle of SARS-CoV2 Highlighting Points of Potential Crosstalk with NRF2 Activation.

Steps 1–7 depict the different steps of the viral cycle. (1) Binding of the viral spike (S) protein to ACE2 leads to virion entry. NRF2 has been shown to repress ACE2 gene expression in rats [43]. (2) The viral nucleocapsid is uncoated in the cytoplasm of the host cell. (3) Translation of the viral positive-sense single-stranded RNA (+ssRNA) and cleavage of the translation product into specific viral proteins. Viral RNA inside the host cell activates the DNA/RNA sensor cGAS, which signals through the adaptor STING [117], and induces the expression of type I and III interferons (IFNs). NRF2 represses IFN production by downregulating STING expression [56]. (4) Replication of the viral genome. NRF2 induces the expression of HO-1, generating Fe²⁺ that can bind to the divalent metal-binding pocket of the RNA-dependent RNA polymerase (RdRp) of SARS-CoV2 and inhibit its catalytic activity [63,64]. (5) Translation of structural proteins. Host defense is conducted by double-stranded RNA-activated protein kinase R (PKR), which phosphorylates eIF2 and inhibits protein translation. PKR also phosphorylates p62, thus activating NRF2 upon removal of its repressor KEAP1 by autophagy [118]. Inhibition of protein translation in turn activates the unfolded protein response (UPR). PERK, a crucial Ser/Thr protein kinase in UPR signaling, phosphorylates NRF2, resulting in its stabilization and increased transcriptional activity [49]. (6) Virion assembly. (7) Release of viral particles. Abbreviations: ACE2, angiotensin-converting enzyme 2; eIF2, eukaryotic initiation factor 2; ER, endoplasmic reticulum; ERGIC, ER–Golgi intermediate compartment; HO-1, heme oxygenase 1; IFN, interferon; KEAP1, Kelch-like ECH-associated protein 1; NRF2, nuclear factor erythroid 2 p45-related factor 2; PERK, PKR-like endoplasmic reticulum kinase; P, phosphorylation; PKR, protein kinase R; STING, stimulator of interferon genes. Figure generated with Biorender (https://biorender.com/).

NRF2 activity is frequently dysregulated in disease states, including diabetes, liver disease, and inflammatory bowel disease [15], and declines with aging [16]. Some of these disease states (e.g., diabetes) and older age are risk factors associated with SARS-CoV-2-induced ARDS [17]. Importantly, activation of NRF2 has been shown to be involved in preserving lung architecture in response to inflammatory cues, and therapeutic effects of NRF2 activation have been reported in animal models of several lung disorders, including respiratory infections and ARDS [18]. Moreover, single-nucleotide polymorphisms (SNPs) located in the promoter region of NFE2L2 (encoding NRF2) have been implicated in lung disease susceptibility in humans, hence reinforcing NRF2 as therapeutic target for pulmonary diseases [19,20].

NRF2 also plays a role in both the execution and the resolution of inflammation [12] by repressing proinflammatory genes such as IL6 and IL1B [21]. This is particularly prominent in lipopolysaccharide (LPS)-stimulated macrophage cells, where the anti-inflammatory immunometabolite itaconate, that accumulates during metabolic reprogramming of these cells, activates NRF2 [22]. Moreover, NRF2 also induces the transcription of several macrophage-specific genes that participate in tissue repair. These include macrophage receptor with collagenous structure (MARCO), a receptor required for bacterial phagocytosis, cluster of differentiation 36 (CD36), a scavenger receptor for oxidized low-density lipoproteins (LDL) [24], and IL-17D [25], which confer protection against viral infections [26]. Similarly, NRF2 activation restores redox homeostasis by upregulating glutathione (GSH), NADPH, thioredoxin, thioredoxin reductase, and peroxiredoxin that protect against oxidative stress and favor alternative wound healing versus classical proinflammatory activation of macrophages and other immune cells [27].

NRF2 in Viral Infections

The role of NRF2 in viral infections has been investigated in the context of both DNA and RNA viruses. In general, viruses can benefit from either activating or inhibiting NRF2 in host cells [28]. This might be dependent on factors such as the stage of infection [29] or the specific mechanisms of viral propagation – that favor either death of the infected cells and lytic release of virions, or survival of the infected cells with reduction of the inflammatory response to help viral propagation [30]. For human coronavirus HCoV-229E, which is associated with the common cold and pulmonary disease [31], deficiency in expression of the NRF2 target gene glucose-6-phosphate dehydrogenase (G6PDH) increases ROS production and enhances viral gene expression and particle production [32]. Crucially, the NRF2 pathway has been found to be suppressed in lung biopsies from COVID-19 patients; conversely, pharmacological inducers of NRF2 inhibit the replication of SARS-CoV2 and the inflammatory response [33].

Interestingly, there is reciprocal crosstalk between NRF2 and NF-κB in inflamed tissues, where innate immune cells are recruited [34., 35., 36.]. Following infection with SARS-CoV, NF-κB is activated in lungs of mice and in human monocyte macrophages in vitro; conversely, inhibition of NF-κB decreases inflammation and improves survival after SARS-CoV infection in mice [7,37]. Thus, pharmacological activation of NRF2 might also limit NF-κB-mediated inflammatory processes inflicted in the lung by SARS-CoV-2 infection.

SARS-CoV-2 Biology and Potential Crosstalk with NRF2

The SARS-CoV-2 genome encodes non-structural proteins (nsp) that are required for replication, structural proteins including spike (S), envelope (E), membrane (M), and nucleocapsid (N), and accessory proteins ORF3, 6, 7a, 7b, 8, and 9b that interact with the host cells [38]. The receptor-binding domain (RBD) located in the S protein of SARS-CoV-2 interacts with the angiotensin-converting enzyme 2 (ACE2) of host cells to allow viral entry (Figure 1) [39]. The use of ACE inhibitors/angiotensin-receptor blockers, which are widely prescribed to patients with cardiovascular pathologies [40], is currently being considered for COVID-19 (clinical trial numbersi NCT04311177 and NCT04312009 for the use of losartan) because angiotensin II, the target of ACE inhibitors, has vasoconstrictive, proinflammatory, pro-oxidative, and prothrombotic effects [41]. However, these inhibitors alter the balance ACE/ACE2 and increase ACE2 levels, thus potentially increasing the number of docking sites for viral entry [42]. NRF2 deficiency is known to upregulate ACE2, whereas its activator oltipraz reduces ACE2 levels [43], suggesting that NRF2 activation might reduce the availability of ACE2 for SARS-CoV-2 entry into the cell (Figure 1).

By analogy with other coronaviruses, SARS-CoV-2 is expected to modulate the host translational machinery to favor the generation of its own proteins (Figure 1) [44]. Host countermeasures to this step include inactivation of eukaryotic initiation factor 2 (eIF2) by two of the three cellular eIF2α kinases, protein kinase R (PKR) and PKR-like endoplasmic reticulum kinase (PERK), which are known to be activated in response to SARS-CoV infection [45]. Interestingly, PKR also has the potential to upregulate the autophagy cargo protein p62, which competes with NRF2 for binding to KEAP1 [46] and further promotes the autophagic degradation of KEAP1 [47], thus activating NRF2 transcriptional activity (Figure 1). Moreover, it has been observed in SARS-CoV infection that host-induced blockade of translation of coronavirus proteins, including the S protein, triggers the unfolded protein response (UPR), activating PERK [48] that phosphorylates and activates NRF2 [49]. This may thus be one step at which NRF2 can be modulated to reduce the potential of SARS-CoV-2 infection of host cells.

Cells infected with RNA viruses recognize viral molecular patterns, especially nucleic acids, by cytoplasmic and endosomal receptors, such as the RNA sensors retinoic acid-inducible gene I (RIG-I) and melanoma differentiation-associated protein 5 (MDA-5) [50], and the DNA sensor cyclic GMP-AMP synthase (cGAS), which signals through the adaptor protein stimulator of interferon genes (STING) to mediate an appropriate immune response [51]. These innate detection systems activate interferon regulatory factor 3 (IRF3)-mediated transcription of type I and III interferons (IFNs) [51]. Coronavirus infections (including SARS-CoV) have been shown to antagonize STING-mediated host immune systems [52,53]. Although type I IFNs are crucial for restricting viral replication and spread by activating autocrine and paracrine type I IFN receptor signaling, excessive release of IFNs by infected pulmonary alveolar cells or resident macrophages may exacerbate the pulmonary infiltration of additional monocyte-derived macrophages, further potentiating inflammatory damage [54]. NRF2 downregulates IFN production, in part by downregulating STING expression [55,56] (Figure 1). Therefore, NRF2 may attenuate the inflammatory response to viral infection by preventing excessive production of IFNs.

In addition, upregulation of the NRF2-transcriptional target heme oxygenase 1 (HO-1, gene name HMOX1) has been linked to an antiviral response against many viruses including HIV, hepatitis C virus (HCV), hepatitis B virus (HBV), enterovirus 71 (E71), influenza virus, respiratory syncytial virus (RSV), Dengue virus (DENV), and Ebola virus (EBOV) [57]. HO-1 can mediate antiviral responses by forming a heterodimeric complex with IRF3 [58]. With this interaction, IRF3 is phosphorylated and translocated into the nucleus where it induces the expression of type I IFNs (Figure 2 ).

Figure 2.

Antiviral Activity of HO-1, a Target of NRF2.

HO-1 catalyzes the degradation of heme into carbon monoxide (CO), Fe²⁺, and biliverdin. Free Fe²⁺ is expected to bind to the highly conserved divalent metal-binding pocket of the viral RNA-dependent RNA polymerase (RdRp). Carbon monoxide activates soluble guanylyl cyclase (sGC) to generate cGMP, thus activating protein kinase G (PKG), which inhibits NAPDH oxidases (NOX), preventing an increase in reactive oxygen species (ROS). By inhibiting the SARS-CoV-2 proteases 3CLpro and PLpro, biliverdin is expected to suppress the proteolytic maturation of viral polypeptides. Heterodimerization of HO-1 with IRF3 facilitates the phosphorylation and nuclear translocation of IRF3 and the induction of type I IFN gene expression. Abbreviations, HO-1, heme oxygenase 1; IFN, interferon; ISRE, interferon-sensitive response element; IRF3, interferon regulatory factor 3; NRF2, nuclear factor erythroid 2 p45-related factor 2; P, phosphorylation. Figure generated with Biorender (https://biorender.com/).

Several other mechanisms have been described for the control of viral infection by HO-1, which can be extrapolated to some extent to SARS-CoV-2. HO-1 catalyzes the degradation of heme into three products, biliverdin, Fe²⁺, and CO, each with putative anti-SARS-CoV-2 activity. Coronaviruses produce viral proteases – 3C-like proteinase (3CL-pro) and papain-like protease (PLpro) – that process the viral polyproteins and are essential for viral replication [59]. Both 3CL-Pro and PLpro share high homology with other viral proteases [60] that are known to be inhibited by biliverdin [61] (Figure 2). Biliverdin is then expected to inhibit both SARS-CoV-2 3CLpro and PLpro. Free Fe²⁺ binds to the highly conserved divalent metal-binding pocket of RdRp of HCV, inhibiting its enzymatic activity (Figure 2) [62,63]. Because this binding pocket is highly conserved in SARS-CoV-2 [64] a similar mechanism may confer NRF2/HO-1-mediated antiviral activity against COVID-19. Furthermore, CO elicits antiviral responses against positive-sense single-stranded RNA (+ssRNA) viruses such as E71 [65] and bovine viral diarrhea virus (BVDV9) [66], and this effect is phenocopied by the CO donor, CO-releasing molecule 2 (CORM-2), through a mechanism that depends on the activation of soluble guanylyl cyclase (sGC), which increases the local levels of cGMP and activates protein kinase G (PKG) (Figure 2). In turn, PKG inhibits NADPH oxidase (NOX) [67], preventing an increase in ROS levels (Figure 2) that otherwise would contribute to inflammation. If these mechanisms are also mirrored in the context of COVID-19, activation of the NRF2/HO-1 pathway holds promise for mitigating SARS-CoV-2 infection.

Armamentarium of Available NRF2 Activators for Potential Anti-Inflammatory Therapy of COVID-19

An important limitation for the development of effective therapies against SARS-Cov-2 is the poor reproducibility of COVID-19 in animal models, most of which do not share relevant physiology, do not mount an appropriate immune response, or do not present relevant clinical symptoms [68]. Nevertheless, genetic or pharmacological NRF2 activation has consistently demonstrated anti-inflammatory and antiviral effects in other pathologies in animals and in humans. The most physiologically and pharmacologically relevant mechanism of NRF2 regulation is by targeting specific cysteine sensors within KEAP1 [11]. A comprehensive review on the use of NRF2 activators against viral infections has been published recently [69]. Given that changes in redox homeostasis in infected cells and lung inflammation are hallmarks of infections caused by respiratory viruses [70], the information obtained from viruses that affect the airways may be relevant for extrapolation to COVID-19. Indeed, experimental evidence is beginning to emerge, and it was recently demonstrated that the NRF2 activators dimethyl fumarate (DMF) and 4-octyl itaconate (4-OI), a cell-permeable analog of the endogenous anti-inflammatory metabolite itaconate [22], suppress the inflammatory response to SARS-CoV2 in human cells, including peripheral blood mononuclear cells (PBMCs) from COVID-19 patients [33].

The NRF2 activators targeting KEAP1 that are under clinical development have been recently described [11,71]. We discuss below DMF, the only drug approved by the US Food and Drug Administration (FDA) and the European Medicines Agency (EMA) that targets the NRF2/KEAP1 axis [72], as well as two types of NRF2 activators that have been tested in advanced clinical trials (Table 1 ), and thus can be immediately expedited to clinical trials to examine their therapeutic efficacy in patients with COVID-19.

Table 1.

Selected Clinical Trials of Relevance to Inflammation and Infection of Sulforaphane and Its Encapsulated Variant Sulfodarex (SFX-01), and Bardoxolone-Methyl and Its Structural Analog Omaveloxolone (RTA-408), Four NRF2 Activators That Target KEAP1

Compounda	Disease	Clinical trial	Clinical trial identifieri
Sulforaphane	Healthy	Phase I	NCT01008826
		Phase I	NCT02023931
	Chronic obstructive pulmonary disease (COPD)	Phase II	NCT01335971
	Asthma	Phase I	NCT01845493
		Phase I	NCT01845493
		Phase I/II	NCT01183923
	Aging	Phase II	NCT03126539
	Allergic rhinitis	Phase II	NCT02885025
	Helicobacterpylori infection	Phase IV	NCT03220542
	Type 2 diabetes mellitus	Phase II	NCT02801448
Sulforadex (SFX-01)	Subarachnoid hemorrhage	Phase II	NCT02614742
Bardoxolone methyl (CDDO-Me) R = CO2CH3	Pulmonary hypertension	Phase III	NCT03068130
		Phase III	NCT02657356
	Renal insufficiency Type 2 diabetes mellitus	Phase II	NCT01053936
	Type 2 diabetic nephropathy Chronic kidney disease	Phase II	NCT00811889
	IgA nephropathy Chronic kidney disease associated with type 1 diabetes mellitus Focal segmental glomerulosclerosis Autosomal dominant polycystic kidney disease	Phase II	NCT03366337
	Chronic renal insufficiency Type 2 diabetes mellitus	Phase III	NCT01351675
	Liver disease	Phase I/II	NCT00550849
	Hepatic impairment Healthy	Phase I	NCT01563562
	Alport syndrome	Phase II/III	NCT03019185
Omaveloxolone (RTA-408) R = NHCOCF2CH3	Inflammation and pain following ocular surgery	Phase II	NCT02065375
	Corneal endothelial cell loss Ocular pain Ocular inflammation Cataract surgery	Phase II	NCT02128113
	Radiation dermatitis in breast cancer	Phase II	NCT02142959

^aThe pink circles on the chemical structures indicate the electrophilic carbon that undergoes nucleophilic attack by cysteine 151 of KEAP1.

Dimethyl Fumarate

DMF is used in the treatment of multiple sclerosis (MS) and psoriasis, and may have beneficial effect in lung diseases [73]. Consistent with its role in preventing demyelination, DMF protects against Theiler's murine encephalomyelitis virus (TMEV), a +ssRNA virus that causes a MS-like disease, via enhancing the NRF2 antioxidant and anti-inflammatory responses as well as suppressing IL-17A [74]. However, a well-characterized off-target effect, not related to the NRF2/KEAP1 axis, is leukopenia that occurs in a subset of MS patients [75]. Considering that leukopenia is a hallmark of severe cases of COVID-19, the potential use of DMF in this setting should be considered with caution.

Sulforaphane

The isothiocyanate sulforaphane (SFN), originally isolated from broccoli, a cruciferous vegetable, as an inducer of the classical NRF2 target, NAD(P)H:quinone oxidoreductase 1 (NQO1) [76], is the most potent naturally occurring NRF2 activator, with well-documented antioxidant and anti-inflammatory effects [77]. The high bioavailability of SFN and its stabilized α-cyclodextrin-encapsulated version sulforadex (SFX-01) makes it an excellent candidate for alleviating excessive anti-inflammatory responses and protecting the lungs. SFN has been found to be protective in animal models of respiratory disease, including an ARDS model in rabbits [78] and a hyperoxia-induced pulmonary injury model in mice [79]. It also limits RSV replication and virus-induced inflammation in the lungs of wild-type, but not NRF2-null, mice [80]. In HIV-1 transgenic rats, SFN increased GSH levels and the expression of NQO1, and restored the tight junctions between the alveolar epithelial cells [81]. In an in vitro model of influenza A infection, SFN reduced both viral cell entry and replication [82]. In addition, SFN suppresses HCV replication [83] and reduces HSV-1 virion production [29]. Interestingly, SFN inhibits nucleotide-binding oligomerization domain (NOD)-, leucine-rich repeat (LRR)-, and pyrin domain-containing protein (NLRP) 1 and 3 inflammasomes (crucial innate immune components that shape host immune homeostasis) as well as pyroptosis, partly in an NRF2-independent manner [84]. Moreover, an interesting study conducted in smokers (a patient cohort with higher risk of lung infections, damage etc.) showed that SFN increased the expression of NQO1 in cells of nasal lavage fluid and, upon infection with live attenuated influenza virus, lowered the levels of IL-6 and viral load [85].

Sources of sulforaphane, including standardized broccoli extracts, dietary supplements, and encapsulated stabilized sulforaphane (Prostaphane and SFX-01) have been in numerous clinical trials for indications that range from lung disease to inflammatory diseases which are closely related to COVID-19 pathophysiology. These include chronic obstructive pulmonary disease (COPD), asthma, allergy, rhinitis, aging, diabetes mellitus, Helicobacter pylori infection, and subarachnoid hemorrhage (Table 1). The clinical trials provide extensive pharmacokinetics, pharmacodynamics, safety, and efficacy information [77] that can be extrapolated to COVID-19. Notably, most of these trials have recommended cruciferous-free diets during the study period to minimize baseline noise and accurately detect the plasma and urinary levels of sulforaphane and its metabolites [86].

Bardoxolone Methyl (CDDO-Me) and Omaveloxolone (RTA-408)

Semisynthetic pentacyclic triterpenoids derived from the natural product oleanolic acid represent the most potent NRF2 activators known to date, with activities in the sub- to low-nanomolar concentration range [87]. An early study highlighted that the anti-inflammatory and NRF2-inducer potencies of 18 triterpenoids correlated linearly over six orders of magnitude of concentration, suggesting that the two processes are mechanistically linked [88]. Some triterpenoids isolated from Ganoderma lucidum have been found to be potential inhibitors of the NS2B-NS3 protease of DENV [89]. A study conducted in 2003 after the SARS outbreak [90] found that glycyrrhizin, a triterpenoid from liquorice roots, inhibited the replication of SARS-CoV in two clinical isolates of coronaviruses from patients with SARS. The potential effect of glycyrrhizin on NRF2 was not studied; however, glycyrrhizin has been shown to activate NRF2 in other settings [77,91], and it is plausible that at least part of the observed antiviral effect was due to NRF2 activation.

Bardoxolone methyl (CDDO-Me), a semisynthetic pentacyclic triterpenoid, has been shown to possess a broad-spectrum anti-inflammatory activity against both DENV and Zika virus (ZIKV) [92]. In preclinical models, bardoxolone methyl alleviated LPS-induced acute lung injury through NRF2-dependent suppression of inflammation and oxidative stress [93]. The antiviral properties of bardoxolone methyl have also been shown in cell culture models of HBV, HCV, and HSV1 infections, where it reduced intracellular HBV RNA pre-genome levels, suppressed HCV genome replication [94], and inhibited the production of HSV1 virions [29]. Bardoxolone methyl and a closely related analog, omaveloxolone (RTA-408), are currently in clinical trials for various indications where inflammation and oxidative stress underlie disease pathogenesis, including pulmonary hypertension, pulmonary arterial hypertension, and ocular inflammation (Table 1) [95].

It is important to note that, even though NRF2 is the primary mediator, additional factors contribute to the anti-inflammatory effects of SFN, bardoxolone methyl, and omaveloxolone (RTA-408). Thus, SFN inhibits NF-κB [96], inhibitor of NF-κB kinase subunit β (IKKβ), and STAT3 [98], whereas bardoxolone methyl inhibits IKKβ [99] and STAT3 and STAT5 activation [100]. Overall, the combined NRF2-activating and anti-inflammatory effects of these compounds culminate in highly robust cytoprotection. These compounds potentially warrant exploration for the management of COVID-19 symptoms.

NRF2 Activators versus Other Anti-Inflammatory Approaches to COVID-19

The exacerbated inflammation observed in COVID-19 patients could potentially be treated with anti-inflammatory drugs such as corticosteroids and nonsteroidal anti-inflammatory drugs (NSAIDs). Indeed, the RECOVERY (randomised evaluation of COVID-19 therapy) trial, a randomized multicenter clinical trial in COVID-19 patients from National Health Service (NHS) hospitals in the UK, found that low-dose dexamethasone, a corticosteroid, reduced mortality in ventilated patients and in patients receiving oxygen only, although it had no effect in patients not receiving respiratory support [101].

Although results with NSAIDs are not conclusive in people with COVID-19 [102], ibuprofen, an NSAID, has been shown to impair neutrophil function, their recruitment to the inflammatory site, and the resolution of inflammatory processes in patients with pneumonia [103]. However, ibuprofen is associated with higher rates of nephrotoxicity [104], cardiovascular disease, and stroke [105], and appears to increase the risk for these outcomes in ARDS [106]. A significant difference between NSAIDs and NRF2 activators is that NRF2 elicits a much more integrated regulation of the inflammatory response because it is necessary for both execution and resolution. Furthermore, by regulating the endogenous cytoprotective systems, NRF2 may have a more physiological role in achieving a balance between the beneficial and adverse effects of inflammation.

Another alternative to conventional anti-inflammatory drugs that holds great promise in COVID-19 is the use of drugs that target cytokines involved in the cytokine storm in COVID-19. This includes targeting IL-6 and IL-1 signaling [107]. Tocilizumab (a humanized monoclonal antibody against the IL-6 receptor) and anakinra (a recombinant human IL-1 receptor antagonist) are being repurposed and studied in COVID-19 [108,109]. Use of NRF2 activators represents an excellent alternative or parallel to these approaches because it is known that NRF2 inhibits IL-6 and IL-1β gene expression [21].

Concluding Remarks and Future Perspectives

In the past few months, COVID-19, a disease caused by a novel coronavirus SARS-CoV-2, has had a tremendous health and socioeconomic impact at a global scale. We propose here a potential anti-inflammatory therapy based on pharmacological targeting of transcription factor NRF2. We envisage that the benefits of pharmacological activation of NRF2 in the context of SARS-Cov-2 infection will be threefold: (i) increasing fitness and providing protection to the host cell; (ii) promoting the anti-inflammatory phenotype during macrophage activation, thus preventing uncontrolled production of proinflammatory cytokines and pyroptosis; and (iii) inhibiting viral propagation. Notably, unlike direct antioxidants such as vitamin C, that are short-lived (minutes to hours) and are consumed in the process of ROS scavenging, the antioxidant and cytoprotective effects of NRF2 activation are long-lasting and persist for several days after inducer elimination [110,111]. This is because they are mediated by enzymes that, in contrast to small molecules, have long half-lives [11] and are not consumed, and are instead regenerated during the reactions which they catalyze [112].

Most NRF2 inducers, including DMF, sulforaphane, and bardoxolone methyl, are electrophiles that modify cysteine sensors of KEAP1 and inactivate its repressor function. Concerns in using electrophilic NRF2 activators include: (i) possible toxicity at high doses – electrophiles react with GSH and thus, at high doses, may cause GSH depletion; indeed an electrophilic metabolite is responsible for the hepatotoxicity of high doses of acetaminophen [113]. (ii) Possible perturbations of redox signaling owing to persistent NRF2 activity. Both concerns can be resolved by careful selection of dose and dosing regimen in the design of clinical trials, such as including periods of NRF2 activation only during times of active disease with the aim of restoring redox balance and resolving inflammation. Moreover, experimental evidence suggests that the maximally tolerated dose of sulforaphane (and other electrophiles) is not necessarily the most effective [114]. This realization is driving research that aims to identify non-electrophilic NRF2 activators, which inhibit binding to KEAP1, and where promising candidates are emerging [71,115,116].

An area of potential interest for developing COVID-19 candidate drugs in the NRF2 pathway would be to identify inhibitors of the transcriptional repressor BTB domain and CNC homolog 1 (BACH1) that shows increased levels as NRF2 activation declines with age (a risk factor in COVID-19) [18].

Collectively, the research discussed strongly suggests that NRF2 activation holds promise as a strategy against COVID-19. However, before implementing this strategy it is desirable to address several important issues (see Outstanding Questions). For example, the finding that SARS-CoV-2 inhibits NRF2 [33] indicates that the virus deprives the host cells of an essential cytoprotective pathway, and it will be crucial to determine how and when during the process of the viral infection this takes place, and the underlying mechanism. It is presently unclear whether NRF2 can contribute to metabolic reprogramming and adaptation of macrophages and T cells, and whether it affects their effector functions during the course of COVID-19. It will also be important to establish whether pharmacological activation of NRF2 can suppress the entry of SARS-CoV-2 into the host cell, how NRF2 activators reduce the replication of SARS-CoV-2, and whether this effect depends on NRF2, HO-1, or the broader network of proteins regulated by NRF2.

Outstanding Questions.

How does SARS-CoV-2 downregulate NRF2 in the host cells, and does this depend on the stage of the viral infection?

Does NRF2 contribute to metabolic reprogramming and adaptation of macrophages and T cells, and does it affect their anti-inflammatory functions during the course of COVID-19?

Can pharmacological activation of NRF2 decrease SARS-CoV-2 entry into host cells?

Do all NRF2 activators reduce replication and virion production, or do they affect other stages of propagation of SARS-CoV-2?

If they do, does this effect depend on NRF2 and/or HO-1?

Alt-text: Outstanding Questions

Nonetheless, the wealth of safety and efficacy information for NRF2 activators such as sulforaphane and bardoxolone methyl, that are already in advanced clinical trials for other indications, provides a clear route for their testing in randomized clinical trials in patients with COVID-19. If successful, this therapeutic strategy could be rapidly mobilized to improve recovery and decrease the need for mechanical ventilation in patients with severe COVID-19, relieving the enormous strain that is currently being experienced by intensive care units worldwide.

Glossary

Acute respiratory distress syndrome (ARDS)

a type of respiratory failure characterized by rapid onset of widespread inflammation in the lungs which impairs their ability to exchange oxygen and carbon dioxide.

Angiotensin-converting enzyme 2 (ACE2)

a transmembrane receptor protein that is found in lungs, arteries, heart, kidney, and intestine, and which serves as the main entry point into cells for SARS- CoV and SARS-CoV2.

Antioxidant response elements (AREs)

specific DNA sequences in the promoter regions of NRF2-dependent genes.

Bioavailability

the proportion of a drug or other substance which, when introduced into the body, enters the circulation and is thus able exert biological effects.

Electrophile

a chemical species that is attracted to an electron-rich center. Electrophiles are chemically reactive and, by accepting an electron pair, binds to nucleophiles.

Glutathione (GSH)

the most abundant thiol in animal cells; >90% of total glutathione is in the reduced form (GSH), and the remainder is in the disulfide form (GSSG). An increased GSSG/GSH ratio is indicative of oxidative stress.

Granulocytosis

an increase in number of granulocytes (basophils, eosinophils, and neutrophils) in the peripheral blood.

Macrophage activation syndrome (MAS)

a potentially fatal complication of rheumatic diseases; MAS is characterized by high fever and can be associated with hemorrhage, damage to the liver, kidney, and the central nervous system, and may lead to multiple organ failure.

NAD(P)H:quinone oxidoreductase 1 (NQO1)

a homodimeric FAD-binding protein that catalyzes the obligatory two-electron reduction of quinones to hydroquinones, thus preventing redox cycling and glutathione depletion. NQO1 is a classical NRF2-regulated gene and is used as a marker of NRF2 transcriptional activity.

Nonsteroidal anti-inflammatory drugs (NSAIDs)

inhibitors of the activity of cyclooxygenases (COX-1 or COX-2) that catalyze the biosynthesis of prostaglandins (involved in inflammation) and thromboxanes (involved in blood clotting).

Oxidative stress

imbalance between oxidants and antioxidants in favor of the oxidants, leading to disruption of cellular redox signaling and damage to proteins, lipids, and DNA.

Reactive oxygen species (ROS)

unstable oxygen-containing molecules formed by redox reactions or by electronic excitation.

Stimulator of interferon genes (STING)

an adaptor protein associated with the endoplasmic reticulum, which is essential for transcription of host defense genes, including type I interferons (IFNs) and proinflammatory cytokines, following recognition of aberrant DNA species or cyclic dinucleotides (CDNs) in the cytosol.

Unfolded protein response (UPR)

a homeostatic signaling network that is activated following endoplasmic reticulum stress and results in functional recovery of the organelle.

Resource

ⁱhttps://www.clinicaltrials.gov/