The frequency and number of MAIT cells is significantly decreased in the peripheral blood and the liver of patients with chronic hepatitis B (37–42) and is associated with middle/late stages of the disease compared to early stages. Notably, the decrease in circulating MAIT cells indicates poor prognosis for patients with chronic HBV (40). Peripheral MAIT cells express higher levels of the activation markers CD69 (37), CD38 (37–39, 42), HLA-DR (37, 38) than intrahepatic MAIT cells (37) indicating that circulating MAIT cells are more activated than MAIT cells in the liver. In addition, blood and liver MAIT cells from patients express high levels of PD1, compared to healthy individuals (39, 42), which is directly associated with increased plasma levels of HBV-DNA (39), indicating that PD1⁺MAIT cells are dysfunctional in patients with chronic HBV infection. Consistent with that, MAIT cells from chronically HBV infected patients produce lower amounts of IFNγ, TNFα, granzyme B, and perforin after ex vivo stimulation, compared to healthy controls (37–39, 41). Importantly, the frequency and the number of MAIT cells is restored after anti-viral therapy in patients that survived compared to those that succumbed to disease (40) ( Figure 1 ). Consistent with these findings, MAIT cells exhibit strong and direct cytotoxicity against HBV-infected hepatocytes (41), rendering them potential targets in anti-viral therapeutic strategies.

Similar to chronic HBV infection, the frequency and the number of circulating and intrahepatic MAIT cells is reduced in patients with chronic HCV infection (43–49), although MAIT cells are enriched in the liver compared to the blood of chronic HCV patients (46). This reduction in MAIT cell number is independent of the disease stage (44). Peripheral MAIT cells are characterized by an exhausted phenotype, as shown by the increased expression of exhaustion markers PD1, CTLA4 and TIM3 (44, 45) and the chronic activation marker CD38 (45, 48). In addition, MAIT cells produced reduced levels of IFNγ, TNFα, and IL17 after E. coli stimulation, although production of these cytokines was normal after IL12/IL18 stimulation (44, 46), indicating impaired TCR-dependent MAIT cell responses. The frequency of circulating CD57⁺ (senescence marker) MAIT cells is increased, providing additional evidence that MAIT cells are dysfunctional in chronic HCV patients (45). Activation/exhaustion of intrahepatic MAIT cells is mediated through liver monocyte-derived cytokines in patients with chronic HCV infection (46). In addition, MAIT cells are more cytotoxic (46) due to the increased production of granzyme B (44). IFN-free therapy against chronic HCV infection leads to clearance of the virus, although the frequency of MAIT cells does not recover (44), but the number of CD8⁺ T and NK cells is increased (50). IFNα-based therapies increase the frequency and activation of MAIT cells in the liver (43) leading to partial resolution of liver inflammation (46). Taken together, these data suggest that the frequency and number of MAIT cells is inversely correlated with liver inflammation and fibrosis in chronic HCV infection ( Figure 2 ), while the function of the remaining MAIT cells is impaired. It is, thus, possible that this exhausted phenotype contributes to the chronicity of viral infection, although studies that examine the function of MAIT cells in acute viral hepatitis are currently lacking.

iNKT cell number is significantly increased in the liver of HBV transgenic mice with acute hepatitis. HBV-infected hepatocytes presented lipid antigens to liver iNKT cells, through CD1D presentation, thus leading to their activation and immediate production of anti-viral IFNγ (51). IFNγ inhibited proliferation of infected hepatocytes and enhanced innate and adaptive immune responses, including the activity of cytolytic cells (51, 52). Importantly, αGalCer-activated iNKT cells directly inhibited HBV replication in the liver of HBV-transgenic mice (53), eventually limiting HBV infection through various mechanisms. Although iNKT cells contribute to the control of acute HBV infection, their functionality and number are compromised in patients and HBV transgenic mice with chronic HBV infection, as indicated by PD1 upregulation and CD28 downregulation, and their impaired ability to produce IFNγ (54, 55). Inhibition of PD1 and activation of the CD28/CD80 pathway in iNKT cells inhibited HBV replication (54). iNKT cells expressed high levels of TIM3 in HBV transgenic mice and inhibition of TIM3 restored production of IFNγ and TNFα, resulting in a reduction of serum HBs Ag and inhibition of HBV replication (56) ( Figure 1 ).

Although the number of blood iNKT cells is reduced in patients with chronic HBV-related cirrhosis, circulating iNKT cells are hyperactive during transition from chronic HBV to cirrhosis, as shown by increased expression of CD25 and several cytokines (57). This reduction in blood iNKT cell number was probably due to iNKT migration to the liver, because proliferation or apoptosis remained unaffected. Isolated peripheral iNKT cells from these patients were able to activate an HSC cell line in vitro and promoted proliferation of hepatocytes, indicating that in a chronic HBV inflammatory background, iNKT cells may eventually contribute to progression to liver cirrhosis (57, 58) ( Figure 1 ).

The frequency of iNKT cells was significantly reduced in the blood of HCV-seropositive patients (59, 60), while their frequency increased in the liver (61), possibly indicating that iNKT cells migrate from the periphery to the liver. Hepatic iNKT cells from patients with chronic HCV infection produced high levels of IFNγ, while they did not produce Th2-related cytokines, such as IL4 or IL13. Interestingly, iNKT cells from patients with HCV-related cirrhosis showed a marked increase in the production of pro-fibrotic IL4 and IL13, suggesting that iNKT cell effector functions are modified during progression of chronic viral hepatitis to cirrhosis. In addition, expression of CD1D is upregulated in cirrhotic livers, which indicates that continuous lipid presentation may induce a switch in cytokine production from iNKT cells during the course of chronic viral hepatitis that contributes to the development of hepatic cirrhosis (61). Nonetheless, in a humanized mouse model of HCV infection, IFNα treatment triggered production of IFNγ by iNKT cells, which lead to inhibition of HCV replication (62) ( Figure 2 ).

MAIT cells recognize antigens presented by a molecule called MR1, which is expressed in antigen presenting cells (APCs) (79). The frequency of MAIT cells was increased in patients’ NAFLD livers (80), whereas it was decreased in patients’ blood (80–82); interestingly, patients with cirrhosis showed decreased MAIT cell frequency in the liver (81), indicating that MAIT cell accumulation in the liver may depend on the stage of the disease. Notably, in cirrhotic livers, MAIT cells were relocated from the sinusoids to the fibrotic septa, possibly indicating interactions of MAIT cells with fibrogenic cells. Indeed, activated MAIT cells increased proliferation of hepatic myofibroblasts, which accumulate in sites of liver injury, in an MR1-dependent way, while they also stimulated secretion of pro-inflammatory cytokines by hepatic fibrogenic cells and macrophages through TNFα (81). MAIT cells from blood samples showed enhanced activation, according to the expression of the activation markers CD69 and CD25, and increased expression of the chemokine receptor CXCR6 (80, 81). CXCR6 is involved in the recruitment of immune cells in the liver (83) and the increased levels of CXCR6 in MAIT cells suggest that circulating MAIT cells may migrate to the liver in patients with NAFLD.

MAIT cells from the liver of mice with MCD-induced NAFLD stimulated with Phorbol 12-myristate 13-acetate (PMA) and ionomycin produced increased levels of anti-inflammatory cytokines, such as IL4 and IL10, and lower levels of the pro-inflammatory cytokines IFNγ and TNFα (80, 84, 85), indicating a switch to Th2 cytokine production. Mr1 ^−/− mice that lack MAIT cells, developed NAFLD with more severe hepatic steatosis and increased lipid accumulation (80), accompanied with increased gene expression of pro-inflammatory cytokines, such as TNFα, and increased number of M1 macrophages (80). However, Mr1^−/− mice were protected from CCL₄-induced liver fibrosis, although liver damage was comparable to their WT counteparts (81). M1 macrophage polarization was enhanced by pro-inflammatory cytokines (IFNγ, TNFα), while anti-inflammatory cytokines (IL4, IL10) lead to differentiation of M2 macrophages (86). M2 macrophages are associated with reduced liver damage in mice and humans with NAFLD (66) and M2 differentiation is reduced in Mr1^−/− mice (80, 84), while MAIT cells isolated from human NAFLD patients promoted M2 polarization, probably through IL4 production (80, 84). Taken together, these results indicate that MAIT cells regulate the fate of macrophages and contribute to the resolution of early inflammation during NAFLD development, although they may promote liver fibrosis when disease progresses to cirrhosis ( Figure 3 ).

Similar to MAIT cells, an accumulation of iNKT cells in the liver (87) and reduction of iNKT cells in patients’ blood (82, 88) has been observed in patients with NAFLD. The frequency of hepatic iNKT cells is positively correlated with steatosis severity (89). Hepatic iNKT cells from NAFLD patients are in an activated status, according to the increased expression of CD69 (87). Isolation of human hepatic iNKT cells from patients with NAFLD and stimulation with α-GalCer (89) in vitro showed increased production of IFNγ (87, 89) compared to healthy individuals. Increased hepatic expression of CD1d has been observed in NAFLD patients (87, 88), indicating that presentation of lipid antigens to iNKT cells may be enhanced, leading to increased activation of iNKT cells.

Murine models of obesity and NAFLD using the leptin-deficient mice ob/ob, showed that development and progression of NAFLD was associated with a reduction in iNKT cell number (90). Adoptive transfer of iNKT cells in ob/ob mice led to decreased hepatic steatosis and improved glucose tolerance (91). Administration of choline-deficient diet (CDD) in mice, which contributes to NAFLD development, promoted steatosis characterized by loss of iNKT cells (84). In addition, in a high-fat (HF) diet murine model, mice developed NAFLD and the frequency of iNKT cells decreased specifically in the liver (85, 92), probably due to increased apoptosis; however, the remaining iNKT cells showed increased production of IFNγ and TNFα (92). In the HF diet model, the increased apoptosis of iNKT cells contributed to insulin resistance and hepatic steatosis (92). A possible mechanism that leads to iNKT cell apoptosis is through the Tim-3/Galectin-9 signaling pathway. Tim-3 expression was significantly increased in iNKT cells, and the upregulation of Tim-3 was correlated with progression of steatosis (93). Interestingly, Tim-3⁺ iNKT cells were more prone to apoptosis compared to Tim-3⁻ iNKT cells.

iNKT cell number was increased in the liver of mice with NASH. iNKT cells expanded in mice fed with MCD diet (94), characterized by an increased production of IFNγ, OPN, and IL15 (94, 95). Although the early phase of steatohepatitis is associated with lower frequency of iNKT cells (84, 92), iNKT cell expansion with concomitant up-regulation of IL15 indicates advanced NASH (84, 94). In addition, in MCD-fed mice, progression of NASH was associated with activation of the Hh pathway (96), which lead to the production of Hh-regulated fibrogenic factors (OPN) and the chemokine CXCL16 (iNKT cell chemoattractant) (97), resulting in the recruitment and accumulation of iNKT cells in the liver (87, 88). Administration of MCD diet in CD1d^−/− mice that lack iNKT cells, showed significant attenuation of fibrogenesis and iNKT cell depletion rescued from fibrosis and NASH (88). In CD-HFD-fed mice, the increased number of iNKT cells was associated with enhanced uptake of fat by hepatocytes, activation of hepatic stellate cells (HSC) and induced steatosis (98). Increased numbers and activation of T cells (CD4⁺, CD8⁺) was observed in CD-HFD mice with enhanced secretion of IL17 by CD4⁺ T cells and TNFα by CD8⁺ T cells (98). β2m^−/− mice, which lack CD8⁺ and NKT cells, fed with CD-HFD showed no liver damage, fibrosis and NASH and lower levels of cholesterol and triglyceride compared to CD-HFD-fed WT mice. Depletion of CD8⁺ T cells using anti-CD8 rescued from CD-HFD-induced liver damage with no change in cholesterol levels (98), but iNKT cells were not affected and promoted fat uptake from hepatocytes. light signaling in hepatocytes promotes lipid uptake and Light^−/− CD-HFD-fed mice showed reduced liver damage. Interestingly, iNKT cells were decreased in Light^−/− CD-HFD-fed mice, while the number of CD8⁺ T cells was not affected (98) compared with CD-HFD-fed WT mice. Blocking LTβR signaling in CD-HFD-fed WT mice did not rescue from liver damage. The phenotype of CD-HFD-fed Light^−/− mice was associated with reduction of iNKT cell number. Therefore, iNKT cells contribute to initiation of liver damage, interact with CD8⁺ T cells through light and encumber liver damage in CD-HFD mice. CD1d^−/− mice fed with HFHC were protected from NASH, did not gain weight, had normal levels of ALT (liver damage marker), fasting glucose, a-SMA (fibrosis marker) and lower or no steatosis (99). Importantly, iNKT cells were enriched in patients with NASH (88, 98,). Therefore, all this evidence supports that iNKT cells promote initiation and progression of liver fibrosis ( Figure 3 ).

Studies using human blood and HCC samples showed that MAIT cells were significantly decreased in HCC compared with adjacent tissue (112, 113). Circulating MAIT cells from the blood expressed higher levels of the exhaustion marker PD-1, suggesting a deficiency of MAIT cells in HCC patients (114). Normally, MAIT cells produce Th1- and Th17-related cytokines (112, 115, 116). Stimulation of MAIT cells isolated from HCC samples and blood with IL-2/IL-18 and PMA/ionomycin for 24 hours, showed an increased production of IL-6 and decreased IFNγ, indicating that the function of MAIT cells is impaired (114). In addition, stimulation of HCC MAIT cells with PMA/ionomycin for 5 hours, showed an increased production of IL-8 (117), a cytokine that promotes tumor progression and angiogenesis. MAIT cells, normally, are able to kill target cells (118), but in HCC, their ability to produce granzyme B and perforin is decreased (117). Infiltration of MAIT cells in HCC is reduced due to the lower expression of the chemokine receptors, CXCR6, CCR6, and CCR9 (117). The reduced presence of MAIT cells in the tumor microenvironment is, also, associated with apoptosis. Single-cell analysis from HCC samples revealed that MAIT cells express genes related to apoptotic pathways (114). Therefore, the number of MAIT cells is reduced and the remaining MAIT cells are dysfunctional in HCC ( Figure 3 ).

iNKT cell number is reduced in late stages of HCC (stages III, IV) in tissue (119) and blood samples (120, 121) from HCC patients. Expression of inhibitory receptors in iNKT cells, such as TIM3, CTLA4, PDL1, is increased and PD1⁺ iNKT cells produce lower amounts of IFNγ showing an exhausted phenotype and impaired function (121, 122). This impaired function may happen due to chronic TCR stimulus; Indeed, there is a recent study showing that long-chain Acylcarnitines (LCACs) derived from tumor cells can lead to impaired function of iNKT cells through TCR signalling (122). Blocking the PD1/PDL1 pathway using anti-PD1 blockade improved production of cytokines (IFNγ, TNFα) from iNKT cells after PMA/ionomycin stimulation (121). Patients with increased presence of iNKT cells had a better overall survival (OS) compared to those with lower numbers of iNKT cells (123, 124). Radiotherapy in patients with HCC, increased the number of iNKT cells after 3 months and patients with increased iNKT cell number achieved higher 2-year OS (125). Adoptive transfer of in vitro expanded autologous iNKT cells in patients with HCC reduced the expression level of the HCC marker a-fetoprotein; in addition, both overall and progression-free survival increased in four out of ten patients, while one patient survived without tumor recurrence, indicating that therapy using iNKT cells is promising and safe and may be combined with other therapies against HCC (126).

In mouse cancer models, iNKT cells promote liver damage, although the mechanisms related to HCC development are not clear (127). Murine studies using an orthotopic HCC mouse model showed that activation of iNKT cells with aGalCer suppressed tumor development, while the NK cell cytotoxic activity increased (128). In the transgenic L-type pyruvate kinase Lpk-myc⁺ HCC mouse model, depletion of iNKT cells using anti-NK1.1 accelerated progression of liver tumors induced by β-catenin (129). Adoptive transfer of ex vivo activated iNKT cells suppressed HCC development in mice (130). In Fkbp5^−/− mice treated with DEN, progression of HCC was inhibited and T cells, including iNKT cells, were significantly increased compared to WT (131). Hepatic iNKT, NK, and T cells express CXCR6 (83, 132). Cxcr6^−/− mice, which are characterized by a reduced number of hepatic iNKT cells, treated short-term with CCL₄ or fed with MCD diet were protected from fibrosis (83)., while adoptive transfer of iNKT cells but conventional CD4⁺ T cells enhanced fibrogenesis (83). However, Cxcr6^−/− mice treated with DEN developed more tumors than WT mice, while the number of iNKT cells and their ability to produce IFNγ was decreased (133). Adoptive transfer of CD4⁺ T or iNKT cells in Cxcr6^−/− DEN mice reduced the number of senescent cells, indicating that during HCC development, CD4⁺ and iNKT cells participate in the surveillance of senescent cells (133). Surveillance of senescent cells is associated with increased amounts of IFNγ and TNFα produced by iNKT cells (134, 135). Treatment with aGalCer reduced the number of senescent hepatocytes (133). Importantly, HCC cells produced TGFβ and suppressed the anti-oncogenic functions of iNKT cells and T cells (136). In contrast, in CD-HFD fed mice, iNKT cells contributed to NASH and HCC development through production of Light and enhanced lipid uptake from hepatocytes. Light^−/− mice were protected from NASH and HCC with no increase in ALT and cholesterol levels and no change in the number and activation of CD8⁺ and iNKT cells (98). Importantly, CD-HFD causes severe steatosis and fibrosis before HCC, whereas DEN-mediated HCC does not involve fibrogenesis. Taken together, these results indicate that iNKT cells contribute to HCC tumorigenesis through promotion of hepatic fibrosis; however, iNKT cells may have anti-oncogenic functions in established HCC tumors ( Figure 3 ).