It has been previously reported that depletion of NK cells had no significant effect on hepatic I/R injury, as demonstrated by unchanged liver function assays and infiltrated MPO content into the liver, suggesting that NK cells are not recruited to the liver after reperfusion (32). However, there is accumulating direct evidence that NK cells are involved in the development of the pathophysiology of hepatic I/R. In an experiment in which a rat was subjected to 1 hour of right hepatic lobe ischemia and the remaining liver was excised, a significant increase in NK cell infiltration into the rat liver parenchyma was detected after reperfusion for 2 hours (33), and depletion of NK cells could significantly decrease hepatic CXCL-2 expression, reduce neutrophil infiltration into the liver, and attenuate hepatic I/R injury levels (34). Similarly, the mRNA level of NKG2D, an activating receptor for NK cells, rapidly increased in allografts (LEW to SD rats), indicating a significant activation of NK cells, while donor livers that were pretreated with anti-asialo monosialotetrahexosylganglioside (AAGM1) to deplete NK cells, showed a significant decrease in not only NKG2D expression levels but also hepatic cytokines (TNF-α, IL-1 β, IL-6, and IL-8) as well as secretion levels of cytolytic molecules (perforin, granzyme B), along with a reduction in early neutrophil infiltration (31). In contrast to the depletion of NK cells described above, administration of soluble pro-inflammatory IL-15/IL-15Rα complexes increased the absolute number of NK cells in the liver of IRF-1 knockout mice after orthotopic liver transplantation, accompanied by increased expression of cytotoxic effector molecules (NKG2D, granzyme B, and perforin) and inflammatory cytokines (IFN-γ, IL-6, and TNF-α), eventually resulting in worsening liver injury and decreased survival (35). NK cell activation in hepatic I/R relied on the hydrolysis of ADP to AMP by CD39, and CD39 deletion reduces IFN-γ secreted by NK cells to limit hepatic I/R injury (5). To be specific, CD39-deficient mice exhibited reduced pro-inflammatory cytokines in serum 3 hours after reperfusion, and also showed reduced hepatocyte injury and necrosis area after 24 hours of reperfusion (5). In addition, TRAIL expression on NK cells was upregulated following hepatic I/R in mice and exerted marked protective effects such as reduced serum transaminases, histological necrosis, neutrophil infiltration, and IL-6 levels in serum, whereas TRAIL-null NK cells exhibited higher cytotoxicity and significantly increased secretion of IFN-γ, indicating that TRAIL could confine further liver injury by blocking NK cell activation (36). IFN-γ secreted by NK cells can upregulate the expression of Fas in hepatocytes, while IL-18 released by injured Kupffer cells in hepatic I/R injury could increase the expression level of FasL (Fas ligand) in NK cells (37, 38). Therefore, the inflammation and liver damage are further amplified under this complex positive feedback. As can be seen from the above literature, IFN-γ secretion by NK cells plays a pivotal role in hepatic I/R, and the mechanism of its secretion is largely regulated by Tbox transcription factors such as T-bet and Eomes (39), which is tightly associated with NK cell development. NK cells can not only aggravate hepatic I/R injury by producing IFN-γ, but also increase the synthesis of IL-17, which could enhance the recruitment of neutrophils into the injured liver (34). This study provided strong proof that neutralization of IL-17 attenuated hepatic I/R injury in Rag1 knockout mice (34).

The immunological process of donor NK cells entering the recipient bloodstream and recipient NK cells flowing into the donor graft with the bloodstream occurs early after liver transplantation, where donor NK cells migrate out of the liver and are detected in the recipient’s circulation generally for 2 weeks, but there are also possibilities that graft NK cells will persist for decades (40). Thirteen genes were found to be significantly overexpressed in NK cells from immune-tolerant recipients of liver transplantation, suggesting that NK cells may be involved in the induction of immune tolerance (41). In fact, recipient-derived NK cells and donor-derived NK cells could play opposed roles in liver graft tolerance, with the former tending to reject allografts and the latter mainly promoting tolerance (40, 42). Recipient-derived NK cells produced IFN-γ after entering liver grafts, which predisposed to graft non-function (43). Correspondingly, either depletion of NK cells or reduction of IFN-γ production could be capable of promoting increased graft survival rate (43). According to clinical trials, recipient hypertension can further activate NK cells and lead to moderate to severe I/R injury, which may markedly increase the incidence of early allograft dysfunction and reduce the 6-month survival rate of grafts (44, 45). In contrast, after liver transplantation, treatment with anti-inflammatory factor IL-10 given to the recipient reduced the NK recruitment of chemokines CXCL-9, CXCL-10, and CXCL-11 produced by activated Dendritic cells, leading to a decrease in the number of recipient NK cells entering the liver graft in a clinical study (46). Meanwhile, a decrease of pro-inflammatory IL-12 also induced a shift in recipient NK cells to a tolerogenic phenotype with concomitant downregulation of NK-activating receptors, and reduction of cytotoxicity and cytokine production (47), which further limits the rejection of transplanted liver mediated by recipient NK cells. Of note, the rejection of ABO-incompatible liver transplantation by NK cells was particularly pronounced in clinical practice. It has been reported that a large number of NK cells in recipient peripheral blood was the only risk factor for the induction of ischemic biliary tract disease after ABO-incompatible adult living donor liver transplantation. This may be explained that recipient NK cells could recognize various NK cell ligands on the donor endothelial cells after flowing into the liver graft, and the ABO antigen was abundantly expressed on the endothelial cells of the transplant graft, thereby directly producing cytotoxicity and resulting in decreased graft survival (48, 49). Besides, there is a clinical study suggesting that recipient-derived NK cells are reduced but retain the robust expression of NK cell receptors such as NKG2D in the early stage of pediatric liver transplantation, which may be closely related to the increase of acute graft rejection episode (50).

As previously reported, infusion of donor liver NK cells can alleviate acute rejection of rat liver allografts and prolong graft survival (51), revealing the important function of donor NK cells in immune tolerance. It has also been reported in clinical research that bone marrow-derived mesenchymal stromal cell infusion induces the increase of donor-derived NK cells, which promotes the establishment of a pro-tolerance graft environment that persists in a long time (52). Hepatic NK cells from the donors played a major role in promoting graft tolerance, possibly through direct killing of recipient activated T cells and immature Dendritic cells recruited to the transplanted liver (40, 53). But this requires more experimental evidence to further confirm.

In general, there were two commonly used depletion antibodies for NK cells, AAGM1 and anti-NK1.1 (34, 54). AAGM1 causes certain membrane damage that gives rise to loss of NK function, and is effective in depleting NK cells in various mouse strains, but it may also interfere with other lymphocyte subsets that express GM1 (54). Treatment with the anti-NK1.1 antibody PK136 depletes NK cells in the liver and in a subset of NKT and γδ T cells (34). However, anti-NK1.1-mediated NK cell depletion is still the mainstay of analysis of NK cells in the liver (34). In a phase I/II trial, NK cells are depleted by a combination of anti-CD3 and anti-CD7 antibodies to treat acute graft-versus-host disease (55).

It has been reported that transforming growth factor-β, IL-10, tryptophan catabolites, prostaglandin E₂, dickkopf-related protein 2, indoleamine 2,3-dioxygenase, soluble HLA-G, soluble NKG2D ligands, and galactin-3 (soluble inhibitory receptor for NKp30) could be viewed as the inhibitors of NK cells and their receptors, downregulating cytotoxic activity and the capabilities of secreting IFN-γ (56). For example, corticosteroids are utilized to significantly downregulate the expression of activated receptors NKp30 and NKp46 in clinical research, and NKG2D blockade can also reduce the incidence of allograft rejection (55). However, there are still many aspects of validation necessary to apply the above methods to the clinic.

It has been reported that multiple signaling pathways are involved in the activation of NK cells and mediate the important role of NK cells in liver I/R. For example, activated AMPK, deletion of FoxO1 gene, and inhibition of SREBP all could downregulate the number of mature terminally differentiated NK cells, inhibit NK cell cytotoxicity, and reduce granzyme B and IFN-γ production expression levels (57, 58). But these pathways are far from well-studied and full of controversy and contradictions. At present, the mTOR pathways have been widely and relatively well studied, and the metabolic signaling mediated by it is generally considered to be an important node in NK cell development. mTOR is a ubiquitous serine/threonine kinase that requires two regulatory proteins, raptor and rictor, to form functionally distinct mTOR complexes 1 and 2 (mTORC1 and 2), respectively (59). mTORC1 plays a major role among mTOR pathways, whereas mTORC2 can negatively regulate mTORC1 activity to some extent by inhibiting STAT5-mediated expression of the amino acid transporter SLC7A5 (60, 61). IL-15 stimulated mTORC1 through the Jak1 and PI3K/Akt signaling axes, and activated mTORC1 promoted NK precursor development (62, 63). Moreover, mTOR activated by the kinase PDK1, downstream of IL-15 signaling, was found to be required for E4BP4 expression in bone marrow NK cells, and E4BP4 can promote Eomes transcription, thereby playing an indispensable role in NK cell development (15). Since mTOR activity was inhibited after knockdown of PDK1 in NK cells, NK development was impeded at an early stage (64). When mTOR was specifically knocked out in NK cells, the number of NK cells in peripheral blood was drastically reduced (65). Moreover, the use of the mTOR-selective inhibitor rapamycin broadly inhibited the expression levels of IFN-γ, perforin, and granzyme B secreted by NK cells (66, 67). In a rat I/R study, rapamycin significantly reduced parenchymal infiltration of NK cells, liver histological damage, and mortality (33), which formed strong support for the above observations.