HLA-G inhibits rolling adhesion of activated human NK cells on porcine endothelial cells.

Human NK cells adhere to and lyse porcine endothelial cells (pEC) and therefore may contribute to the cell-mediated rejection of vascularized pig-to-human xenografts. Since MHC class I molecules inhibit the cytotoxic activity of NK cells, the expression of HLA genes in pEC has been proposed as a potential solution to overcome NK cell-mediated xenogeneic cytotoxicity. HLA-G, a minimally polymorphic HLA class I molecule that can inhibit a wide range of NK cells, is an especially attractive candidate for this purpose. In this study we tested whether the expression of HLA-G on pEC inhibits the molecular mechanisms that lead to adhesion of human NK cells to pEC and subsequent xenogeneic NK cytotoxicity. To this end two immortalized pEC lines (2A2 and PED) were stably transfected with HLA-G1. Rolling adhesion of activated human NK cells to pEC monolayers and xenogeneic cytotoxicity against pEC mediated by polyclonal human NK lines as well as NK clones were inhibited by the expression of HLA-G. The adhesion was partially reversed by masking HLA-G on pEC with anti-HLA mAbs or by masking the HLA-G-specific inhibitory receptor ILT-2 on NK cells with the mAb HP-F1. The inhibition of NK cytotoxicity by HLA-G was only partially mediated by ILT-2, indicating a role for other unknown NK receptors. In conclusion, transgenic expression of HLA-G may be useful to prevent human NK cell responses to porcine xenografts, but is probably not sufficient on its own. Moreover, the blocking of rolling adhesion by HLA-G provides evidence for a novel biological function of HLA molecules.

Inhibition of human NK cell-mediated cytotoxicity by exposure to ammonium chloride.

Ammonium-chloride-containing solutions (AC) are routinely used to lyse red blood cells during preparation of PBMC. Although exposure to AC has been described to affect the ultrastructural appearance of large granular lymphocytes and to temporarily inhibit cytolytic activity of PBMC preparations, the cellular basis of this phenomenon has not been studied. Here, the inhibitory effect of AC on human CTL and NK-mediated cytotoxicity has been analyzed in 4-h 51Cr-release assays. The results show that NK killing of K562 leukemia cells and xenogeneic endothelial cells is inhibited by AC exposure. The effect is dose-dependent and reversible, because recovery of cytotoxicity is observed within 15 h of re-culturing. AC does not reduce the viability of NK cells and the inhibitory effect is not mediated by the exhaustive release of granzymes upon AC treatment. In contrast, antigen-specific CTL killing of EBV-transformed B-lymphoblastoid cell lines and xenogeneic PHA lymphoblasts was less sensitive to AC and data are presented suggesting that FasL-induced apoptosis is not inhibited by AC. In conclusion, perforin-mediated NK killing is AC-sensitive whereas CTL killing and FasL-mediated killing appear to be AC-resistant. Therefore, AC represents a powerful tool to study different mechanisms of cell-mediated cytotoxicity and may be helpful in assessing antigen-specific CTL cytotoxicity without the influence of NK cell-mediated background killing.

Porcine aortic endothelial cells transfected with HLA-G are partially protected from xenogeneic human NK cytotoxicity.

In this study we tested whether the expression of HLA-G protects porcine endothelial cells (PEC) from the lysis mediated by human natural killer (NK) cells. Because HLA-E is not present in PEC, this model provides an ideal tool to study the direct role of HLA-G in NK inhibition. Immortalized porcine aortic endothelial cells (PED) were stably transfected with a vector coding for the HLA-G1 protein and surface expression was demonstrated by flow cytometry analysis. Although the adhesion of human NK cells to PED was not compromised by HLA-G, the expression of HLA-G partially protected PED from the lysis mediated by polyclonal NK lines derived from different donors. A decrease of the surface expression of HLA-G on PED corresponded to a loss of the capacity of PED to inhibit NK cytotoxicity, indicating that the surface density of HLA-G molecules must exceed a certain threshold to protect target cells. In summary, these data show that HLA-G, independent from the presence of HLA-E, can only partially and inefficiently protect PED from human NK cell-mediated cytotoxicity. Because ILT-2/LIR-1 expression did not correlate with HLA-G mediated inhibition, we hypothesize that other yet unidentified receptors expressed by peripheral blood NK cells are involved in the recognition of HLA-G.