Interactions Between KIR3DS1 and HLA-F Activate Natural Killer Cells to Control HCV Replication in Cell Culture.

Killer-cell immunoglobulin-like receptors (KIRs) are transmembrane glycoproteins expressed by natural killer (NK) cells. Binding of KIR3DS1 to its recently discovered ligand, HLA-F, activates NK cells and has been associated with resolution of hepatitis C virus (HCV) infection. We investigated the mechanisms by which KIR3DS1 contributes to the antiviral immune response. Using cell culture systems, mice with humanized livers, and primary liver tissue from HCV-infected individuals, we found that the KIR3DS1 ligand HLA-F is up-regulated on HCV-infected cells, and that interactions between KIR3DS1 and HLA-F contribute to NK cell-mediated control of HCV. Strategies to promote interaction between KIR3DS1 and HLA-F might be developed for treatment of infectious diseases and cancer.

Rhesus macaque inhibitory and activating KIR3D interact with Mamu-A-encoded ligands.

Specific interactions between killer cell Ig-like receptors (KIRs) and MHC class I ligands have not been described in rhesus macaques despite their importance in biomedical research. Using KIR-Fc fusion proteins, we detected specific interactions for three inhibitory KIRs (3DLW03, 3DL05, 3DL11) and one activating KIR (3DS05). As ligands we identified Macaca mulatta MHC (Mamu)-A1- and Mamu-A3-encoded allotypes, among them Mamu-A1*001:01, which is well known for association with slow progression to AIDS in the rhesus macaque experimental SIV infection model. Interactions with Mamu-B or Mamu-I molecules were not found. KIR3DLW03 and KIR3DL05 differ in their binding sites to their shared ligand Mamu-A1*001:01, with 3DLW03 depending on presence of the α1 domain, whereas 3DL05 depends on both the α1 and α2 domains. Fine-mapping studies revealed that binding of KIR3DLW03 is influenced by presence of the complete Bw4 epitope (positions 77, 80-83), whereas that of KIR3DL05 is mainly influenced by amino acid position 77 of Bw4 and positions 80-83 of Bw6. Our findings allowed the successful prediction of a further ligand of KIR3DL05, Mamu-A1*002:01. These functional differences of rhesus macaque KIR3DL molecules are in line with the known genetic diversification of lineage II KIRs in macaques.

Killer Ig-like receptor ligand mismatch directs NK cell expansion in vitro.

NK cell alloreactivity is governed largely through failure to detect self-HLA class I ligands by the clonally distributed inhibitory killer Ig-like receptors (KIR) expressed on the NK cell surface. In this study, we investigated the extent to which HLA class I-KIR interactions influence human NK cell proliferation in the allogeneic setting. NK cells were cultured with feeder cells either matched or mismatched for inhibitory KIR ligands, the latter lacking one or more ligands present in the NK cell donor. In postculture cytotoxicity assays, the ability of polyclonal NK cells to kill KIR ligand-mismatched targets was enhanced by exposure to appropriately mismatched feeder cells in prior culture. This corresponded with an increased frequency of postculture donor NK cells expressing a given inhibitory KIR if the allogeneic feeder cells used in the culture lacked its ligand. Similar skewing of KIR distribution was seen in clonally expanded NK cells. Finally, a flow cytometry-based proliferation assay was used to show KIR-specific NK cell division in response to missing self. The findings demonstrate that KIR distribution among a population of alloresponding peripheral blood NK cells is shaped by the HLA class I environment.