Humans differ from other hominids in lacking an activating NK cell receptor that recognizes the C1 epitope of MHC class I.

Modulation of human NK cell function by killer cell Ig-like receptors (KIR) and MHC class I is dominated by the bipartite interactions of inhibitory lineage III KIR with the C1 and C2 epitopes of HLA-C. In comparison, the ligand specificities and functional contributions of the activating lineage III KIR remain poorly understood. Using a robust, sensitive assay of KIR binding and a representative panel of 95 HLA class I targets, we show that KIR2DS1 binds C2 with ~50% the avidity of KIR2DL1, whereas KIR2DS2, KIR2DS3, and KIR2DS5 have no detectable avidity for C1, C2, or any other HLA class I epitope. In contrast, the chimpanzee has activating C1- and C2-specific lineage III KIR with strong avidity, comparable to those of their paired inhibitory receptors. One variant of chimpanzee Pt-KIR3DS2, the activating C2-specific receptor, has the same avidity for C2 as does inhibitory Pt-KIR3DL4, and a second variant has ~73% the avidity. Chimpanzee Pt-KIR3DS6, the activating C1-specific receptor, has avidity for C1 that is ~70% that of inhibitory Pt-KIR2DL6. In both humans and chimpanzees we observe an evolutionary trend toward reducing the avidity of the activating C1- and C2-specific receptors through selective acquisition of attenuating substitutions. However, the extent of attenuation has been extreme in humans, as exemplified by KIR2DS2, an activating C1-specific receptor that has lost all detectable avidity for HLA class I. Supporting such elimination of activating C1-specific receptors as a uniquely human phenomenon is the presence of a high-avidity activating C1-specific receptor (Gg-KIR2DSa) in gorilla.