The ability of H-2Dd molecule to affect natural resistance to hemopoietic allografts is an intrinsic property shared by Ddm1 but not Ld

Impaired MHC class I (H-2Dd)-mediated protection against Ly-49A+ NK cells after amino acid substitutions in the antigen binding cleft

The MHC class I molecule H-2Dd (Dd) acts as a ligand for the inhibitory NK cell receptor Ly-49A. We have constructed altered Dd molecules by site-directed mutagenesis, replacing residues with the corresponding amino acids from the Db molecule, which fails to inhibit via Ly-49A. Mutations at positions 73 and 156 (DdS73WD156Y) impaired the protective effect of the Dd molecule, as evaluated by testing lymphoma cells transfected with the mutant gene for sensitivity to killing by Ly-49A+ NK cells in vitro and rejection by NK cells in vivo. The altered residues form a hydrophobic ridge across the floor of the antigen binding cleft. A mutation in the alpha helix of the alpha2 domain, facing the solvent and without direct contact with the peptide (DdA150S) had no effect. Dd recognition by Ly-49A+ NK cells is considered to be peptide dependent, but not peptide specific. Our results indicate that alterations of residues buried in the antigen binding cleft can induce changes in peptide binding patterns and/or conformational changes in the Dd molecule that make the trimolecular complex less permissive for inhibition of Ly-49A+ NK cells.

The α2 Domain of H-2Dd Restricts the Allelic Specificity of the Murine NK Cell Inhibitory Receptor Ly-49A

Mouse NK lymphocytes express Ly-49 receptors, which inhibit cytotoxicity upon ligation by specific MHC I molecules on targets. Different members of the lectin-like mouse Ly-49 receptor family recognize distinct subsets of murine H-2 molecules, but the molecular basis for the allelic specificity of Ly-49 has not been defined. We analyzed inhibition of natural killing by chimeric MHC I molecules in which the α1, α2, or α3 domains of the Ly-49A-binding allele H-2Dd were exchanged for the corresponding domains of the nonbinding allele H-2Db. Using the Ly-49A-transfected rat NK cell line, RNK-mLy-49A.9, we demonstrated that the H-2Dd α2 domain alone accounts for allelic specificity in protection of rat YB2/0 targets in vitro. We also showed that the H-2Dd α2 domain is sufficient to account for the allele-specific in vivo protection of H-2b mouse RBL-5 tumors from NK cell-mediated rejection in D8 mice. Thus, in striking contrast to the α1 specificity of Ig-like killer inhibitory receptors for human HLA, the lectin-like mouse Ly-49A receptor is predominantly restricted by the H-2Dd α2 domain in vitro and in vivo.

Role of murine NK cells and their receptors in hybrid resistance

Hybrid resistance refers to the rejection of parental strain bone marrow cells by natural killer cells of mice that are F1 hybrids derived from two inbred parental strains. This pattern of rejection is not seen in solid organ transplants. Progress in understanding this exception to the laws of transplantation genetics has occurred with the recent discovery of negative signaling receptors for MHC class I molecules. In the last year the discovery of natural killer cell subsets with non-overlapping inhibitory receptors for parental class I molecules has provided an explanation for hybrid resistance. In some instances, however, positive rather than negative signaling seems to be the basis for rejection of allogeneic as well as parental marrow cell grafts.

Influence of glycosylphosphatidylinositol-linked H-2Dd molecules on target cell protection and natural killer cell specificity in transgenic mice

The expression of certain major histocompatibility complex (MHC) class I ligands on target cells is one important determinate of their susceptibility to lysis by natural killer (NK) cells. NK cells express receptor molecules that bind to MHC class I. Upon binding to their MHC class I ligand, the NK cell is presumed to receive a signal through its receptor that inhibits lysis. It is unclear what role the MHC class I molecules of the effector and target cells play in signaling to the NK cell. We have investigated the role of the cytoplasmic and transmembrane domains of MHC class I molecules by producing a glycosylphosphatidylinositol (GPI)-linked H-2Dd molecule. The GPI-linked H-2Dd molecule is recognized by H-2Dd-specific antibodies and cytotoxic T lymphocytes. Expression of the GPI-linked H-2Dd molecule on H-2b tumor cells resulted in protection of the tumor cells after transplantation into D8 mice (H-2b, H-2Dd) from rejection by NK cells. In addition, NK cells from mice expressing the GPI-linked H-2Dd molecule as a transgene were able to kill nontransgenic H-2b lymphoblast target cells. The GPI-linked MHC class I molecule was able to alter NK cell specificity at the target and effector cell levels. Thus, the expression of the cytoplasmic and transmembrane domains of MHC class I molecules are not necessary for protection and alteration of NK cell specificity.