Characterization of a dipeptide motif regulating IFN-gamma receptor 2 plasma membrane accumulation and IFN-gamma responsiveness.

The IFN-gammaR complex is composed of two IFN-gammaR1 and two IFN-gammaR2 polypeptide chains. Although IFN-gammaR1 is constitutively expressed on all nucleated cells, IFN-gammaR2 membrane display is selective and tightly regulated. We created a series of fluorescent-tagged IFN-gammaR2 expression constructs to follow the molecule's cell surface expression and intracellular distribution. Truncation of the receptor immediately upstream of Leu-Ile 255-256 (254X) created a receptor devoid of signaling that overaccumulated on the cell surface. In addition, this truncated receptor inhibited wild-type IFN-gammaR2 activity and therefore exerted a dominant negative effect. In-frame deletion (255Delta2) or alanine substitution (LI255-256AA) of these amino acids created mutants that overaccumulated on the plasma membrane, but had enhanced function. Single amino acid substitutions (L255A or I256A) had a more modest effect. In-frame deletions upstream (253Delta2), but not downstream (257Delta2), of Leu-Ile 255-256 also led to overaccumulation. A truncation within the IFN-gammaR2 Jak2 binding site (270X) led to a mutant devoid of function that did not overaccumulate and did not affect wild-type IFN-gammaR2 signaling. We have created a series of novel mutants of IFN-gammaR2 that have facilitated the identification of intracellular domains that control IFN-gammaR2 accumulation and IFN-gamma responsiveness. In contrast to IFN-gammaR1, not only dominant negative, but also dominant gain-of-function, mutations were created through manipulation of IFN-gammaR2 Leu-Ile 255-256. These IFN-gammaR2 mutants will allow fine dissection of the role of IFN-gamma signaling in immunity.