Abstract: Some aspects of this invention are based on the recognition that reversible protein multimers in which monomeric proteins are conjugated to a carrier molecule via chelation complex bonds are stable under physiological conditions and can be dissociated in a controlled manner under physiological, nontoxic conditions. Accordingly, such protein multimers are useful for a variety of in vitro, ex vivo, and in vivo application for research, diagnostics, and therapy. Some aspect of this invention provide reversible MHC protein multimers, and methods of using such multimers in the detection and/or isolation of specific T-cells or T-cell populations. Because reversible MHC multimers can efficiently be dissociated, the time of MHC binding to T-cell receptors, and, thus, T-cell receptor-mediated T-cell activation can be minimized.

Abstract: Some aspects of this invention are based on the recognition that reversible protein multimers in which monomeric proteins are conjugated to a carrier molecule via chelation complex bonds are stable under physiological conditions and can be dissociated in a controlled manner under physiological, nontoxic conditions. Accordingly, such protein multimers are useful for a variety of in vitro, ex vivo, and in vivo application for research, diagnostics, and therapy. Some aspect of this invention provide reversible MHC protein multimers, and methods of using such multimers in the detection and/or isolation of specific T-cells or T-cell populations. Because reversible MHC multimers can efficiently be dissociated, the time of MHC binding to T-cell receptors, and, thus, T-cell receptor-mediated T-cell activation can be minimized.

Abstract: Some aspects of this invention are based on the recognition that reversible protein multimers in which monomeric proteins are conjugated to a carrier molecule via chelation complex bonds are stable under physiological conditions and can be dissociated in a controlled manner under physiological, nontoxic conditions. Accordingly, such protein multimers are useful for a variety of in vitro, ex vivo, and in vivo application for research, diagnostics, and therapy. Some aspect of this invention provide reversible MHC protein multimers, and methods of using such multimers in the detection and/or isolation of specific T-cells or T-cell populations. Because reversible MHC multimers can efficiently be dissociated, the time of MHC binding to T-cell receptors, and, thus, T-cell receptor-mediated T-cell activation can be minimized.

Abstract: Immunostimulatory NY-ESO-1 epitopes recognized by MHC-DRB3*0202 (DR52b) or DRB1*0101 (DR1) restricted T cells are described. Methods for their use in diagnostic and therapeutic approaches are also provided. Further, methods for the generation and isolation of MHC class II molecules, either “empty” or peptide-loaded, are provided. Methods for the assembly of MHC class II multimers, for example, tetramers, are also provided. Methods for the detection of T cells binding to specific peptide-loaded MHC class II molecules are also described herein.