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Primary and secondary functions of HLA-E are determined by stability and conformation of the peptide-bound complexes

Lucy C. Walters, Daniel Rozbeský, Karl Harlos, Max Quastel, Hong Sun, Sebastian Springer, Robert P. Rambo, Fiyaz Mohammed, E. Yvonne Jones, Andrew J. McMichael, Geraldine M. Gillespie

2022Cell Reports26 citationsDOIOpen Access PDF

Abstract

T cells. To understand these affinity differences, human MHC-E (HLA-E)-VL9 versus pathogen-derived peptide structures are compared. Small-angle X-ray scatter (SAXS) measures biophysical parameters in solution, allowing comparison with crystal structures. For HLA-E-VL9, there is concordance between SAXS and crystal parameters. In contrast, HLA-E-bound pathogen-derived peptides produce larger SAXS dimensions that reduce to their crystallographic dimensions only when excess peptide is supplied. Further crystallographic analysis demonstrates three amino acids, exclusive to MHC-E, that not only position VL9 close to the α2 helix, but also allow non-VL9 peptide binding with re-configuration of a key TCR-interacting α2 region. Thus, non-VL9-bound peptides introduce an alternative peptide-binding motif and surface recognition landscape, providing a likely basis for VL9- and non-VL9-HLA-E immune discrimination.

Topics & Concepts

PeptideMajor histocompatibility complexT-cell receptorSmall-angle X-ray scatteringReceptorHuman leukocyte antigenCD8MHC class IMHC restrictionBiologyChemistryPeptide sequenceImmune systemCrystallographyT cellBiochemistryAntigenImmunologyPhysicsGeneScatteringOpticsImmune Cell Function and InteractionT-cell and B-cell ImmunologyImmunotherapy and Immune Responses
Primary and secondary functions of HLA-E are determined by stability and conformation of the peptide-bound complexes | Litcius