Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E

C A O'Callaghan; J Tormo; B E Willcox; V M Braud; B K Jakobsen; D I Stuart; A J McMichael; J I Bell; E Y Jones

Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E

C A O'Callaghan, J Tormo, B E Willcox, V M Braud, B K Jakobsen, D I Stuart, A J McMichael, J I Bell, E Y Jones

Cancer and Genomic Sciences

Research output: Contribution to journal › Article › peer-review

162 Citations (Scopus)

Abstract

The crystal structure of the nonclassical human class lb MHC molecule HLA-E has been determined in complex with a prototypic ligand, the nonamer peptide (VMAPRTVLL), derived from the highly conserved residues 3-11 of the human MHC class la leader sequence. The mode of peptide binding retains some of the standard features observed in MHC class la complexes, but novel features imply that HLA-E has evolved to mediate specific binding to a tightly defined set of almost identical hydrophobic peptides from the highly conserved class l leader sequences. These molecular adaptations make HLA-E a rigorous checkpoint at the cell surface reporting on the integrity of the antigen processing pathway to CD94/NKG2 receptor-bearing natural killer cells.

Original language	English
Pages (from-to)	531-41
Number of pages	11
Journal	Molecular Cell
Volume	1
Issue number	4
Publication status	Published - 1998

Cite this

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title = "Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E",

abstract = "The crystal structure of the nonclassical human class lb MHC molecule HLA-E has been determined in complex with a prototypic ligand, the nonamer peptide (VMAPRTVLL), derived from the highly conserved residues 3-11 of the human MHC class la leader sequence. The mode of peptide binding retains some of the standard features observed in MHC class la complexes, but novel features imply that HLA-E has evolved to mediate specific binding to a tightly defined set of almost identical hydrophobic peptides from the highly conserved class l leader sequences. These molecular adaptations make HLA-E a rigorous checkpoint at the cell surface reporting on the integrity of the antigen processing pathway to CD94/NKG2 receptor-bearing natural killer cells.",

author = "O'Callaghan, {C A} and J Tormo and Willcox, {B E} and Braud, {V M} and Jakobsen, {B K} and Stuart, {D I} and McMichael, {A J} and Bell, {J I} and Jones, {E Y}",

year = "1998",

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journal = "Molecular Cell",

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T1 - Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E

AU - O'Callaghan, C A

AU - Tormo, J

AU - Willcox, B E

AU - Braud, V M

AU - Jakobsen, B K

AU - Stuart, D I

AU - McMichael, A J

AU - Bell, J I

AU - Jones, E Y

PY - 1998

Y1 - 1998

N2 - The crystal structure of the nonclassical human class lb MHC molecule HLA-E has been determined in complex with a prototypic ligand, the nonamer peptide (VMAPRTVLL), derived from the highly conserved residues 3-11 of the human MHC class la leader sequence. The mode of peptide binding retains some of the standard features observed in MHC class la complexes, but novel features imply that HLA-E has evolved to mediate specific binding to a tightly defined set of almost identical hydrophobic peptides from the highly conserved class l leader sequences. These molecular adaptations make HLA-E a rigorous checkpoint at the cell surface reporting on the integrity of the antigen processing pathway to CD94/NKG2 receptor-bearing natural killer cells.

AB - The crystal structure of the nonclassical human class lb MHC molecule HLA-E has been determined in complex with a prototypic ligand, the nonamer peptide (VMAPRTVLL), derived from the highly conserved residues 3-11 of the human MHC class la leader sequence. The mode of peptide binding retains some of the standard features observed in MHC class la complexes, but novel features imply that HLA-E has evolved to mediate specific binding to a tightly defined set of almost identical hydrophobic peptides from the highly conserved class l leader sequences. These molecular adaptations make HLA-E a rigorous checkpoint at the cell surface reporting on the integrity of the antigen processing pathway to CD94/NKG2 receptor-bearing natural killer cells.

M3 - Article

C2 - 9660937

SN - 1097-2765

VL - 1

SP - 531

EP - 541

JO - Molecular Cell

JF - Molecular Cell

IS - 4

ER -

Structural features impose tight peptide binding specificity in the nonclassical MHC molecule HLA-E

Abstract

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