MHC-I Genotype Restricts the Oncogenic Mutational Landscape

Rachel Marty; Saghar Kaabinejadian; David Rossell; Michael J. Slifker; Joris van de Haar; Hatice Billur Engin; Nicola de Prisco; Trey Ideker; William H. Hildebrand; Joan Font-Burgada; Hannah Carter

doi:10.1016/j.cell.2017.09.050

MHC-I Genotype Restricts the Oncogenic Mutational Landscape

Rachel Marty, Saghar Kaabinejadian, David Rossell, Michael J. Slifker, Joris van de Haar, Hatice Billur Engin, Nicola de Prisco, Trey Ideker, William H. Hildebrand, Joan Font-Burgada, Hannah Carter

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

260 Scopus citations

Abstract

MHC-I molecules expose the intracellular protein content on the cell surface, allowing T cells to detect foreign or mutated peptides. The combination of six MHC-I alleles each individual carries defines the sub-peptidome that can be effectively presented. We applied this concept to human cancer, hypothesizing that oncogenic mutations could arise in gaps in personal MHC-I presentation. To validate this hypothesis, we developed and applied a residue-centric patient presentation score to 9,176 cancer patients across 1,018 recurrent oncogenic mutations. We found that patient MHC-I genotype-based scores could predict which mutations were more likely to emerge in their tumor. Accordingly, poor presentation of a mutation across patients was correlated with higher frequency among tumors. These results support that MHC-I genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors and paves the way for predicting personal cancer susceptibilities from knowledge of MHC-I genotype. HLA genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors.

Original language	English
Pages (from-to)	1272-1283.e15
Journal	Cell
Volume	171
Issue number	6
DOIs	https://doi.org/10.1016/j.cell.2017.09.050
State	Published - Nov 30 2017

Keywords

antigen presentation
cancer
cancer predisposition
cancer susceptibility prediction
human leukocyte antigen
immunoediting
immunology
immunotherapy
major histocompatibility complex
neoantigens

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10.1016/j.cell.2017.09.050

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title = "MHC-I Genotype Restricts the Oncogenic Mutational Landscape",

abstract = "MHC-I molecules expose the intracellular protein content on the cell surface, allowing T cells to detect foreign or mutated peptides. The combination of six MHC-I alleles each individual carries defines the sub-peptidome that can be effectively presented. We applied this concept to human cancer, hypothesizing that oncogenic mutations could arise in gaps in personal MHC-I presentation. To validate this hypothesis, we developed and applied a residue-centric patient presentation score to 9,176 cancer patients across 1,018 recurrent oncogenic mutations. We found that patient MHC-I genotype-based scores could predict which mutations were more likely to emerge in their tumor. Accordingly, poor presentation of a mutation across patients was correlated with higher frequency among tumors. These results support that MHC-I genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors and paves the way for predicting personal cancer susceptibilities from knowledge of MHC-I genotype. HLA genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors.",

keywords = "antigen presentation, cancer, cancer predisposition, cancer susceptibility prediction, human leukocyte antigen, immunoediting, immunology, immunotherapy, major histocompatibility complex, neoantigens",

author = "Rachel Marty and Saghar Kaabinejadian and David Rossell and Slifker, {Michael J.} and {van de Haar}, Joris and Engin, {Hatice Billur} and {de Prisco}, Nicola and Trey Ideker and Hildebrand, {William H.} and Joan Font-Burgada and Hannah Carter",

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year = "2017",

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doi = "10.1016/j.cell.2017.09.050",

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AU - Marty, Rachel

AU - Kaabinejadian, Saghar

AU - Rossell, David

AU - Slifker, Michael J.

AU - van de Haar, Joris

AU - Engin, Hatice Billur

AU - de Prisco, Nicola

AU - Ideker, Trey

AU - Hildebrand, William H.

AU - Font-Burgada, Joan

AU - Carter, Hannah

PY - 2017/11/30

Y1 - 2017/11/30

N2 - MHC-I molecules expose the intracellular protein content on the cell surface, allowing T cells to detect foreign or mutated peptides. The combination of six MHC-I alleles each individual carries defines the sub-peptidome that can be effectively presented. We applied this concept to human cancer, hypothesizing that oncogenic mutations could arise in gaps in personal MHC-I presentation. To validate this hypothesis, we developed and applied a residue-centric patient presentation score to 9,176 cancer patients across 1,018 recurrent oncogenic mutations. We found that patient MHC-I genotype-based scores could predict which mutations were more likely to emerge in their tumor. Accordingly, poor presentation of a mutation across patients was correlated with higher frequency among tumors. These results support that MHC-I genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors and paves the way for predicting personal cancer susceptibilities from knowledge of MHC-I genotype. HLA genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors.

AB - MHC-I molecules expose the intracellular protein content on the cell surface, allowing T cells to detect foreign or mutated peptides. The combination of six MHC-I alleles each individual carries defines the sub-peptidome that can be effectively presented. We applied this concept to human cancer, hypothesizing that oncogenic mutations could arise in gaps in personal MHC-I presentation. To validate this hypothesis, we developed and applied a residue-centric patient presentation score to 9,176 cancer patients across 1,018 recurrent oncogenic mutations. We found that patient MHC-I genotype-based scores could predict which mutations were more likely to emerge in their tumor. Accordingly, poor presentation of a mutation across patients was correlated with higher frequency among tumors. These results support that MHC-I genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors and paves the way for predicting personal cancer susceptibilities from knowledge of MHC-I genotype. HLA genotype-restricted immunoediting during tumor formation shapes the landscape of oncogenic mutations observed in clinically diagnosed tumors.

KW - antigen presentation

KW - cancer

KW - cancer predisposition

KW - cancer susceptibility prediction

KW - human leukocyte antigen

KW - immunoediting

KW - immunology

KW - immunotherapy

KW - major histocompatibility complex

KW - neoantigens

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JO - Cell

JF - Cell

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MHC-I Genotype Restricts the Oncogenic Mutational Landscape

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