Integrative HLA typing of tumor and adjacent normal tissue can reveal insights into the tumor immune response

Angelina Sverchkova; Scott Burkholz; Reid Rubsamen; Richard Stratford; Trevor Clancy

doi:10.1186/s12920-024-01808-8

Integrative HLA typing of tumor and adjacent normal tissue can reveal insights into the tumor immune response

BMC Med Genomics. 2024 Jan 27;17(1):37. doi: 10.1186/s12920-024-01808-8.

Authors

Angelina Sverchkova^{1

2}, Scott Burkholz³, Reid Rubsamen^{3

4

5}, Richard Stratford¹, Trevor Clancy⁶

Affiliations

¹ NEC OncoImmunity, Oslo Cancer Cluster, Innovation Park, Oslo, Norway.
² Institute of Clinical Medicine, University of Oslo, Oslo, Norway.
³ Flow Pharma, Inc, Warrensville Heights, Galaxy Parkway, OH, 4829, USA.
⁴ University Hospitals, Cleveland Medical Center, Cleveland, OH, USA.
⁵ Case Western Reserve School of Medicine, Cleveland, OH, USA.
⁶ NEC OncoImmunity, Oslo Cancer Cluster, Innovation Park, Oslo, Norway. trevor@oncoimmunity.com.

Abstract

Background: The HLA complex is the most polymorphic region of the human genome, and its improved characterization can help us understand the genetics of human disease as well as the interplay between cancer and the immune system. The main function of HLA genes is to recognize "non-self" antigens and to present them on the cell surface to T cells, which instigate an immune response toward infected or transformed cells. While sequence variation in the antigen-binding groove of HLA may modulate the repertoire of immunogenic antigens presented to T cells, alterations in HLA expression can significantly influence the immune response to pathogens and cancer.

Methods: RNA sequencing was used here to accurately genotype the HLA region and quantify and compare the level of allele-specific HLA expression in tumors and patient-matched adjacent normal tissue. The computational approach utilized in the study types classical and non-classical Class I and Class II HLA alleles from RNA-seq while simultaneously quantifying allele-specific or personalized HLA expression. The strategy also uses RNA-seq data to infer immune cell infiltration into tumors and the corresponding immune cell composition of matched normal tissue, to reveal potential insights related to T cell and NK cell interactions with tumor HLA alleles.

Results: The genotyping method outperforms existing RNA-seq-based HLA typing tools for Class II HLA genotyping. Further, we demonstrate its potential for studying tumor-immune interactions by applying the method to tumor samples from two different subtypes of breast cancer and their matched normal breast tissue controls.

Conclusions: The integrative RNA-seq-based HLA typing approach described in the study, coupled with HLA expression analysis, neoantigen prediction and immune cell infiltration, may help increase our understanding of the interplay between a patient's tumor and immune system; and provide further insights into the immune mechanisms that determine a positive or negative outcome following treatment with immunotherapy such as checkpoint blockade.

Keywords: Breast cancer; HLA typing; Immune cell infiltration; RNA-seq analysis.

MeSH terms

Breast Neoplasms* / genetics
Female
Genotype
HLA Antigens / genetics
Histocompatibility Antigens Class I*
Histocompatibility Testing / methods
Humans
Immunity

Substances

Histocompatibility Antigens Class I
HLA Antigens