Proteogenomics of Diffuse Gliomas Reveal Molecular Subtypes Associated with Specific Therapeutic Targets and Immune-evasion Mechanisms

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Jan 31

PMID 36720864

Authors

Yunzhi Wang

Rongkui Luo

Xuan Zhang

Hang Xiang

Bing Yang

Jinwen Feng

Mengjie Deng

Peng Ran

Akesu Sujie

Fan Zhang

Jiajun Zhu

Subei Tan

Tao Xie

Pin Chen

Zixiang Yu

Yan Li

Dongxian Jiang

Xiaobiao Zhang

Jian-Yuan Zhao

Yingyong Hou

Chen Ding

Affiliations

Soon will be listed here.

Abstract

Diffuse gliomas are devastating brain tumors. Here, we perform a proteogenomic profiling of 213 retrospectively collected glioma tumors. Proteogenomic analysis reveals the downstream biological events leading by EGFR-, IDH1-, TP53-mutations. The comparative analysis illustrates the distinctive features of GBMs and LGGs, indicating CDK2 inhibitor might serve as a promising drug target for GBMs. Further proteogenomic integrative analysis combined with functional experiments highlight the cis-effect of EGFR alterations might lead to glioma tumor cell proliferation through ERK5 medicates nucleotide synthesis process. Proteome-based stratification of gliomas defines 3 proteomic subgroups (S-Ne, S-Pf, S-Im), which could serve as a complement to WHO subtypes, and would provide the essential framework for the utilization of specific targeted therapies for particular glioma subtypes. Immune clustering identifies three immune subtypes with distinctive immune cell types. Further analysis reveals higher EGFR alteration frequencies accounts for elevation of immune check point protein: PD-L1 and CD70 in T-cell infiltrated tumors.

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