Tumor Microenvironment Remodeling Plus Immunotherapy Could Be Used in Mesenchymal-like Tumor with High Tumor Residual and Drug Resistant Rate

Overview

Journal Commun Biol

Specialty Biology

Date 2023 Dec 19

PMID 38110614

Authors

Shuai Shen

Xing Liu

Qing Guo

Qingyu Liang

Jianqi Wu

Gefei Guan

Cunyi Zou

Chen Zhu

Zihao Yan

Tianqi Liu

Ling Chen

Peng Cheng

Wen Cheng

Anhua Wu

Affiliations

Soon will be listed here.

Abstract

Epithelial-mesenchymal transition (EMT) is a common process during tumor progression and is always related to residual tumor, drug resistance and immune suppression. However, considering the heterogeneity in EMT process, there is still a need to establish robust EMT classification system with reasonable molecular, biological and clinical implications to investigate whether these unfavorable survival factors are common or unique in different individuals. In our work, we classify tumors with four EMT status, that is, EMT, EMT, EMT-NOS (Not Otherwise Specified), and EMT-AKT (AKT pathway overactivation) subtypes. We find that EMT-NOS subtype is driven by intrinsic somatic alterations. While, EMT-AKT subtype is maintained by extrinsic cellular interplay between tumor cells and macrophages in an AKT-dependent manner. EMT-AKT subtype is both unresectable and drug resistant while EMT-NOS subtype can be treated with cell cycle related drugs. Importantly, AKT activation in EMT-AKT not only enhances EMT process, but also contributes to the immunosuppressive microenvironment. By remodeling tumor immune-microenvironment by AKT inhibition, EMT-AKT can be treated by immune checkpoint blockade therapies. Meanwhile, we develop TumorMT website ( http://tumormt.neuroscience.org.cn/ ) to apply this EMT classification and provide reasonable therapeutic guidance.

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