Therapeutic Efficacy of ECs Foxp1 Targeting Hif1α-Hk2 Glycolysis Signal to Restrict Angiogenesis

Overview

Journal Redox Biol

Specialties Biology
Cell Biology
Endocrinology

Date 2024 Jul 31

PMID 39083899

Authors

Jingjiang Pi

Huan Chang

Xiaoli Chen

Wenqi Pan

Qi Zhang

Tao Zhuang

Jiwen Liu

Haikun Wang

Brian Tomlinson

Paul Chan

Yu Cheng

Zuoren Yu

Lin Zhang

Zhenlin Zhao

Zhongmin Liu

Jie Liu

Yuzhen Zhang

Affiliations

Soon will be listed here.

Abstract

Endothelial cells (ECs) rely on glycolysis for energy production to maintain vascular homeostasis and the normalization of hyperglycolysis in tumor vessels has recently gained attention as a therapeutic target. We analyzed the TCGA database and found reduced Foxp1 expression in lung carcinoma. Immunostaining demonstrated reduced expression more restricted at tumor vascular ECs. Therefore, we investigated the function and mechanisms of Foxp1 in EC metabolism for tumor angiogenesis required for tumor growth. EC-Foxp1 deletion mice exhibited a significant increase of tumor and retinal developmental angiogenesis and Hif1α was identified as Foxp1 target gene, and Hk2 as Hif1α target gene. The Foxp1-Hif1α-Hk2 pathway in ECs is important in the regulation of glycolytic metabolism to govern tumor angiogenesis. Finally, we used genetic deletion of EC-Hif1α and RGD-peptide nanoparticles EC target delivery of Hif1α/Hk2-siRNAs to knockdown gene expression which reduced the tumor EC hyperglycolysis state and restricted angiogenesis for tumor growth. This study advances our understanding of EC metabolism for tumor angiogenesis, and meanwhile provides evidence for future therapeutic intervention of hyperglycolysis in tumor ECs for suppression of tumor growth.

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PMID: 39583207 PMC: 11582285. DOI: 10.1007/s13205-024-04150-z.

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