Functional Verification of Differentially Expressed Genes Following DENV2 Infection in

Overview

Journal Viruses

Publisher MDPI

Date 2025 Jan 25

PMID 39861856

Authors

Xiaoli Chen

Xinyu Zhou

Xiaoxue Xie

Bo Li

Teng Zhao

Haotian Yu

Dan Xing

Jiahong Wu

Chunxiao Li

Affiliations

Soon will be listed here.

Abstract

The dengue virus (DENV) is primarily transmitted by . Investigating genes associated with mosquito susceptibility to DENV2 offers a theoretical foundation for targeted interventions to regulate or block viral replication and transmission within mosquitoes. Based on the transcriptomic analyses of the midgut and salivary glands from infected with DENV2, alongside analyses of Aag2 cell infections, 24 genes potentially related to the regulation of infection with DENV2 were selected. By establishing transient transfection and overexpression models of Aag2 cells, and mosquito target gene interference models, the difference in viral load before and after treatment was compared, and the effects of DEGs on viral replication were evaluated. After overexpressing 24 DEGs in Aag2 cells, 19 DEGs showed a significant difference in DENV2 RNA copies in the cell supernatant ( < 0.05). In adult mosquitoes, knocking down defensin-A, defensin-A-like, and SMCT1 respectively reduced the DENV2 RNA copies, while knocking down UGT2B1 and ND4 respectively increased the DENV2 RNA copies. In this study, to assess the role of genes related to DENV2 replication, and transient transfection and overexpression models in Aag2 cells and mosquito gene knockdown models were established, and five genes, defensin-A, defensin-A-like, SMCT1, UGT2B1, and ND4, were found to have an impact on the replication of DENV2, providing a reference basis for studying the complex mechanism of mosquito-virus interactions.

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