The Zinc Finger Protein ZFP36L2 Inhibits Flavivirus Infection Via the 5'-3' XRN1-mediated RNA Decay Pathway in the Replication Complexes

Overview

Journal J Biomed Sci

Publisher Biomed Central

Specialty Biology

Date 2025 Feb 19

PMID 39972499

Authors

Ren-Jye Lin

Li-Hsiung Lin

Zih-Ping Chen

Bing-Cheng Liu

Pin-Chen Ko

Ching-Len Liao

Affiliations

Soon will be listed here.

Abstract

Background: The zinc finger protein 36-like (ZFP36L) family is a CCCH-type group consisting of RNA-binding proteins, i.e., ZFP36L1 and ZFP36L2, which regulate cellular mRNA through the RNA decay pathway. ZFP36L1 combats flavivirus infections through the 5'-3' XRN1 and 3'-5' RNA exosome decay pathways. The present study clarified the role of human ZFP36L2 in the defense response of the host against flavivirus infection.

Methods: Cell lines with overexpression or knockdown of ZFP36L2 were established using lentiviral vectors carrying genes for overexpression and short-hairpin RNA targeting specific genes, respectively. A plaque assay was employed to determine the viral titer. Immunofluorescence and real-time quantitative polymerase chain reaction were used to measure the viral RNA levels. The in vitro-transcribed RNA transcript derived from a replication-dead Japanese encephalitis virus (JEV) replicon containing the renilla luciferase reporter gene (J-R2A-NS5mt) was used to assess the stability of the flavivirus RNA. An RNA immunoprecipitation assay was used to detect the protein-RNA binding ability. Confocal microscopic images were captured to analyze protein colocalization.

Results: ZFP36L2 served as an innate host defender against JEV and dengue virus. ZFP36L2 inhibited flavivirus infection solely through the 5'-3' XRN1 RNA decay pathway, whereas ZFP36L1 inhibited JEV infection via the 5'-3' XRN1 and 3'-5' RNA exosome RNA decay pathways. The direct binding between viral RNA and ZFP36L2 via its CCCH-type zinc finger motifs facilitated the degradation of flavivirus RNA mediated by 5'-3' XRN1. Furthermore, ZFP36L2 was localized in processing bodies (PBs), which participate in the 5'-3' XRN1-mediated RNA decay pathway. Nonetheless, the disruption of PBs did not affect the antiviral activity of ZFP36L2, suggesting that its localization is not essential for the function of the protein. Interestingly, the colocalization of ZFP36L2 and XRN1 with viral RNA and NS3 revealed that the antiviral activity of ZFP36L2 occurred within the replication complexes (RCs).

Conclusions: In summary, ZFP36L2 bound to and degraded viral RNA through the XRN1-mediated RNA decay pathway in the RCs, thereby inhibiting flavivirus replication. These findings provide valuable insights into the diverse antiviral mechanisms of the ZFP36-like family of proteins in the innate immune response against flavivirus infection.

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