Zika virus NS1 drives tunneling nanotube formation for mitochondrial transfer and stealth transmission in trophoblasts

JEV NS1' protein enhances cell-to-cell viral spread by inducing the formation of tunneling nanotubes

Japanese encephalitis virus (JEV), a mosquito-borne virus, can infect various host cells. However, the efficiency with which JEV spreads from cell to cell remains unclear. This study demonstrates that JEV infection can induce the formation of tunneling nanotubes (TNTs), which is mediated by the viral NS1' protein. Further investigations revealed that NS1' protein induces TNTs formation by interacting with PAK1. The establishment of TNTs facilitates the transport of JEV virions and the NS1' protein, thereby evading neutralization by antibodies. In conclusion, our study elucidates the mechanism through which JEV induces the formation of TNTs in host cells and highlights a novel pathway for JEV intercellular spread.

TRIM14 restricts tembusu virus infection through degrading viral NS1 protein and activating type I interferon signaling

Tembusu virus (TMUV), an emerging avian orthoflavivirus, causes severe economic losses due to egg-drop syndrome and fatal encephalitis in domestic waterfowl. To combat this threat, the host immune system plays a crucial role in controlling and eliminating TMUV infection. Understanding the mechanisms of this immune response is thus vital for developing effective strategies against the virus. In this study, we investigated the antiviral activities of duck TRIM family proteins (duTRIM) against TMUV, focusing particularly on duTRIM14 as a potent host restriction factor. We showed that overexpression of duTRIM14 significantly inhibits TMUV replication, while its deficiency leads to increased viral titers. We elucidate a novel mechanism by which duTRIM14 interacts with the TMUV NS1 protein, facilitating its K27/K29-linked polyubiquitination and subsequent proteasomal degradation. The Lys141 residue on NS1 was identified as critical for this process, with its removal significantly enhancing TMUV replication both in vitro and in vivo. Furthermore, we showed that duTRIM14 interacts with duck TBK1 (duTBK1), promoting its K63-linked polyubiquitination on Lys30 and Lys401, which substantially augments IFN-β production during TMUV infection. Taken together, these results provide a novel dual-action antiviral mechanism in which duTRIM14 suppresses TMUV replication by simultaneously promoting proteasomal degradation of NS1 and enhancing the host antiviral response by modulating duTBK1 activity.

The HAVCR1-centric host factor network drives Zika virus vertical transmission

Zika virus (ZIKV) vertical transmission results in devastating congenital malformations and pregnancy complications; however, the specific receptor and host factors facilitating ZIKV maternal-fetal transmission remain elusive. Here, we employ a genome-wide CRISPR screening and identify multiple placenta-intrinsic factors modulating ZIKV infection. Our study unveils that hepatitis A virus cellular receptor 1 (HAVCR1) serves as a primary receptor governing ZIKV entry in placental trophoblasts. The GATA3-HAVCR1 axis regulates heterogeneous cell tropism in the placenta. Notably, placenta-specific Havcr1 deletion in mice significantly impairs ZIKV transplacental transmission and associated adverse pregnancy outcomes. Mechanistically, the immunoglobulin variable-like domain of HAVCR1 binds to ZIKV via domain III of envelope protein and virion-associated phosphatidylserine. Proteomic profiling and function analyses reveal that AP2S1 cooperates with HAVCR1 for ZIKV internalization through clathrin-mediated endocytosis. Overall, our work underscores the pivotal role of HAVCR1 in mediating ZIKV vertical transmission and highlights a therapeutic target for alleviating congenital Zika syndrome.