AI Article Synopsis
- * Researchers used reverse genetics to create four DPV mutants with specific mutations in gI's N-glycosylation sites, confirming that three asparagine residues are critical for glycosylation.
- * The mutations lead to reduced replication and transmission of DPV in ducks, highlighting a potential pathway for developing live attenuated vaccines against the virus.
Article Abstract
Duck plague virus (DPV) causes the highly pathogenic duck plague, and the envelope glycoprotein I (gI), as one of the key virulence genes, has not yet had its critical virulence sites identified through screening. This study used reverse genetics technology to target the gI, specifically within the DPV genome. Four DPV mutants with gI N-glycosylation site mutations were designed and constructed, and these mutant strains were successfully rescued. Our results confirmed that three asparagine residues of gI (N, N, and N) are N-glycosylation sites, and western blot analysis substantiated that glycosylation at each predicted N-glycosylation site was compromised. The deglycosylation of gI leads to the protein misfolding and subsequent retention in the endoplasmic reticulum (ER). The subsequent deglycosylated gI is carried into the Golgi apparatus (GM130) in the interaction of gE. Compared to the parental virus, the mutated virus shows a 66.3% reduction in intercellular transmission capability. In ducks, the deglycosylation of gI significantly reduces DPV replication in vivo, thereby weakening the virulence of DPV. This study represents the first successful creation of a weak DPV virus strain by specific mutation at the N-glycosylation site. The findings provide a foundational understanding of DPV pathogenesis and form the basis for developing live attenuated vaccines against the disease.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11514881 | PMC |
| http://dx.doi.org/10.1186/s13567-024-01398-4 | DOI Listing |
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Article Synopsis
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- * The mutations lead to reduced replication and transmission of DPV in ducks, highlighting a potential pathway for developing live attenuated vaccines against the virus.
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- The findings suggest that DPV exploits Lnc BTU to evade the immune response, identifying potential therapeutic targets for managing DPV infections in waterfowl.
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