AI Article Synopsis
- A biotrophic fungus causes smut disease in maize by secreting various effector proteins, particularly focusing on the gene Vp1 which remains highly expressed throughout the fungus's life cycle.
- Vp1 was analyzed using multiple methods, revealing its role in enhancing virulence and suggesting it localizes to the plant nucleus after secretion, while an ortholog (UhVp1) lacks this nuclear localization signal.
- Complementation studies showed that Vp1's orthologs from other related fungi failed to replicate its virulence function, indicating that Vp1 has developed a specialized role through evolutionary changes.
Article Abstract
The biotrophic fungus secretes a plethora of uncharacterized effector proteins and causes smut disease in maize. Among the effector genes that are up-regulated during the biotrophic growth in maize, we identified (), which has an expression that was up-regulated and maintained at a high level throughout the life cycle of the fungus. We characterized Vp1 by applying in silico analysis, reverse genetics, phenotypic assessment, microscopy, and protein localization and provided a fundamental understanding of the Vp1 protein in . The reduction in fungal virulence and colonization in the mutant suggests the virulence-promoting function of Vp1. The deletion studies on the NLS (nuclear localization signal) sequence and the protein localization study revealed that the C-terminus of Vp1 is processed after secretion in plant apoplast and could localize to the plant nucleus. The ortholog UhVp1 lacks NLS localized in the plant cytoplasm, suggesting that the orthologs might have a distinct subcellular localization. Further complementation studies of the Vp1 orthologs in related smut fungi revealed that none of them could complement the virulence function of Vp1, suggesting that UmVp1 could acquire a specialized function via sequence divergence.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8396986 | PMC |
| http://dx.doi.org/10.3390/jof7080589 | DOI Listing |
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