Minicell-based fungal RNAi delivery for sustainable crop protection

Autor:	Kira Bartlett, Ameer Hamza Shakeel, Jacob A. Englaender, Mark Kester, Joseph Thomas Frank, Sepehr Zomorodi, Sherif M. Sherif, Elisabeth Somers, Payam Pourtaheri, Sergio M. Carballo, Tabibul Islam, Zachery George Davis, Lisa Chen
Přispěvatelé:	Virginia Agricultural Experiment Station, School of Plant and Environmental Sciences
Rok vydání:	2020
Předmět:	RNase P Bioengineering Biology Applied Microbiology and Biotechnology Biochemistry 03 medical and health sciences RNA interference Disease management (agriculture) Gene silencing Gene 030304 developmental biology Plant Diseases 0303 health sciences 030306 microbiology Crop Protection Brief Report fungi Fungi Chitin synthase Crop protection Cell biology RNA silencing biology.protein RNA Interference Brief Reports Botrytis TP248.13-248.65 Biotechnology
Zdroj:	Microbial Biotechnology Microbial Biotechnology, Vol 14, Iss 4, Pp 1847-1856 (2021)
ISSN:	1751-7915
Popis:	Spray‐induced gene silencing (SIGS) using topical dsRNA applications has risen as a promising, target‐specific, and environmentally‐friendly disease management strategy against phytopathogenic fungi. We demonstrated that minicell‐encapsulated dsRNA (ME‐dsRNA) halted gray mold disease progression in strawberries. ME‐dsRNAs offer a platform that can readily be translated to large‐scale production and deployed in open‐field applications to control gray mold in strawberries. Summary Spray‐induced gene silencing (SIGS) using topical dsRNA applications has risen as a promising, target‐specific, and environmentally friendly disease management strategy against phytopathogenic fungi. However, dsRNA stability, efficacy, and scalability are still the main constraints facing SIGS broader application. Here we show that Escherichia coli‐derived anucleated minicells can be utilized as a cost‐effective, scalable platform for dsRNA production and encapsulation. We demonstrated that minicell‐encapsulated dsRNA (ME‐dsRNA) was shielded from RNase degradation and stabilized on strawberry surfaces, allowing dsRNA persistence in field‐like conditions. ME‐dsRNAs targeting chitin synthase class III (Chs3a, Chs3b) and DICER‐like proteins (DCL1 and DCL2) genes of Botryotinia fuckeliana selectively knocked‐down the target genes and led to significant fungal growth inhibition in vitro. We also observed a compensatory relationship between DCL1 and DCL2 gene transcripts, where the silencing of one gene upregulated the expression of the other. Contrary to naked‐dsRNAs, ME‐dsRNAs halted disease progression in strawberries for 12 days under greenhouse conditions. These results elucidate the potential of ME‐dsRNAs to enable the commercial application of RNAi‐based, species‐specific biocontrols comparable in efficacy to conventional synthetics. ME‐dsRNAs offer a platform that can readily be translated to large‐scale production and deployed in open‐field applications to control grey mould in strawberries.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::3edf1bf8cb8eca06f4d502da3af7476a https://pubmed.ncbi.nlm.nih.gov/33624940 Zobrazit plný text záznamu Plný text