Cross-kingdom RNA trafficking and environmental RNAi for powerful innovative pre- and post-harvest plant protection

Wang, Ming; Thomas, Nicholas; Jin, Hailing

doi:10.1016/j.pbi.2017.05.003

Cited by 100 publications

(62 citation statements)

References 81 publications

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“…Based on studies of small RNA movement in plants and fungi described above, there are several pathways for cross‐kingdom small RNA transportation. Because naked small RNAs can move short and long distances in plants (Hyun et al , ) and can also be taken up by fungal cells (Wang, Thomas, and Jin, ), trafficking during plant–fungus interactions may involve naked small RNAs. For instance, when small RNAs targeting B. cinerea DCL1 and DCL2 genes were directly sprayed to Arabidopsis and tomato, treated plants gained resistance to grey mould disease, suggesting the naked exogenous small RNAs were assimilated into the pathogen and interfered with fungal virulence (Wang et al , ).…”

Section: Cross‐kingdom Trafficking Of Small Rnasmentioning

confidence: 99%

“…Based on studies of small RNA movement in plants and fungi described above, there are several pathways for cross-kingdom small RNA transportation. Because naked small RNAs can move short and long distances in plants (Hyun et al, 2011) and can also be taken up by fungal cells (Wang, Thomas, and Jin, 2017) .…”

Section: Possible Pathways For Small Rna Crosskingdom Movementmentioning

confidence: 99%

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Movement of small RNAs in and between plants and fungi

Wang

Dean

2020

Molecular Plant Pathology

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RNA interference is a biological process whereby small RNAs inhibit gene expression through neutralizing targeted mRNA molecules. This process is conserved in eukaryotes. Here, recent work regarding the mechanisms of how small RNAs move within and between organisms is examined. Small RNAs can move locally and systemically in plants through plasmodesmata and phloem, respectively. In fungi, transportation of small RNAs may also be achieved by septal pores and vesicles. Recent evidence also supports bidirectional cross‐kingdom communication of small RNAs between host plants and adapted fungal pathogens to affect the outcome of infection. We discuss several mechanisms for small RNA trafficking and describe evidence for transport through naked form, combined with RNA‐binding proteins or enclosed by vesicles.

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Section: Cross‐kingdom Trafficking Of Small Rnasmentioning

confidence: 99%

Section: Possible Pathways For Small Rna Crosskingdom Movementmentioning

confidence: 99%

Movement of small RNAs in and between plants and fungi

Wang

Dean

2020

Molecular Plant Pathology

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“…During evolution, a certain balance between herbivores, their plant hosts and pathogens/parasites has been reached. Using RNAi as a gene manipulator, key herbivore genes involved in maintaining this homeostasis could be targeted . We define such RNAi as ‘RNAi plus ’.…”

Section: Synergy Of Rna With Plant Defense Chemicals and Micro‐organismsmentioning

confidence: 99%

“…In addition, the RNAi plus approach could also be integrated in current dsRNA delivery strategies. Small RNAs could move within an organism (systemic RNAi), from the environment to the organism (environmental RNAi) and between interacting organisms (cross‐species RNAi), thereby inducing gene silencing in the target organism . This cross‐species RNAi offers interesting delivery possibilities, using for example transgenic plants and micro‐organisms.…”

Section: Synergy Of Rna With Plant Defense Chemicals and Micro‐organismsmentioning

confidence: 99%

Beyond insects: current status and achievements of RNA interference in mite pests and future perspectives

Niu

Shen

Christiaens

et al. 2018

Pest Management Science

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Mites comprise a group of key agricultural pests on a wide range of crops. They cause harm through feeding on the plant and transferring dangerous pathogens, and the rapid evolution of pesticide resistance in mites highlights the need for novel control methods. Currently, RNA interference (RNAi) shows great potential for insect pest control. Here, we review the literature regarding RNAi in mite pests. We discuss different target genes and RNAi efficiency in various mite species, a promising Varroa control program using RNAi, the synergy of RNAi with plant defense mechanisms and microorganisms, and current understanding of systemic movement of double-stranded RNA (dsRNA). On the basis of this evidence, we can conclude that there is clear potential for application of RNAi-based mite control, but further research on several aspects of RNAi in mites is needed, including: (i) the factors influencing RNAi efficiency, (ii) the mechanism of environmental RNAi and cross-kingdom dsRNA trafficking, (iii) the mechanism of possible systemic and parental RNAi, and (iv) non-target effects, specifically in predatory mites, which should be considered during RNAi target selection. © 2018 Society of Chemical Industry.

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“…Consistent with the central role of dsRNA in triggering RNAi, numerous studies have shown that plants treated with virus‐specific dsRNA or single‐stranded RNA (ssRNA) molecules that fold into hairpin conformation showed antiviral resistance (Carbonell et al ., ; Gan et al ., ; Konakalla et al ., ; Tenllado and Diaz‐Ruiz, ; Tenllado et al ., ,b; Yin et al ., ). dsRNAs were also shown to be effective against fungi (Koch et al ., ; Wang et al ., , ) and insects (Baum et al ., ; Ghosh et al ., ; Li et al ., ; Luo et al ., ), thus providing important implications for dsRNA‐triggered RNAi as an emerging novel approach for crop protection. RNAi has been deployed for plant protection since it was discovered.…”

Section: Introductionmentioning

confidence: 99%

Synthetic biology approach for plant protection using dsRNA

Niehl

Soininen

Poranen

et al. 2018

Plant Biotechnology Journal

109

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SummaryPathogens induce severe damages on cultivated plants and represent a serious threat to global food security. Emerging strategies for crop protection involve the external treatment of plants with double‐stranded (ds)RNA to trigger RNA interference. However, applying this technology in greenhouses and fields depends on dsRNA quality, stability and efficient large‐scale production. Using components of the bacteriophage phi6, we engineered a stable and accurate in vivo dsRNA production system in Pseudomonas syringae bacteria. Unlike other in vitro or in vivo dsRNA production systems that rely on DNA transcription and postsynthetic alignment of single‐stranded RNA molecules, the phi6 system is based on the replication of dsRNA by an RNA‐dependent RNA polymerase, thus allowing production of high‐quality, long dsRNA molecules. The phi6 replication complex was reprogrammed to multiply dsRNA sequences homologous to tobacco mosaic virus (TMV) by replacing the coding regions within two of the three phi6 genome segments with TMV sequences and introduction of these constructs into P. syringae together with the third phi6 segment, which encodes the components of the phi6 replication complex. The stable production of TMV dsRNA was achieved by combining all the three phi6 genome segments and by maintaining the natural dsRNA sizes and sequence elements required for efficient replication and packaging of the segments. The produced TMV‐derived dsRNAs inhibited TMV propagation when applied to infected Nicotiana benthamiana plants. The established dsRNA production system enables the broad application of dsRNA molecules as an efficient, highly flexible, nontransgenic and environmentally friendly approach for protecting crops against viruses and other pathogens.

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Cross-kingdom RNA trafficking and environmental RNAi for powerful innovative pre- and post-harvest plant protection

Cited by 100 publications

References 81 publications

Movement of small RNAs in and between plants and fungi

Movement of small RNAs in and between plants and fungi

Beyond insects: current status and achievements of RNA interference in mite pests and future perspectives

Synthetic biology approach for plant protection using dsRNA

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