Small RNA Functions Are Required for Growth and Development of <i>Magnaporthe oryzae</i>

Raman, Vidhyavathi; Simon, Stacey A.; Demirci, Feray; Nakano, Mayumi; Donofrio, Nicole

doi:10.1094/mpmi-11-16-0236-r

Cited by 55 publications

(51 citation statements)

References 70 publications

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“…DCLs are the most important components of the RNAi machinery in eukaryotes, and in the present study, downregulation of the DCL2-like gene was revealed, but the DCL1-like gene in P. italicum did not significantly reduce in its ability to infect citrus fruits (Figures 2 and 3). Subsequent sRNA sequencing also indicated that the DCL2-like gene plays a more important role in regulating milRNA expression than the DCL1-like gene in P. italicum ( Figure 6), as similarly reported in Magnaporthe oryzae [45]. These data suggest that P. italicum may possess a mechanism of RNAi or ck-RNAi and that its sRNA might be an effector in citrus epidermal cells that induces the RNAi response of citrus fruits during the infection process.…”

Section: Discussionsupporting

confidence: 74%

Silencing Dicer-Like Genes Reduces Virulence and sRNA Generation in Penicillium italicum, the Cause of Citrus Blue Mold

Yin

Zhu

Jiang

et al. 2020

Cells

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The Dicer protein is one of the most important components of RNAi machinery because it regulates the production of small RNAs (sRNAs) in eukaryotes. Here, Dicer1-like gene (Pit-DCL1) and Dicer2-like gene (Pit-DCL2) RNAi transformants were generated via pSilent-1 in Penicillium italicum (Pit), which is the causal agent of citrus blue mold. Neither transformant showed a change in mycelial growth or sporulation ability, but the pathogenicity of the Pit-DCL2 RNAi transformant to citrus fruits was severely impaired, compared to that of the Pit-DCL1 RNAi transformant and the wild type. We further developed a citrus wound-mediated RNAi approach with a double-stranded fragment of Pit-DCL2 generated in vitro, which achieved an efficiency in reducing Pi-Dcl2 expression and virulence that was similar to that of protoplast-mediated RNAi in P. italicum, suggesting that this approach is promising in the exogenous application of dsRNA to control pathogens on the surface of citrus fruits. In addition, sRNA sequencing revealed a total of 69.88 million potential sRNAs and 12 novel microRNA-like small RNAs (milRNAs), four of which have been predicated on target innate immunity or biotic stress-related genes in Valencia orange. These data suggest that both the Pit-DCL1 and Pit-DCL2 RNAi transformants severely disrupted the biogenesis of the potential milRNAs, which was further confirmed for some milRNAs by qRT-PCR or Northern blot analysis. These data suggest the sRNAs in P. italicum that may be involved in a molecular virulence mechanism termed cross-kingdom RNAi (ck-RNAi) by trafficking sRNA from P. italicum to citrus fruits.

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Section: Discussionsupporting

confidence: 74%

Silencing Dicer-Like Genes Reduces Virulence and sRNA Generation in Penicillium italicum, the Cause of Citrus Blue Mold

Yin

Zhu

Jiang

et al. 2020

Cells

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“…The number of AGO-like genes varied from 1 ( A. nidulans, S. pombe ) to 4 ( Cryphonectria parasitica, Gaeumannomyces graminis ) but most of the fungal species examined here possessed three AGO-like genes. Based on their amino acid sequences in the Piwi domain, the AGO genes were clustered into three major groups, which corresponded to the AGO1, AGO2 and AGO3 groups reported previously (62). Three AGO genes in P. oryzae were designated MoAGO1 (MGG 14873), MoAGO2 (MGG 13617) and MoAGO3 (MGG 01294) (62).…”

Section: Resultsmentioning

confidence: 89%

“…Based on their amino acid sequences in the Piwi domain, the AGO genes were clustered into three major groups, which corresponded to the AGO1, AGO2 and AGO3 groups reported previously (62). Three AGO genes in P. oryzae were designated MoAGO1 (MGG 14873), MoAGO2 (MGG 13617) and MoAGO3 (MGG 01294) (62). Protein domain analysis using InterPro Scan revealed that all three proteins possessed conserved domains (N-terminal, linker 1, PAZ, linker 2 and Piwi) and conserved amino acid residues (nucleic acid binding site, 5′ RNA guide strand anchoring site and enzymatic active site) (Figure 1B).…”

Section: Resultsmentioning

confidence: 89%

A fungal Argonaute interferes with RNA interference

Nguyen

Iritani

Ohkita

et al. 2018

Nucleic Acids Research

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Small RNA (sRNA)-mediated gene silencing phenomena, exemplified by RNA interference (RNAi), require a unique class of proteins called Argonautes (AGOs). An AGO protein typically forms a protein–sRNA complex that contributes to gene silencing using the loaded sRNA as a specificity determinant. Here, we show that MoAGO2, one of the three AGO genes in the fungus Pyricularia oryzae (Magnaporthe oryzae) interferes with RNAi. Gene knockout (KO) studies revealed that MoAGO1 and MoAGO3 additively or redundantly played roles in hairpin RNA- and retrotransposon (MAGGY)-triggered RNAi while, surprisingly, the KO mutants of MoAGO2 (Δmoago2) showed elevated levels of gene silencing. Consistently, transcript levels of MAGGY and mycoviruses were drastically reduced in Δmoago2, supporting the idea that MoAGO2 impeded RNAi against the parasitic elements. Deep sequencing analysis revealed that repeat- and mycovirus-derived small interfering RNAs were mainly associated with MoAGO2 and MoAGO3, and their populations were very similar based on their size distribution patterns and positional base preference. Site-directed mutagenesis studies indicated that sRNA binding but not slicer activity of MoAGO2 was essential for the ability to diminish the efficacy of RNAi. Overall, these results suggest a possible interplay between distinct sRNA-mediated gene regulation pathways through a competition for sRNA.

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“…A priority now is to determine how widely the deployment of sRNA effectors is conserved among plant‐associated fungi with contrasting lifestyles, including endophytes and symbionts. For example, the P. oryzae and F. graminearum ΔΔdcl1:dcl2 Dicer‐like double mutants are still pathogenic, suggesting that these fungal species do not use DICER‐dependent sRNA to manipulate host plant defences, as observed with B. cinerea (Raman et al ., ; Zeng et al ., ).The discovery of sRNA effectors raises many other questions: to what extent is the expression of fungal sRNA effectors constitutive or plant‐induced; are specific sRNA populations produced at different infection stages to target different sets of host genes; and do wide host‐range pathogens produce different populations of sRNA effectors when infecting different hosts?…”

Section: Small Rnas New Fungal Effectors Targeting Plant Gene Expresmentioning

confidence: 99%

Nonproteinaceous effectors: the terra incognita of plant–fungal interactions

2019

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Summary Molecular plant–fungal interaction studies have mainly focused on small secreted protein effectors. However, accumulating evidence shows that numerous fungal secondary metabolites are produced at all stages of plant colonization, especially during early asymptomatic/biotrophic phases. The discovery of fungal small RNAs targeting plant transcripts has expanded the fungal repertoire of nonproteinaceous effectors even further. The challenge now is to develop specific functional methods to fully understand the biological roles of these effectors. Studies on fungal extracellular vesicles are also needed because they could be the universal carriers of all kinds of fungal effectors. With this review, we aim to stimulate the nonproteinaceous effector research field to move from descriptive to functional studies, which should bring a paradigm shift in plant–fungal interactions.

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Small RNA Functions Are Required for Growth and Development of Magnaporthe oryzae

Cited by 55 publications

References 70 publications

Silencing Dicer-Like Genes Reduces Virulence and sRNA Generation in Penicillium italicum, the Cause of Citrus Blue Mold

Silencing Dicer-Like Genes Reduces Virulence and sRNA Generation in Penicillium italicum, the Cause of Citrus Blue Mold

A fungal Argonaute interferes with RNA interference

Nonproteinaceous effectors: the terra incognita of plant–fungal interactions

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