SAGA complex mediates the transcriptional up-regulation of antiviral RNA silencing

Andika, Ida Bagus; Jamal, Atif; Kondō, Hideki; Suzuki, Nobuhiro

doi:10.1073/pnas.1701196114

Cited by 47 publications

(41 citation statements)

References 63 publications

(98 reference statements)

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“…Infection of Plant Pathogenic Fungi with Viroids. We investigated the possibility of viroid infection in three phytopathogenic ascomycete fungi, Cryphonectria parasitica, Valsa mali, and Fusarium graminearum, which are the causative agents of chestnut blight, apple tree canker, and wheat/barley head blight and maize ear rot diseases, respectively (46)(47)(48). Spheroplasts prepared from these three fungi were transfected with in vitro RNA transcripts derived from each of the seven viroid cDNA clones and then regenerated and followed by subcultures (SI Appendix, Fig.…”

Section: Resultsmentioning

confidence: 99%

Symptomatic plant viroid infections in phytopathogenic fungi

Wei

Bian

Andika

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Viroids are pathogenic agents that have a small, circular noncoding RNA genome. They have been found only in plant species; therefore, their infectivity and pathogenicity in other organisms remain largely unexplored. In this study, we investigate whether plant viroids can replicate and induce symptoms in filamentous fungi. Seven plant viroids representing viroid groups that replicate in either the nucleus or chloroplast of plant cells were inoculated to three plant pathogenic fungi, Cryphonectria parasitica, Valsa mali, and Fusarium graminearum. By transfection of fungal spheroplasts with viroid RNA transcripts, each of the three, hop stunt viroid (HSVd), iresine 1 viroid, and avocado sunblotch viroid, can stably replicate in at least one of those fungi. The viroids are horizontally transmitted through hyphal anastomosis and vertically through conidia. HSVd infection severely debilitates the growth of V. mali but not that of the other two fungi, while in F. graminearum and C. parasitica, with deletion of dicer-like genes, the primary components of the RNA-silencing pathway, HSVd accumulation increases. We further demonstrate that HSVd can be bidirectionally transferred between F. graminearum and plants during infection. The viroids also efficiently infect fungi and induce disease symptoms when the viroid RNAs are exogenously applied to the fungal mycelia. These findings enhance our understanding of viroid replication, host range, and pathogenicity, and of their potential spread to other organisms in nature.plant viroid | fungus | transmission | pathogenicity V iroids are infectious pathogenic agents possessing small, nonencapsidated, circular single-stranded RNAs that, to date, have been found to naturally infect only plants (1, 2). Viroids infect a wide variety of higher plant species, causing devastating diseases in many crops, particularly vegetables, fruits, and ornamental plants (3). In crop plants, viroids are known to spread by vegetative propagation; by mechanical agricultural practices; and, in certain cases, through seeds, pollen, and insect transmission (3, 4). As viroids do not encode any proteins and do not require a helper agent for their multiplication and survival, the biological activities of viroids are entirely dependent on direct interactions of their RNA genome or its derivatives with cellular host components (5-9). Viroid replication or processing of its RNAs in the yeast, Saccharomyces cerevisiae, and cyanobacterium, Nostoc (Nostocales), have been demonstrated (10-12).Currently, at least 34 viroid species have been identified and are classified into two families, Avsunviroidae and Pospiviroidae (13-15). The members of Avsunviroidae (type species: Avocado sunblotch viroid) replicate in the chloroplasts or plastids through symmetric rolling-circle replication using the host nuclear-encoded polymerase. Their RNAs form highly branched secondary structures and have ribozyme activities. Members of Pospiviroidae (type species: Potato spindle tuber viroid) replicate and accumulate in the nucleus th...

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Section: Resultsmentioning

confidence: 99%

Symptomatic plant viroid infections in phytopathogenic fungi

Wei

Bian

Andika

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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“…In the case of the budding yeast, Saccharomyces cerevisiae, ∼10% of all genes have been reported to be under the control of SAGA (27,28). Our previous study showed HAT activity, but not DUB activity, to be a major player in the SAGA-mediated induction of dcl2 upon viral infection in C. parasitica (21). HAT activity, as a major contributor, and DUB activity as a minor contributor, are involved in the SAGAmediated up-regulation of agl2 (21).…”

Section: Significancementioning

confidence: 96%

“…Δp69 Infection in C. parasitica. Using a genetic screening approach, we have previously shown that sgf73, a component of the SAGA, is essential for the high induction of antiviral RNA silencing (21). To investigate whether the SAGA complex is involved in transcriptional up-regulation of a wide range of genes following viral infection in C. parasitica, we analyzed the global transcriptome profiles of the CHV1-Δp69-infected Δsgf73 and DK80 (Δsgf73 parental strain) strains relative to that of the virus-free DK80 strain using high-throughput cDNA sequencing (RNA-seq) ( Fig.…”

Section: Dcl2 Is Essential For Saga-mediated Gene Up-regulation Upon mentioning

confidence: 99%

“…We have previously developed a genetic screening protocol for the identification of factors involved in the induction pathway from the sensing of viral infection to transcriptional up-regulation. This screen led to the identification of the universally conserved Spt-Ada-Gcn5 acetyltransferase (SAGA) complex as a regulator of this up-regulation (21), which interestingly requires DCL2 and AGL2 as positive feedback players. However, DCL2 and AGL2 requirement patterns are different among viruses; a dsRNA reovirus, mycoreovirus 1 (MyRV1, family Reoviridae) requires only DCL2 but not AGL2, while a positive-stranded RNA hypovirus lacking an RNA-silencing suppressor, p29 (Cryphonectria hypovirus 1-Δp69, CHV1-Δp69, family Hypoviridae) requires both DCL2 and AGL2 (21).…”

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Dicer functions transcriptionally and posttranscriptionally in a multilayer antiviral defense

Andika

Kondō

Suzuki

2019

Proc. Natl. Acad. Sci. U.S.A.

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In antiviral RNA interference (RNAi), Dicer plays a primary role in processing double-stranded RNA (dsRNA) molecules into small-interfering RNAs (siRNAs) that guide Argonaute effectors to posttranscriptional suppression of target viral genes. Here, we show a distinct role for Dicer in the siRNA-independent transcriptional induction of certain host genes upon viral infection in a filamentous fungus. Previous studies have shown that the two key players, dicer-like 2 (dcl2) and argonaute-like 2 (agl2), of antiviral RNAi in a phytopathogenic ascomycete,Cryphonectria parasitica, are highly transcriptionally induced upon infection with certain RNA mycoviruses, including the positive-stranded RNA hypovirus mutant lacking the RNAi suppressor (Cryphonectriahypovirus 1-Δp69, CHV1-Δp69). This induction is regulated by the Spt–Ada–Gcn5 acetyltransferase (SAGA) complex, a well-known transcriptional coactivator. The present study shows that diverse host genes, in addition todcl2andagl2, were up-regulated more than 10-fold by SAGA upon infection with CHV1-Δp69. Interestingly, DCL2, but not AGL2, was essential for SAGA-mediated global gene up-regulation. Moreover, deletion of certain virus-induced genes enhanced a CHV1-Δp69 symptom (growth rate) but not its accumulation. Constitutive, modest levels ofdcl2expression drastically reduced viral siRNA accumulation but were sufficient for full-scale up-regulation of host genes, suggesting that high induction ofdcl2and siRNA production are not essential for the transcriptional up-regulation function of DCL2. These data clearly demonstrate the dual functionality of DCL2: as a dsRNA-specific nuclease in posttranscriptional antiviral RNA silencing and as a key player in SAGA-mediated host gene induction, which independently represses viral replication and alleviates virus-induced symptom expression.

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“…．一方，中国の Jiang らのグループが， gemini 様 ssDNA ウイルスや (-)RNA ウイルスが Sclerotinia sclerotiorum へ人為的導入に成功している (Liu et al, 2014;Yu et al, 2010) ．また，筆者らは粒子ではなく YkV1 感染性 cDNA クローンの合成に成功した (Zhang et al, 2016 (Chiba et al, 2013a;Chiba et al, 2013b;Chiba et al, 2016;Salaipeth et al, 2014) ，その調節機構にもメスが入った (Andika et al, 2017;Chiba and Suzuki, 2015) ．RNA サイレンシングが RNA ウイルスのゲノムの安定維持に正にも負にも働くことが示された(Eusebio-Cope and Sun et al, 2009) ．また，菌類ウイルスの RNA サイレンシング抑制蛋白質として同定されている CHV1 の p29 が，異種ウイルスの複製，無性胞子を通じた垂直伝搬を促進することも明らかにした (Suzuki et al, 2003) ．さらに，CHV1，MyRV1 の病徴発現に関与する宿主因子 (Faruk et al, 2008a(Faruk et al, , 2008b (Kanhayuwa et al, 2015;Zhang et al, 2016) ，菌類ウイルスの虫媒伝染 (Liu et al, 2016)あるいは菌類ウイルスの昆虫 (Liu et al, 2016) ，植物細胞 (Nerva et al, 2017)…”

unclassified

Frontiers in fungal virology

Suzuki

2017

Jpn. J. Phytopathol.

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SAGA complex mediates the transcriptional up-regulation of antiviral RNA silencing

Cited by 47 publications

References 63 publications

Symptomatic plant viroid infections in phytopathogenic fungi

Symptomatic plant viroid infections in phytopathogenic fungi

Dicer functions transcriptionally and posttranscriptionally in a multilayer antiviral defense

Frontiers in fungal virology

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