Sugarcane mosaic virus mediated changes in cytosine methylation pattern and differentially transcribed fragments in resistance-contrasting sugarcane genotypes

Silva, Marcel Fernando da; Gonçalves, Marcos César; Brito, Michael dos Santos; Medeiros, Cibele Nataliane Facioli; Harakava, Ricardo; Landell, Marcos Guimarães de Andrade; Pinto, Luciana Rossini

doi:10.1371/journal.pone.0241493

Cited by 8 publications

(4 citation statements)

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“…Previous studies showed that the infection of potyviruses, e.g., TuMV and SCMV caused comprehensive changes of DNA methylation in host plant (da Silva et al 2020;Corrêa et al 2020). In this study, we further analyzed the methylome change in virus-infected cells to insight the arms race between virus and host at the DNA methylation level.…”

Section: Discussionmentioning

confidence: 97%

Turnip mosaic virus manipulates DRM2 expression to regulate host CHH and CHG methylation for robust infection

Chai

Liu

et al. 2022

Stress Biology

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DNA methylation is an important epigenetic marker for the suppression of transposable elements (TEs) and the regulation of plant immunity. However, little is known how RNA viruses counter defense such antiviral machinery. In this study, the change of DNA methylation in turnip mosaic virus (TuMV)-infected cells was analyzed by whole genome bisulfite sequencing. Results showed that the total number of methylated sites of CHH and CHG increased in TuMV-infected cells, the majority of differentially methylated regions (DMRs) in the CHH and CHG contexts were associated with hypermethylation. Gene expression analysis showed that the expression of two methylases (DRM2 and CMT3) and three demethylases (ROS3, DML2, DML3) was significantly increased and decreased in TuMV-infected cells, respectively. Pathogenicity tests showed that the enhanced resistance to TuMV of the loss-of-function mutant of DRM2 is associated with unregulated expression of several defense-related genes. Finally, we found TuMV-encoded NIb, the viral RNA-dependent RNA polymerase, was able to induce the expression of DRM2. In conclusion, this study discovered that TuMV can modulate host DNA methylation by regulating the expression of DRM2 to promote virus infection.

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Section: Discussionmentioning

confidence: 97%

Turnip mosaic virus manipulates DRM2 expression to regulate host CHH and CHG methylation for robust infection

Chai

Liu

et al. 2022

Stress Biology

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“…Similarly, a heavy metal-associated isoprenylated plant protein was shown to interact with the Pomovirus movement protein, affecting virus long-distance movement (Cowan et al ., 2018). Interestingly, transcripts of two chaperones and a heavy metal-associated isoprenylated protein differentially accumulated in response to SCMV in sugarcane (da Silva et al, 2020). Another protein annotated in the present study that has been shown to interact with the potyviral movement protein P3N-PIPO is a beta-glucosidase, possibly facilitating viral spread through the plant (Song et al ., 2016); beta-glucosidase genes have also been found in QTLs for resistance to SCMV and other potyviruses (Gustafson et al ., 2018; Rubio et al ., 2019).…”

Section: Discussionmentioning

confidence: 99%

“…According to the results of our analysis, biological processes enriched in SCMV resistance-associated modules included stress responses, regulation of transcription and translation, and a process that has long been known to be affected by SCMV infection (Irvine, 1971) but has not been featured by the analysis of genes directly associated with resistance— photosynthesis. Recent transcriptomic and proteomic studies have shown that infection by SCMV indeed affects the regulation of genes and proteins involved in these processes (Wu et al ., 2013; Chen et al ., 2017; Akbar et al ., 2020; da Silva et al ., 2020). Notably, the results of our coexpression network analyses indicate that the expression of genes identified in the present study as being associated with SCMV resistance are also associated with those controlling such processes; thus, those genes possibly play roles in their regulation during viral infection.…”

Section: Discussionmentioning

confidence: 99%

“…Although RNA-Seq data from sugarcane plants infected with SCMV are available (Akbar et al ., 2020), they include data from only two biological replicates, which equates to a very low sample number for network modeling—the WGCNA developers recommend a minimum of 15 samples to avoid noise and biologically meaningless inferences (Langfelder and Horvath, 2017). The summarization of GO terms from genes close to markers directly associated with SCMV resistance revealed a few general processes previously associated with responses to this virus; these included stress responses and the regulation of transcription and translation (Akbar et al ., 2020; da Silva et al ., 2020).…”

Section: Discussionmentioning

confidence: 99%

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Multiomic investigation of sugarcane mosaic virus resistance in sugarcane

Pimenta

Aono

Burbano

et al. 2022

Preprint

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Sugarcane mosaic virus (SCMV) is the main etiological agent of sugarcane mosaic disease, which affects sugarcane, maize and other economically important grass species. Despite the extensive characterization of quantitative trait loci controlling resistance to SCMV in maize, the genetic basis of this trait is largely unexplored in sugarcane. Here, a genome-wide association study was performed and machine learning coupled to feature selection was used for the genomic prediction of resistance to SCMV in a diverse panel of sugarcane accessions. This ultimately led to the identification of nine single nucleotide polymorphisms (SNPs) explaining up to 29.9% of the phenotypic variance and a 73-SNP set that predicted resistance with high accuracy, precision, recall, and F1 scores. Both marker sets were validated in additional sugarcane genotypes, in which the SNPs explained up to 23.6% of the phenotypic variation and predicted resistance with a maximum accuracy of 69.1%. Synteny analyses showed that the gene responsible for the major SCMV resistance in maize is probably absent in sugarcane, explaining why such a major resistance source is thus far unknown in this crop. Lastly, using sugarcane RNA sequencing data, markers associated with the resistance to SCMV in sugarcane were annotated and a gene coexpression network was constructed to identify the predicted biological processes involved in SCMV resistance. This allowed the identification of candidate resistance genes and confirmed the involvement of stress responses, photosynthesis and regulation of transcription and translation in the resistance to this virus. These results provide a viable marker-assisted breeding approach for sugarcane and identify target genes for future molecular studies on resistance to SCMV.

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