- Open Access
NS3 Protein from Rice stripe virus affects the expression of endogenous genes in Nicotiana benthamiana
Virology Journal volume 15, Article number: 105 (2018)
Rice stripe virus (RSV) belongs to the genus Tenuivirus. It is transmitted by small brown planthoppers in a persistent and circulative-propagative manner and causes rice stripe disease (RSD). The NS3 protein of RSV, encoded by the viral strand of RNA3, is a viral suppressor of RNA silencing (VSR). NS3 plays a significant role in viral infection, and NS3-transgenic plants manifest resistance to the virus.
The stability and availability of NS3 produced by transgenic Nicotiana benthamiana was investigated by northern blot analysis. The accumulation of virus was detected by western blot analysis. Transcriptome sequencing was used to identify differentially expressed genes (DEGs) in NS3-transgenic N. benthamiana.
When the host plants were inoculated with RSV, symptoms and viral accumulation in NS3-transgenic N. benthamiana were reduced compared with the wild type. Transcriptome analysis identified 2533 differentially expressed genes (DEGs) in the NS3-transgenic N. benthamiana, including 597 upregulated genes and 1936 downregulated genes. These DEGs were classified into three Gene Ontology (GO) categories and were associated with 43 GO terms. KEGG pathway analysis revealed that these DEGs were involved in pathways associated with ribosomes (ko03010), photosynthesis (ko00195), photosynthesis-antenna proteins (ko00196), and carbon metabolism (ko01200). More than 70 DEGs were in these four pathways. Twelve DEGs were selected for RT-qPCR verification and subsequent analysis. The results showed that NS3 induced host resistance by affecting host gene expression.
NS3, which plays dual roles in the process of infection, may act as a VSR during RSV infection, and enable viral resistance in transgenic host plants. NS3 from RSV affects the expression of genes associated with ribosomes, photosynthesis, and carbon metabolism in N. benthamiana. This study enhances our understanding of the interactions between VSRs and host plants.
Rice stripe virus (RSV) belongs to the genus Tenuivirus, and is characterized by transovarian transmission in a persistent, circulative-propagative manner by the small brown planthopper (Laodelphax striatellus) . Since 2000, RSV has occurred in the Yangtze River region and generally caused a 30–40% reduction in yield in eastern China [2, 3]. RSV comprises four single-stranded RNAs, named RNA1–RNA4 in order of decreasing molecular size, which encode seven proteins with an ambisense expression strategy . RNA1 encodes a protein in the negative-sense (virus-complementary [vc]) strand, which is called RNA-dependent RNA polymerase (RdRp, 337 kDa) . NS2 (silencing suppressor, 22.8 kDa) and NSvc2 (glycoprotein, 94 kDa) are produced from viral-sense RNA2 (vRNA2) and vcRNA2, respectively . RNA3 encodes a nonstructural protein that has been identified as a viral suppressor of RNA silencing (VSR; NS3, 23.9 kDa), and a nucleocapsid protein (CP, 35 kDa), which are derived independently from vRNA3 and vcRNA3 . vRNA4 and vcRNA4 encode a disease-specific protein (NS4) and a movement protein (NSvc4), respectively [9, 10].
RNA silencing is a defense system that interacts with viral genomic RNAs in plants. VSRs from different viral families do not share any obvious sequence similarity, but they generally bind to double stranded RNAs (dsRNAs), such as small interfering RNA (siRNA) duplexes, to suppress RNA silencing and block host RNA silencing pathways by targeting different steps [11,12,13]. The NS3 protein of Rice hoja blanca tenuivirus suppresses RNA silencing in plant and insect hosts by efficiently binding both siRNAs and microRNAs (miRNAs) . P19, the suppressor of Tomato bushy stunt virus (TBSV), functions by binding siRNAs to prevent them from forming RNA-induced silencing complex (RISC) . P69, the suppressor of Turnip yellow mosaic virus (TYMV), binds dsRNAs to inhibit the initiation of RNA silencing [11, 16, 17]. 2b protein, the suppressor of Cucumber mosaic virus (CMV), targets Argonaute (AGO) protein, a core component of RISC [11, 17]. NS3 of RSV, a reported RNA silencing suppressor, suppresses post-transcriptional gene silencing (PTGS) in Nicotiana benthamiana through its siRNA and dsRNA binding ability .
VSRs may enhance viral pathogenicity and accumulation, but transgenic plants expressing Tobacco etch virus (TEV) HC-Pro exhibit enhanced resistance to heterologous TBRV and to the oomycete Peronospora tabacina . Transgenic rice expressing RSV NS3 exhibit stronger resistance to rice blast disease (Magnaporthe grisea oryzae Guy) than wild-type rice . Furthermore, disease symptoms and viral accumulation are more moderate in transgenic rice than in wild-type rice after RSV inoculation . NS3 not only plays a critical role in combating viral infection at the early stages of disease, but also induces host resistance to the virus and other pathogens. Previous studies showed that NS3-induced miRNA accumulation in rice may lead to enhanced miRNA processing complexes and pathogenicity . The apparent dual roles of NS3 may be further explored using molecular techniques.
To elucidate the underlying mechanisms for host plant responses to RSV infection, we aimed to identify the key genes involved in plant-RSV interactions. Transcriptomic analysis has been a popular approach to explore the unknown players in a wide range of biological processes. In functional genomics, transcriptomic studies typically involve comparisons between biological samples collected under different conditions, and are used to analyze which genes are upregulated or downregulated in response to stresses [20,21,22]. RSV infection affects expression patterns of plant miR171 and several other miRNAs, and a reduction of osa-miR171b in RSV-infected rice contributes to RSV symptoms . How NS3 enhances host resistance to viral infection remains unclear, but this effect is likely to be mediated by changes in endogenous gene expression. NS3 induces the accumulation of several miRNAs and enhances viral infection and pathogenesis in rice; most of these miRNAs target pivotal genes associated with growth and development or pathogen resistance . This study employed transcriptome analysis and RT-qPCR to uncover the function of NS3 in transgenic N. benthamiana. To characterize N. benthamiana responses to NS3 at the transcriptome level, we identified genes that were differentially expressed between wild-type and NS3-expressing N. benthamiana up to the 6th leaf stage. We aimed to provide novel insights into the mechanisms underlying hosts-VSR interactions.
Plant growth and virus inoculation
Wild-type N. benthamiana and NS3-transgenic N. benthamiana were grown in a greenhouse under a 16-h light and 8-h dark cycle at 25 °C. NS3-transgenic N. benthamiana and wild-type N. benthamiana were inoculated with RSV. At 21 days post-infiltration, leaf tissues were collected. Three biological replicates (three plants per replicate) were processed independently.
Total RNA was isolated from frozen NS3-transgenic N. benthamiana plants, which were not infected with RSV, using Trizol (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s instructions. Fifty micrograms of DNase-treated total RNA was separated on a 15% agarose gel, and transferred electrophoretically to Hybond-N+ membranes using 20× SSC. Membranes were baked at 80 °C for 2 h. DNA oligonucleotides complementary to the putative NS3 sequences were end-labeled with digoxigenin (DIG) using the DIG Oligonucleotide 3′-end Labeling Kit (Roche, 11,585,614,910). Membranes were pre-hybridized for at least 1 h and hybridized overnight at 42 °C using the DIG High Prime Labeling and Detection Starter Kit II (Roche, 11,585,614,910).
To determine RSV protein accumulation in RSV-infected N. benthamiana and RSV-infected NS3-transgenic N. benthamiana plants, total proteins were extracted from 0.1 g of plant material in 500 μL of protein extraction buffer. For protein gel blotting, proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in a 12% gel and transferred to PVDF membranes (BioRad, Hercules, CA, USA). The membranes were blocked for 1 h with 5% milk in PBST buffer at room temperature. After washing, the membranes were incubated with anti-RSV CP antibody overnight at room temperature. Signals were developed in NBT/BCIP buffer (Transgen Biotech, Beijing, China).
RNA extraction and purification and transcriptome sequencing
Total RNA was extracted from N. benthamiana and NS3-transgenic N. benthamiana plants uninfected with RSV at the 6th leaf stage using Trizol reagent according to the manufacturer’s instructions (Invitrogen, Carlsbad, CA, USA). RNA was quantified using agarose gel electrophoresis and a NanoDrop. Five RNA samples (CK④, CK⑤, NS3–5①, NS3–6④, and NS3–9④) were sent to the BioMark company for transcriptome sequencing as follows: first, mRNA was purified using poly-T oligo-attached magnetic beads, followed by fragmentation and cDNA synthesis and purification. Library quality was then assessed using the Agilent 2100 system. Libraries were sequenced on the Solexa Illumina HiSeq platform (BioMark Company, Beijing, China). Clean reads were obtained from raw reads by removing reads containing adapter or poly-N, and low-quality reads. The Q20, Q30, GC-content, and sequence duplication level of the clean reads were calculated. Then, clean reads were directly used for further bioinformatics analysis.
Analysis of differentially expressed genes (DEGs)
The original data from transcriptome sequencing comprised raw reads, and clean reads were obtained after removing adaptor sequences and low-quality reads. All clean reads were mapped to Solanaceae reference sequences using bowtie software allowing a 2-bp mismatch. Each gene’s expression level was calculated using reads per kilobase per million mapped reads (RPKM). DEGs were identified by a P value ≤0.05 and an expression change of 2-fold or more (|log2Foldchange| ≥ 1) between the two treatments using IDEG6 software. Gene Ontology (GO) annotation and Kyoto Encyclopedia of Genes and Genomes (KEGG) classification were used to determine the main biological functions and pathways related to DEGs. GO was implemented using the GOseq R package, in which gene length bias was corrected, and GO terms with corrected P values ≤0.05 were considered significantly enriched in DEGs. GO annotation was performed using the REVIGO web server (http://revigo.irb.hr/). The KEGG classification of the DEGs was performed using the KEGG Mapper Annotate Sequence tool with the BlastKOALA server available on the Kyoto Encyclopedia of Genes and Genomes website (https://www.kegg.jp/kegg/tool/annotate_sequence.html).
Real-time quantitative PCR (RT-qPCR) validation
Total RNA was extracted from wild-type N. benthamiana and NS3-transgenic N. benthamiana at the 6th leaf stage using Trizol reagent according to the manufacturer’s instructions (Invitrogen, Carlsbad, CA, USA). cDNA was synthesized from 1 μg of total RNA in a volume of 20 μL using the PrimeScript RT Reagent Kit (TAKARA Bio, RR037A) according to the manufacturer’s instructions. RT-qPCR was performed using the SYBR Green Real-time PCR Master Mix (ToYoBo, JAPAN) with the iQ5 Real-Time PCR system (Bio-Rad, USA) with gene-specific primers (Table 1), each reaction containing 10.0 μL of SYBR Green Real-time PCR Master Mix, 1.0 μL of cDNA, 0.5 μL of (10 pM) primers, and 8.0 μL of water. The expression levels of transcripts are presented relative to the corresponding control samples for each condition. The ubiquitin gene was used as an internal control gene. All RT-qPCR experiments were performed in triplicate.
Symptoms and molecular characteristics of NS3-transgenic N. benthamiana after infection with RSV
We investigated the stability of NS3 expression in transgenic N. benthamiana by northern blot analysis, and the results showed that NS3 was transcribed in plants from different transgenic lines (NS3–5, NS3–6, and NS3–9) (Fig. 1b). To examine the susceptibility of transgenic plants to RSV, NS3-transgenic N. benthamiana plants and wild-type N. benthamiana plants were inoculated with RSV. Twenty-one days post-inoculation (dpi), viral symptoms of chlorotic and stunted stripes appeared on the leaves of wild-type N. benthamiana, but not NS3-transgenic N. benthamiana (Fig. 1a). RSV infection rates among plants were determined by enzyme-linked immunosorbent assay (ELISA). The results showed that only 35.29% of NS3-transgenic N. benthamiana plants were infected with RSV, compared to 47.06% of wild-type N. benthamiana plants (Fig. 1c). Western blot analysis of RSV accumulation in inoculated symptomatic N. benthamiana plants showed that the RSV titer in wild-type N. benthamiana plants was higher than in NS3-transgenic N. benthamiana plants (Fig. 1d), suggesting that NS3 is associated with plant disease symptom development.
Overview of transcriptome sequencing and analysis of DEGs
To explore the transcriptional responses of the transgenic N. benthamiana to RSV, RNA from two control (CK) N. benthamiana plants and three NS3-transgenic N. benthamiana plants was used to construct five cDNA libraries. After adaptor sequence trimming and removing low quality reads, clean reads were obtained from four libraries of “NS3-transgenic” and “CK” samples. In total, 43.64 Gb of clean data with Q30 content > 85% were available for subsequent analysis (Table 2). Clean reads were mapped to the Solanaceae reference genome (https://solgenomics.net) using bowtie software allowing for a 2-bp mismatch. The results are shown in Table 3. The proportion of mapped gene numbers to reference gene numbers exceeded 75% in these five libraries (Table 3), indicating that our RNA-seq data were sufficient for subsequent gene expression analysis.
To characterize N. benthamiana candidate genes that responded to NS3, we analyzed five transcriptome profiles. First, the expression level of each gene was normalized as clean reads per kilobase of exon model per million mapped reads (RPKM). Then, DEGs were identified by comparing genes expressed in transgenic N. benthamiana plant samples with those from CK plants with the stringent criteria of a false discovery rate (FDR) < 0.001 and |log2Foldchange| > 1. In total, 2533 DEGs were identified in these five transcriptome profiles, including 597 upregulated genes and 1936 downregulated genes (Fig. 2).
These results showed that the majority of DEGs were downregulated in NS3-transgenic N. benthamiana compared with control plants, suggesting that NS3 affected the expression of endogenous genes.
GO and KEGG pathway enrichment analysis
In total, 2533 DEGs were assigned to various functional categories following the GO functional classification scheme (Fig. 3). Based on their putative functions, the DEGs were classified into three GO categories (biological process, cellular component, and molecular function), containing 43 GO terms. The three most highly represented GO terms under the biological process category were “metabolic process,” “cellular process”, and “single-organism process”. The five most abundant terms in the cellular component category were “cell part,” “cell,” “organelle,” “membrane”, and “organelle part”. The most abundant GO terms in the molecular function category were “catalytic activity” and “binding”.
We conducted KEGG classification of the DEGs. The 2533 DEGs were classified into five groups (cellular processes, environmental information processing, genetic information processing, metabolism, and organismal systems) related to 50 KEGG pathways (Figs. 4 and 5). The four most common pathways were “ribosome,” “carbon metabolism,” “photosynthesis”, and “photosynthesis-antenna proteins”. There were over 70 DEGs in each of these pathways.
Validation of transcriptome data by RT-qPCR
We used RT-qPCR to verify the RNA-seq data (primers listed in Table 1). Genes were chosen from among DEGs in the most common pathways (ribosome and photosynthesis). The results indicated that all gene expression patterns were consistent between RT-qPCR analysis and RNA-seq analysis (Fig. 6).
VSR is a determinant of viral pathogenicity. Recombinant virus co-expressing heterogeneous VSR is associated with increased virulence and more severe symptoms in host plants. However, our previous research showed that NS3-transgenic rice exhibited enhanced resistance to Magnaporthe oryzae . The expression of some VSRs as transgenes in plants also induced developmental defects in vegetative and reproductive organs [24,25,26]. Conversely, in this study we found that NS3-transgenic N. benthamiana plants not only had the normal phenotype, as observed with transgenic N. benthamiana expressing P19 from TBSV and P25 from Potato virus X (PVX) [25, 27], but also exhibited increased resistance to RSV, as observed with transgenic N. benthamiana expressing HC-Pro from TEV . The underlying mechanism for this resistance requires further investigation, but is presumably related to NS3 activity, possibly in the nucleus . Primary-miRNAs (pri-mRNAs) were differentially expressed in rice infected by RSV, and NS3 was associated with decreased accumulation of pri-miRNAs; however, the mechanism by which NS3 influences pri-miRNA expression levels remains unclear .
Several reports indicated that VSRs have the ability to induce upregulated expression of genes related to the plant responses to biotic or abiotic stress, in addition to their pathogenic roles during viral infection [27, 28]. For example, expression of CMV VSR 2b protein in transgenic plants conferred increased drought tolerance . Expression of the PVX-specific P25 silencing suppressor in transgenic tobacco plants caused upregulation of 138 transcripts belonging to genes that are induced by various biotic and nonspecific stresses . In this study, we found that NS3 affected the expression of endogenous genes in N. benthamiana. These DEGs were associated with 43 GO terms belonging to three categories, as well as four KEGG pathways. The most highly enriched GO terms were “metabolic process,” “single-organism process,” “cell part,” “membrane”, and “organelle part”. The key KEGG pathways were related to “ribosome,” “photosynthesis,” “photosynthesis-antenna proteins”, and “carbon metabolism”. Further functional analysis is required to clarify the roles of genes associated with these pathways. We suggest that NS3 has dual functions, including facilitating viral infection as a VSR and inhibiting pathogenic development as an inducer of host defense.
The fundamental unit of chromatin is the nucleosome, which is composed of approximately 146 base pairs of DNA wrapped around a histone octamer containing two copies each of histones H2A, H2B, H3, and H4. Chromatin structure influences the accessibility of transcription factors and cofactors for DNA-tempered processes. The structure and function of chromatin are regulated by multiple epigenetic mechanisms, including DNA methylation, histone modifications, adenosine triphosphate (ATP)-dependent chromatin remodeling, placement of histone variants, and regulation by non-coding RNA . Since the histone tail domains are highly accessible to the nuclear environment, they constitute attractive targets for signal-activated enzymes, and may function as important links between signal transduction and gene expression . A growing body of research suggests that histone modifications play vital roles in several chromatin-based processes . Recent research has demonstrated that a single methylated H3K36 per nucleosome is sufficient to silence cryptic transcription in vivo. The modification of nucleosomes, including histones, may lead to changes in biological processes and the plant response to abiotic stress [32, 33]. The transgenic expression of RSV NS3 downregulated histone-related genes, indicating that NS3 could affect the nuclear environment of host cells.
Leucine-rich repeats receptor-like kinase (LRR-Like) genes represent a large and complex gene family in plants, and are involved mainly in development and stress responses. These receptors are composed of an LRR-containing extracellular domain (ECD), a transmembrane (TM) domain, and an intracellular kinase domain (KD) . Transcriptome analysis predicted downregulated LRR genes in the NS3-transgenic N. benthamiana, although the precise functional roles of these genes remain unclear. However, it is plausible that NS3 expression affected the TM domain, which is required for RSV infection.
A newly discovered gene for a NAC domain protein in rice confers resistance to Rice dwarf virus (RDV) . Similarly, genes related to the NAC domain were downregulated and associated with enhanced resistance in NS3-transgenic N. benthamiana. The functions of these genes will be verified in subsequent vector-based experiments using vectors. Upregulated genes related to heat shock protein (HSP) play a role in Agrobacterium-mediated plant transformation; therefore, decreased or increased HSP90 expression may affect transformation susceptibility . The function of HSP may be further investigated using transformation studies.
In this study, we showed that NS3-transgenic N. benthamiana plants not only exhibited a normal phenotype, but also possessed enhanced resistance to RSV. We investigated the influence of NS3 on gene expression using transcriptomic analysis. NS3 expression was associated with 2533 DEGs in N. benthamiana, most of which were downregulated. GO annotation and KEGG pathway enrichment analysis revealed biological pathways affected by NS3. These results enhance our understanding of the function of VSR in host plants.
Cucumber mosaic virus
Differentially expressed genes
Heat shock protein
Leucine-Rich Repeats Receptor-Like Kinase
post-transcriptional gene silencing
RNA-dependent RNA polymerase
Rice dwarf virus
RNA-induced silencing complex
Rice stripe virus
Real-time quantitative PCR
Tomato bushy stunt virus
Tobacco etch virus
Turnip yellow mosaic virus
Viral suppressor of RNA silencing
Falk BW, Tsai JH. Biology and molecular biology of viruses in the genus Tenuivirus. Annu Rev Phytopathol. 1998;36:139–63.
Wang HD, Chen JP, Zhang HM, Sun XL, Zhu JL, Wang AG, Sheng WX, Adams MJ. Rencent Rice stripe virus epidemics in Zhejiang province, China, and experiments on sowing date, disease-yield loss relationships, and seedling susceptibility. Plant Dis. 2008;92:78–81.
Wei TY, Yang JG, Liao FR, Gao FL, Lu LM, Zhang XT, Li F, Wu ZJ, Lin QY, Xie LH. Genetic diversity and population structure of Rice stripe virus in China. J Gen Virol. 2009;90(Pt4):1025–34.
Cho WK, Lian S, Kim SM, Park SH, Kim KH. Current insights into research on Rice stripe virus. Plant Pathol J. 2013;29:223–33.
Barbier P, Takahashi M, Nakamura I, Toriyama S, Ishihama A. Solubilization and promoter analysis of RNA polymerase from Rice stripe virus. J Virol. 1992;66:6171–4.
Takahashi M, Toriyama S, Hamamastsu C, Ishihama A. Nucleotide sequence and possible ambisense coding strategy of Rice stripe virus RNA segment 2. J Gen Virol. 1993;74(Pt4):769–73.
Lian S, Cho WK, Jo Y, Kim SM, Kim KH. Interaction study of Rice stripe virus proteins reveals a region of the nucleocapsid protein (NP) required for NP self-interaction and nuclear localization. Virus Res. 2014;183:6–14.
Xiong RY, Wu JX, Zhou YJ, Zhou XP. Characterization and subcellular localization of an RNA silencing suppressor encoded by Rice stripe tenuivirus. Virol. 2009;387:29–40.
Kakutani T, Hayano Y, Hayashi T, Minobe Y. Ambisense segment 4 of Rice stripe virus: possible evolutionary relationship with phleboviruses and uukuviruses (Bunyaviridae). J Gen Virol. 1990;71:1427–32.
Xiong RY, Wu JX, Zhou YJ, Zhou XP. Identification of a movement protein of the tenuivirus Rice stripe virus. J Virol. 2008;82:12304–11.
Dian-Pendon JA, Ding SW. Direct and indirect roles of viral suppressors of RNA silencing in pathogenesis. Annu Rev Phytopathol. 2008;46:303–26.
Pruss GJ, Lawrence CB, Bass T, Li QQ, Bowman LH, Vance V. The potyviral suppressor of RNA silencing confers enhanced resistance to multiple pathogens. Virol. 2004;320:107–20.
Shamadi N, Zytnicki M, Charbonnel C, Elvira-Matelot E, Bochnakian A, Comella P, Mallory AC, Lepere G, Saez-Vasquez J, Vaucheret H. Plants encode a general siRNA suppressor that is induced and suppressed by viruses. PLoS Biol. 2015;13:e1002326.
Hemmes H, Lakatos L, Goldbach R, Burgyan J, Prins M. The NS3 protein of Rice hoja blanca Tenuivirus suppresses RNA silencing in plant and insect hosts by efficiently binding both siRNAs and miRNAs. RNA. 2007;13:1079–89.
Lakatos L, Szittya G, Silhavy D, Burgyan J. Molecular mechanism of RNA silencing suppression mediated by p19 protein of tombusviruses. EMBO J. 2004;23:876–84.
Dey KK, Borth WB, Melzer MJ, Wang ML, Hu JS. Analysis of Pineapple mealybug wilt associated virus −1 and −2 for potential RNA silencing suppressors and pathogenicity factors. Viruses. 2015;7:969–95.
Gururani MA, Venkatesh J, Upadhyaya CP, Nookaraju A, Pandey SK, Park SW. Plant disease resistance genes: current status and future directions. Physiol MolPlant Pathol. 2012;78:51–65.
Wu GT, Wang JY, Yang Y, Dong B, Wang YL, Sun GC, Yan CQ, Yan F, Chen JP. Transgenic rice expressing Rice stripe virus NS3 protein, a suppressor of RNA silencing, shows resistance to rice blast disease. Virus Gene. 2014;48:566–9.
Zheng LJ, Zhang C, Shi CN, Yang ZR, Wang Y, Zhou T, Sun F, Wang H, Zhao SS, Qin QQ, et al. Rice stripe virus NS3 protein regulates primary miRNA processing through association with the miRNA biogenesis factor OsDRB1 and facilitates virus infection in rice. PLoS Pathog. 2017;13:e1006662.
Huang CJ, Cun YP, Yu HQ, Tong ZJ, Xiao BG, Song ZB, Wang BW, Li YP, Liu Y. Transcriptomic profile of tobacco in response to Tomato zonate spot orthotospovirus infection. Virol J. 2017;14:153–63.
Zhai L, Xu L, Wang Y, Zhu XW, Feng HY, Li C, Luo XB, Everlyne MM, Liu LW. Transcriptional identification and characterization of differentially expressed genes associated with embryogenesis in radish (Raphanus sativus L.). Sci Rep. 2016;6:21652.
Yin XJ, Hiraga S, Hajika M, Nishimura M, Komatsu S. Transcriptomic analysis reveals the flooding tolerant mechanism in flooding tolerant line and abscisic acid treated soybean. Plant Mol Biol. 2017;93:479–96.
Tong AZ, Yuan Q, Wang S, Peng JJ, Lu YW, Zheng HY, Lin L, Chen HR, Gong YF, Chen JP. Altered accumulation of Osa-miR171b contributes to Rice stripe virus infection by regulating disease symptoms. J Exp Bot. 2017;68:4357–67.
Shen WJ, Ruan XL, Li XS, Zhao Q, Li HP. RNA silencing suppressor Pns11 of Rice gall dwarf virus induces virus-like symptoms in transgenic rice. Arch Virol. 2012;157:1531–9.
Siddiqui SA, Sarmiento C, Truve E, Lehto H, Lehto K. Phenotypes and functional effects caused by various viral RNA silencing suppressors in transgenic Nicotiana benthamiana and N. tabacum. Mol Plant Microbe Interaction. 2008;21:178–87.
Sire C, Bangratz-Reyser M, Fargette D, Brugidou C. Genetic diversity and silencing suppression effects of Rice yellow mottle virus and the P1 protein. Virol J. 2008;5:55.
Jada B, Soitamo AJ, Lehto K. Organ-specific alteration in tobacco transcriptome caused by the PVX-derived P25 silencing suppressor transgene. BMC Plant Biol. 2013;13:8.
Westwood JH, McCann L, Naish M, Dixon H, Murphy AM, Stancombe MA, Bennett MH, Powell G, Webb AA, Carr JP. A viral RNA silencing suppressor interferes with abscisic acid-mediated signalling and induces drought tolerance in Arabiodopsis thaliana. Mol Plant Pathol. 2013;14:158–70.
Berger SL. The complex language of chromatin regulation during transcription. Nature. 2007;447:407–12.
Cheung P, Allis CD, Sassone-Corsi P. Signaling to chromatin through histone modifications. Cell. 2000;103:263–71.
Cao LL, Shen C, Zhu WG. Histone modifications in DNA damage response. Sci China Life Sci. 2016;59:257–70.
Yuan LY, Liu XC, Luo M, Yang SG, Wu KQ. Involvement of histone modifications in plant abiotic stress responses. J Integr Plant Biol. 2013;55:892–901.
Ichikawa Y, Connelly CF, Appleboim A, Miller TC, Jacobi H, Abshiru NA, Chou HJ, Chen YY, Sharma U. Zheng YP. A synthetic biology approach to probing nucleosome symmetry. elife. 2017;6:e28836.
Dufayard JF, Bettembourg M, Fischer I, Droc G, Guiderdoni E, Perin C, Chantret N, Dievart A. New insights on leucine-rich repeats receptor-like kinase orthologous relationships in angiosperms. Front Plant Sci. 2017;8:381.
Yoshii M, Shimizu T, Yamazaki M, Higashi T, Miyao A, Hirochika H, Omura T. Disruption of novel gene for a NAC-domain protein in rice confers resistance to Rice dwarf virus. Plant J. 2009;57:615–25.
Park SY, Yin XY, Duan KX, Gelvin SB, Zhang ZYJ. Heat shock protein 90.1 plays a role in agrobacterium-mediated plant transformation. Mol Plant. 2014;7:1793–6.
We would like to thank Junmin Li in the Zhejiang Provincial Key Laboratory of Plant Virology, Institute of Virology and Biotechnology, Zhejiang Academy of Agricultural Sciences, for analyzing transcriptome data.
This research was financially supported by the National Natural Science Foundation of China (31601607) and the Fundamental Research Funds for the Central Universities (SWU114030, XDJK2015C168).
Availability of data and materials
All data generated or analyzed during this study are included in this published article.
Ethics approval and consent to participate
Consent for publication
The authors declare that they have no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Wu, G., Zheng, G., Hu, Q. et al. NS3 Protein from Rice stripe virus affects the expression of endogenous genes in Nicotiana benthamiana. Virol J 15, 105 (2018). https://0-doi-org.brum.beds.ac.uk/10.1186/s12985-018-1014-7
- Rice stripe virus
- Suppressor of RNA silencing
- Nicotiana benthamiana