Monoclonal Antibody-Based Serological Detection of Rice Stripe Mosaic Virus Infection in Rice Plants or Leafhoppers.

Rice stripe mosaic virus (RSMV) is a rhabdovirus recently found in southern part of China and can cause severe reduction in rice production. To establish serological methods for RSMV epidemiological studies and to establish a control strategy for this virus, we first purified RSMV virions from infected rice plants and then used them as an immunogen to produce four RSMV-specific monoclonal antibodies (MAbs) (i.e.,1D4, 4A8, 8E4 and 11F11). With these MAbs, we have developed a highly specific and sensitive antigen-coated plate enzyme-linked immunosorbent assay (ACP-ELISA), a Dot-ELISA and a Tissue print-ELISA for rapid detections of RSMV infection in rice plants or in leafhoppers. Our results showed that RSMV can be readily detected in RSMV-infected rice plant tissue crude extracts diluted at 1:20,971,520 (w/v, g/mL) through ACP-ELISA or diluted at 1:327,680 (w/v, g/mL) through Dot-ELISA. Both ACP-ELISA and Dot-ELISA can also be used to detect RSMV infection in individual RSMV viruliferous leafhopper (Recilia dorsalis) homogenate diluted at 1:307,200 and 1:163,840 (individual leafhopper/µL), respectively. Detection of RSMV infection in field-collected rice samples or in RSMV viruliferous leafhoppers indicated that the three serological methods can produce same results with that produced by RT-PCR (19 of the 33 rice samples and 5 of the 16 leafhoppers were RSMV-positive). We consider that the four MAbs produced in this study are very specific and sensitive, and the three new serological methods are very useful for detections of RSMV infection in rice plants or in leafhoppers and the establishment of the disease control strategies.

Potential functional pathways of plant RNA virus-derived small RNAs in a vector insect.

During infection, RNA viruses can produce two types of virus-derived small RNAs (vsRNAs), small interfering RNA (siRNA) and microRNA (miRNA), that play a key role in RNA silencing-mediated antiviral mechanisms in various hosts by associating with different Argonaute (Ago) proteins. Ago1 has been widely identified as an essential part of the miRNA pathway, while Ago2 is required for the siRNA pathway. Thus, analysis of the interaction between vsRNAs and Ago proteins can provide a clue about which pathway the vsRNA may be involved in. In this study, using rice stripe virus (RSV)-small brown planthoppers (Laodelphax striatellus, Fallen) as an infection model, the interactions of eight vsRNAs derived from four viral genomic RNA fragments and Ago1 or Ago2 were detected via the RNA immunoprecipitation (RIP) method. vsRNA4-1 and vsRNA4-2 derived from RSV RNA4 were significantly enriched in Ago1-immunoprecipitated complexes, whereas vsRNA2-1 and vsRNA3-2 seemed enriched in Ago2-immunoprecipitated complexes. vsRNA1-2 and vsRNA2-2 were detected in both of the two Ago-immunoprecipitated complexes. In contrast, vsRNA1-1 and vsRNA3-1 did not accumulate in either Ago1- or Ago2-immunoprecipitated complexes, indicating that regulatory pathways other than miRNA or siRNA pathways might be employed. In addition, two conserved L. striatellus miRNAs were analysed via the RIP method. Both miRNAs accumulated in Ago1-immunoprecipitated complexes, which was consistent with previous studies, suggesting that our experimental system can be widely used. In conclusion, our study provides an accurate and convenient detection system to determine the potential pathway of vsRNAs, and this method may also be suitable for studying other sRNAs.

Melatonin is responsible for rice resistance to rice stripe virus infection through a nitric oxide-dependent pathway.

Rice stripe virus (RSV) causes one of the most important rice virus diseases of plants in East Asia. However, the molecular mechanisms controlling rice resistance to RSV infection are largely unknown. Recently, several studies presented a novel model that melatonin (MT) and nitric oxide (NO) participate in the plant-pathogen interaction in a synergetic manner. In this study, there was a difference in MT content between two rice varieties that correlated with one being susceptible and one being resistant to RSV, which suggested that MT is related to RSV resistance. In addition, a test with two NO biosynthesis inhibitors revealed that NO inhibitor were able to increase the disease incidence of RSV. A pharmacological experiment with exogenous MT and NO showed that increased MT and NO in the MT-pretreated plants led to lower disease incidences; however, only NO increased in a NO-releasing reagent [sodium nitroprusside (SNP)] pretreated plants. The expressions level of OsPR1b and OsWRKY 45 were significantly induced by MT and NO. These results suggest that rice resistance to RSV can be improved by increased MT through a NO-dependent pathway.

Recent progress on gene silencing/suppression by virus-derived small interfering RNAs in rice viruses especially Rice grassy stunt virus.

Noncoding RNAs play essential functions during epigenetic regulation of gene expression and development in numerous organisms. Three type of small noncoding RNAs found in eukaryotes, which are small interfering RNAs (siRNAs), microRNAs (miRNAs) and piwi-interacting RNAs (piRNAs). Small RNAs (sRNAs) originated from infecting viruses are known as virus-derived small interfering RNAs (vsiRNAs), are responsible for RNA silencing in plants. However, Virus-induced gene silencing (VIGS) is mainly dependent on RNA silencing (RNAi). Interestingly, RNA silencing happens in plants and insects during viral infections. VsiRNAs originate from dsRNA molecules which further require hosts Dicer-like (DCL) proteins, RNA dependent RNA polymerase (RdRP) proteins, and Argonaute (AGO) proteins. RdRP uses ssRNA for complete RNA amplification process as well as DCL dependent secondary vsiRNA formation. Viral Suppressors of RNA silencing (VSRs) interfere with the movement of signals during silencing mechanism. Moreover, intercellular movement of viruses is facilitated by virus-encoded movement proteins. Proteomic and Transcriptomic mechanisms regulated by specific factors like microRNAs, which has become an essential factor of gene regulation. RNAi is also involved in gene suppression by regulating the transcriptional and post-transcriptional gene expression in many eukaryotes. Rice grassy stunt virus (RGSV) is a member of genus Tenuivirus. Although, there is no much work done on RGSV, but this virus has become very potent and destructive, and effects rice crop in many Asian countries, particularly in China. In this review, we have highlighted the rice viruses' biology and silencing suppressors. This work will be helpful for plant virologists in understanding the role of vsiRNAs mechanism in rice viruses especially RGSV.

Developing japonica rice introgression lines with multiple resistance genes for brown planthopper, bacterial blight, rice blast, and rice stripe virus using molecular breeding.

Yield losses as a result of biotic stresses by fungi, bacteria, viruses, and insects are a key challenge in most rice cultivation areas. The development of resistant cultivars is considered an efficient and sustainable approach to mitigate rice yield reduction. In the present study, we describe the development of japonica rice introgression lines with multiple resistance genes (MR lines), resistant to four different types of biotic stresses, and compare the agronomic performance, yield, and grain quality parameters of these lines with those of the recurrent parent. A total of nine MR lines were developed by marker-assisted backcrossing, which combined five single-R genes in a japonica background with a minimum of linkage drag. All the MR lines harbored the R genes Bph18 and qSTV11SG and two Pi genes (Pib + Pik) in common, offering resistance to brown planthopper (BPH), rice stripe virus (RSV), and rice blast disease, respectively. In the case of bacterial blight (BB), Xa40 was detected in only five out of the nine and Xa3 was validated in the others. In particular, the five MR lines pyramiding the R genes (Bph18 + qSTV11SG + Pib + Pik) in combination with Xa40 showed stable resistance to all bioassays for BPH, BB, blast, and RSV. The MR lines did not show any negative effects on the main agronomic traits, including yield production and rice grain quality. The lines have significant potential to stabilize rice yield and minimize production costs in disease and pest-prone areas in Korea, through the pyramiding of five R genes using a marker-assisted backcrossing strategy.

P2 of Rice grassy stunt virus (RGSV) and p6 and p9 of Rice ragged stunt virus (RRSV) isolates from Vietnam exert suppressor activity on the RNA silencing pathway.

In Vietnam, the two main viruses that cause disease in rice are the Rice grassy stunt virus (RGSV) and the Rice ragged stunt virus (RRSV). Outbreaks of these two viruses have dramatically decreased rice production in Vietnam. Because natural resistance genes are unknown, an RNAi strategy may be an alternative method to develop resistance to RGSV and RRSV. However, this strategy will be efficient only if putative silencing suppressors encoded by the two viruses are neutralized. To identify these suppressors, we used the classical green fluorescent protein (GFP) agroinfiltration method in Nicotiana benthamiana. Then, we investigated the effects of viral candidate proteins on GFP expression and GFP siRNA accumulation and their interference with the short- or long-range signal of silencing. RGSV genes s2gp1, s5gp2, and s6gp1 and RRSV genes s5gp1, s6gp1, s9gp1, and s10gp1 were selected for viral silencing suppressor investigation according to their small molecular weight, the presence of cysteines, or the presence of a GW motif in related protein products. We confirmed that protein p6 of RRSV displays mild silencing suppressor activity and affects long-range silencing by delaying the systemic silencing signal. In addition, we identified two new silencing suppressors that displayed mild activity: p2 of RGSV and p9 of RRSV.

Functional comparison of RNA silencing suppressor between the p5 protein of rice grassy stunt virus and the p3 protein of rice stripe virus.

Rice grassy stunt virus (RGSV) is a member of the genus Tenuivirus, which includes rice stripe virus (RSV), as the type species. A viral suppressor of RNA silencing (VSR) of RGSV has not been identified, whereas the p3 protein of RSV (RSVp3) encoded by the viral-sense (v) strand of RNA3 has been reported to act as a VSR. In this study, we examined the VSR function of the p5 protein of RGSV (RGSVp5), encoded by vRNA5. Expecting it to correspond to the vRNA3 of RSV, we compared the VSR function of RGSVp5 with that of RSVp3. In an Agrobacterium-mediated transient expression assay using a transgenic line of Nicotiana benthamiana that expressed green fluorescent protein and the wild type, RGSVp5 suppressed sense transgene-mediated post-transcriptional gene silencing (S-PTGS), inverted-repeat (IR) transgene-induced PTGS (IR-PTGS), and the systemic spread of GFP silencing, as in the case with RSVp3. By contrast, a gel mobility shift assay revealed that RGSVp5 did not have any distinct binding activity with 21-, 22-, or 24-nucleotide small interfering RNA (siRNA) duplexes, whereas RSVp3 binds to all three sizes of siRNA duplexes. Furthermore, the transiently expressed p5 protein fused with GFP was dispersed mainly in the cytoplasm, whereas the GFP-fused p3 protein of RSV was localized both in the nucleus and in the cytoplasm. Our results suggest that RGSVp5 functions as a VSR but that the suppression mechanism of RNA silencing and the subcellular localization of RGSVp5 differ from those of the analogous VSR, RSVp3, even in the same genus.

[Construction of rice stripe virus NS2 and NS3 Co-RNAi transgenic rice and disease-resistance analysis].

NS2 and NS3 are two post-transcriptional gene silencing suppressors that are encoded by Rice stripe virus. Gene silencing suppressors are always related to the pathogenicity of viruses. In this study, the cDNA of NS2 and NS3 were recombined by overlapping PCR assays, ligated to the RNAi vector, and inserted into the PXQ expression vector using Pst I; the expressed vector was transferred into calluses induced from seeds of the japonica rice cultivar, 'Nipponbare', using an Agrobacterium-mediated method. Thirty-one T0 transgenic plants were selected by G418 screening. PCR and southern blot analyses confirmed that the target gene was transformed into transgenic rice successfully, and different transgenic plants contained various copies of the gene. The disease resistance assay revealed that T0 transgenic rice had a delayed onset of RSV for approximately 10-20 d, and the accumulation of virus in the transgenic plants was reduced by 30%-50%. This was related to the delayed onset of disease.

Fine mapping and identification of candidate rice genes associated with qSTV11(SG), a major QTL for rice stripe disease resistance.

Rice stripe disease, caused by rice stripe virus (RSV) is a serious constraint to rice production in subtropical regions of East Asia. We performed fine mapping of a RSV resistance QTL on chromosome 11, qSTV11 ( SG ), using near-isogenic lines (NILs, BC(6)F(4)) derived from a cross between the highly resistant variety, Shingwang, and the highly susceptible variety, Ilpum, using 11 insertion and deletion (InDel) markers. qSTV11 ( SG ) was localized to a 150-kb region between InDel 11 (17.86 Mbp) and InDel 5 (18.01 Mbp). Among the two markers in this region, InDel 7 is diagnostic of RSV resistance in 55 Korean japonica and indica rice varieties. InDel 7 could also distinguish the allele type of Nagdong, Shingwang, Mudgo, and Pe-bi-hun from Zenith harboring the Stv-b ( i ) allele. As a result, qSTV11 ( SG ) is likely to be the Stv-b ( i ) allele. There were 21 genes in the 150-kb region harboring the qSTV11 ( SG ) locus. Three of these genes, LOC_Os11g31430, LOC_Os11g31450, and LOC_Os11g31470, were exclusively expressed in the susceptible variety. These expression profiles were consistent with the quantitative nature along with incomplete dominance of RSV resistance. Sequencing of these genes showed that there were several amino acid substitutions between susceptible and resistant varieties. Putative functions of these candidate genes for qSTV11 (SG) are discussed.

RNA-dependent RNA polymerase 6 of rice (Oryza sativa) plays role in host defense against negative-strand RNA virus, Rice stripe virus.

RNA-dependent RNA polymerases (RDRs) from fungi, plants and some invertebrate animals play fundamental roles in antiviral defense. Here, we investigated the role of RDR6 in the defense of economically important rice plants against a negative-strand RNA virus (Rice stripe virus, RSV) that causes enormous crop damage. In three independent transgenic lines (OsRDR6AS line A, B and C) in which OsRDR6 transcription levels were reduced by 70-80% through antisense silencing, the infection and disease symptoms of RSV were shown to be significantly enhanced. The hypersusceptibilities of the OsRDR6AS plants were attributed not to enhanced insect infestation but to enhanced virus infection. The rise in symptoms was associated with the increased accumulation of RSV genomic RNA in the OsRDR6AS plants. The deep sequencing data showed reduced RSV-derived siRNA accumulation in the OsRDR6AS plants compared with the wild type plants. This is the first report of the antiviral role of a RDR in a monocot crop plant in the defense against a negative-strand RNA virus and significantly expands upon the current knowledge of the antiviral roles of RDRs in the defense against different types of viral genomes in numerous groups of plants.

Concentración mínima inhibitoria de higromicina B en callos embriogénicos de arroz -Oryza sativa L / Minimum inhibitory concentration of higromycin B in rice embryogenic calli -Oryza sativa L

Uno de los elementos imprescindibles en la ingeniería genética de plantas es un sistema de selección eficiente. El propósito de este trabajo fue evaluar la sensibilidad al marcador de selección higromicina B, de callos embriogénicos obtenidos a partir del escutelo de semilla de tres variedades colombianas de arroz (FEDEARROZ 2000, FEDEARROZ 50 y FEDEARROZ 369). Además, se validó la respuesta de estas variedades al protocolo de regeneración empleado. Se probaron cuatro concentraciones del antibiótico (25 mg/L, 50 mg/L, 75 mg/L y 100 mg/L) más un control sin higromicina B. Los resultados obtenidos mostraron que una concentración de 50 mg/L de antibiótico en el medio de regeneración es adecuada para la selección. Con esta concentración se impide la formación de brotes, aunque los callos no mueren completamente. Por otra parte, se estableció que el protocolo de regeneración utilizado es de baja eficiencia y, por consiguiente, es necesario optimizarlo para poder usarlo en procesos de ingeniería genética de cultivares colombianos de arroz.

An efficient selection system is one of the most important elements of plant genetic engineering. The purpose of this study was to evaluate the sensitivity of scutellum-derived embriogenic calli obtained from three colombian rice varieties (FEDEARROZ 2000, FEDEARROZ 50 and FEDEARROZ 369), to the selection marker hygromycin B. Aditionally, the response of these varieties to the regeneration protocol was measured. Four antibiotic concentrations were tested (25 mg/L, 50 mg/L, 75 mg/L and 100 mg/L) plus one control without hygromycin B. The results show that 50 mg/L of antibiotic in the regeneration medium is adequate for selection. This concentration prevents the formation of shoots, though the calli do not die. It was also established that the regeneration protocol is a low-efficiency system and it needs to be improved, in order to use it for colombian rice genetic engineering.

Production of transgenic rice new germplasm with strong resistance against two isolations of Rice stripe virus by RNA interference.

Rice stripe disease, with the pathogen Rice stripe virus (RSV), is one of the most widespread and severe virus diseases. Cultivating a resistant breed is an essential and efficient method in preventing rice stripe disease. Following RNA interference (RNAi) theory, we constructed three RNAi binary vectors based on coat protein (CP), special-disease protein (SP) and chimeric CP/SP gene sequence. Transgenic lines of rice cv. Yujing6 were generated through Agrobacterium-mediated transformation. We inoculated T1 generation plants from each line derived from CP/SP, CP, and SP transgenic rice plants with two RSV isolates from Shandong Province and Jiangsu Province using viruliferous vector insects. In these resistance assays, chimeric CP/SP RNAi lines showed stronger resistance against two isolates than CP or SP single RNAi lines. Stable integration and expression of RNAi transgenes were confirmed by Southern and northern blot analysis of independent transgenic lines. In the resistant transgenic lines, lower levels of transgene transcripts and specific short interference RNAs were observed relative to the susceptible transgenic plant, which showed that virus resistance was increased by RNAi. Genetic analysis demonstrated that transgene and virus resistance was stably inherited in the T2 progeny plants.

Expression of defense genes and activities of antioxidant enzymes in rice resistance to rice stripe virus and small brown planthopper.

The rice variety Tai06-1 is resistant to rice stripe disease and Xiushui63 is a highly susceptible rice variety to this disease. These two varieties were used to analyze the expression patterns of defense genes and antioxidant defense responses at the seedling stage, upon feeding with viruliferous small brown planthopper (SBPH) and nonviruliferous SBPH, respectively. The expression levels of CP (coat protein) gene of rice stripe virus (RSV) were higher upon feeding with viruliferous SBPH in Xiushui63 than in Tai06-1 throughout most of the experimental period, suggesting that RSV replicaiton is disturbed in Tai06-1 but not in Xiushui63, therefore, the resistance to RSV is higher in Tai06-1 than in Xiuhsui63. We found that defense genes PR1a (pathogenesis-related class 1a), PAL (phenylalanine ammonia-lyase), and CHS (chalcone synthase) may play roles in the defense responses to both RSV and SBPH in Tai06-1, and PR4 and PR10a may only participate in defending against SBPH attack but not against RSV infection in Tai06-1. Our data reveal that Gns1 (1,3; 1,4-ß-glucanase) may participate in the defense responses to both RSV and SBPH in Xiushui63 but not in Tai06-1, and LOX (lipoxygenase) may only participate in defending against to SBPH in both Tai06-1 and Xiushui63. The antioxidant enzymes superoxide dismutase, peroxidase, catalase, hydrogen peroxide, and malondialdehyde coordinately participate in the resistance to RSV in Tai06-1, and that oxidative damage is less in Tai06-1 than in Xiushui63.