Genome editing of indica rice ASD16 for imparting resistance against rice tungro disease

Journal of Plant Biochemistry and Biotechnology - Rice tungro disease (RTD) is caused by the joint infection of rice tungro bacilliform virus and rice tungro spherical virus (RTSV) and is the most...     

The Differential Reaction of Rice Hybrids to Tungro Virus by Phenotyping and PCR Analysis

Twenty popular rice hybrids were used to screen for rice tungro virus (RTV) disease reaction. Virulent green leafhoppers (GLH) were used as vector to introduce RTV to the rice hybrids. Virus symptoms scores were recorded at 14, 21, 34, 41 and 59 days postinoculation (DPI), which suggested that virus symptoms are greatly influenced by growth stage of plants. To confirm the presence of virus, polymerase chain reaction (PCR)‐based detection of Rice tungro bacilliform virus (RTBV) was carried out at 7, 14, 21 and 59 DPI using virus genome‐specific primers. Virus presence was observed in all the rice hybrids and check varieties, particularly at later stages of infection. This study shows that phenotyping for tungro virus resistance in rice hybrids at 21 DPI gives most reliable results based on both virus symptoms and presence of virus. Further, to assess the relative difference in population of RTBV, quantitative PCR was performed in all the genotypes at 21 DPI. Yield data were also recorded from control and virus‐infected plants to estimate yield loss percentage due to tungro disease. This study is important to understand the response of rice hybrids to tungro virus disease. Results obtained in this study emphasize that molecular detection of virus is very important to screen the rice plants accurately for tungro disease reaction.     

Transformation of rice plants by plant reovirus genes

Rice dwarf phytoreovirus (RDV), and rice ragged stunt oryzairus (RRSV) genes were introduced into rice protoplasts by using the cauliflower mosaic virus 35S promoter, tissue culture techniques and electroporation. The translation products of cDNA to RDV segment 8 were detected in transformed rice. Plants transgenic for RRSV S9 also expressed an mRNA of appropriate size but the protein was not apparently expressed. These latter plants did not show any resistance when inoculated with RRSV; on the contrary, symptom expression was intensified. Since most plant reoviruses are phloem-limited, an alternative promoter could be that of rice tungro bacilliform virus (RTBV), which is itself phloem-limited. When the β-glucuronidase (GUS) gene was coupled to this promoter and introduced into rice, GUS activity was successfully expressed only in the phloem, so the system could be of interest in the reovirus context.     

Comparative transmission of, and varietal reaction to, three isolates of rice tungro virus disease

Comparative transmission by leafhoppers of three tungro isolates obtained from the Philippines, India and Malaysia, and of an infectious clone of the Philippine isolate of rice tungro bacilliform virus (RTBV) by agroinoculation, was conducted on 12 rice cultivars. The symptoms, including height of inoculated plants were recorded and the efficiency of RTBV and rice tungro spherical virus (RTSV) transmission was determined by enzyme-linked immunosorbent assay. In most cases, the reduction of height and leaf symptoms of plants infected with RTBV and/or RTSV by the three isolates were similar in any given cultivar. On cultivar ASD 7 , the Malaysian isolate showed more severe yellow orange leaf discolouration symptoms than the Indian isolate which in turn had more severe leaf discolouration than the Philippine isolate. On the other hand, cultivars ASD 7 and Ptb 18 produced the most severe yellow orange leaf discolouration when agroinoculated with an infectious RTBV clone of the Philippine isolate. There was some variation in the transmission profile of the two tungro viruses among the three isolates. However, there was no one clear set of characteristics by which one could use cultivars to distinguish isolates. The amount of viral DNA in agroinfected plants of cultivars Utri merah, Balimau putih, Utri Rajapan and ARC 11554 was low, while the amount was high in cultivars TN1, ASD7, Ptb 18 and TKM 6. There was high correlation between the amount of viral coat protein by ELISA and viral nucleic acid by DNA hybridisation on 10 agroinoculated rice cultivars; this might indicate that similar proportions of the total RTBV DNA are encapsidated in each cultivar.     

Development of PCR-based allele-specific and InDel marker sets for nine rice blast resistance genes

Blast resistance is one of the most important traits in rice breeding, and application of molecular markers for blast resistance breeding is likely to allow the rapid screening for the trait during early growth stages, without the need for inoculation of pathogen and phenotyping. Allele-specific PCR markers and insertion/deletion (InDel) markers, which genotype single-nucleotide polymorphisms and InDel polymorphisms, respectively, are useful tools for marker-assisted selections. We developed sets of allele-specific PCR and InDel markers for nine rice blast resistance genes—Piz, Piz-t, Pit, Pik, Pik-m, Pik-p, Pita, Pita-2, and Pib—which are commonly used in Japanese blast resistance rice breeding programs. For each resistance gene, we used the segregation information from thousands of progeny in several crosses or published gene locations to generate a marker that cosegregated with the gene and markers that closely flanked the gene on either side. The developed cosegregating markers uniquely discriminated among each of the lines with the individual resistance genes (except for Pita and Pita-2). Therefore, these markers will likely facilitate the development of multiline cultivars carrying one or a combination of these nine blast resistance genes. In addition, the systems we developed may be valuable tools in the quality control of seed production from blast-resistant multiline cultivars.     

Some biological and genomic properties of rice tungro bacilliform badnavirus and rice tungro spherical waikavirus from Nepal

A survey of rice fields during the main growing seasons in 81 locations from 21 districts of the Southern Terai region of Nepal indicated that rice tungro was primarily restricted to the Hardinath (Janakpur) and Parwanipur (Bara) regions. The tungro incidence in Hardinath ranged from 17% to 51% and in Parwanipur from 6% to 61% causing about 89% grain yield loss in Hardinath. Both rice tungro bacilliform badnavirus (RTBV) and rice tungro spherical picornavirus (RTSV) were found in tungro isolates collected from Hardinath and Parwanipur. These isolates were transmitted by Nephotettix virescens and leaf extracts reacted to antisera against RTBV and RTSV. In a dot blot hybridisation assay, leaf extracts of 12 weed species collected from the tungro-affected area in Hardinath and Parwanipur also reacted with RTBV DNA probes. On mass inoculation of 15 popular rice cultivars most became more than 50% infected and only cv. Radha 9 had low (22.2%) infection. RTBV DNA and the coat protein region of RTSV from the Hardinath isolate were cloned and partially characterised. A comparative analyses by restriction endonuclease digestion, cross hybridisation, the polymerase chain reaction and partial sequencing indicated that the Nepalese RTBV DNA clone and the cDNA clones of the RTSV RNA were more similar to the various tungro isolates from the Indian subcontinent than to those from the Philippines.     

Variation of Rice Tungro Viruses: Further Evidence of Two Rice Tungro Bacilliform Virus Strains and Possibly Several Rice Tungro Spherical Virus Variants

Rice tungro disease is caused by two viruses: rice tungro spherical virus (RTSV) and rice tungro bacilhform virus (RTBV). Our results obtained using polymerase chain reaction (for RTBV) and western blot analysis (for RTSV) to study the epidemiology of tungro supported earlier studies that two RTBV strains. South East Asian and Indian, can be differentiated and also better defined the geographic distribution of these two strains.
Data on RTSV variation were not so conclusive and consistent as those on RTBV because of the high degree of microvariation of RNA genomes. Our approach for differentiation of RTSV led to three variants being identified, the geographic distribution of which does not correlate with that found for strains of RTBV.     

Reconstruction of putative DNA virus from endogenous rice tungro bacilliform virus-like sequences in the rice genome: implications for integration and evolution

Background  

Plant genomes contain various kinds of repetitive sequences such as transposable elements, microsatellites, tandem repeats and virus-like sequences. Most of them, with the exception of virus-like sequences, do not allow us to trace their origins nor to follow the process of their integration into the host genome. Recent discoveries of virus-like sequences in plant genomes led us to set the objective of elucidating the origin of the repetitive sequences. Endogenous rice tungro bacilliform virus (RTBV)-like sequences (ERTBVs) have been found throughout the rice genome. Here, we reconstructed putative virus structures from RTBV-like sequences in the rice genome and characterized to understand evolutionary implication, integration manner and involvements of endogenous virus segments in the corresponding disease response.     

A novel approach for developing resistance in rice against phloem limited viruses by antagonizing the phloem feeding hemipteran vectors

Rice production is known to be severely affected by virus transmitting rice pests, brown planthopper (BPH) and green leafhopper (GLH) of the order hemiptera, feeding by phloem abstraction. ASAL, a novel lectin from leaves of garlic (Allium sativum) was previously demonstrated to be toxic towards hemipteran pests when administered in artificial diet as well as in ASAL expressing transgenic plants. In this report ASAL was targeted under the control of phloem-specific Agrobacterium rolC and rice sucrose synthase-1 (RSs1) promoters at the insect feeding site into popular rice cultivar, susceptible to hemipteran pests. PCR, Southern blot and C-PRINS analyses of transgenic plants have confirmed stable T-DNA integration and the transgenes were co-segregated among self-fertilized progenies. The T₀ and T₁ plants, harbouring single copy of intact T-DNA expression cassette, exhibit stable expression of ASAL in northern and western blot analyses. ELISA showed that the level of expressed ASAL was as high as 1.01% of total soluble protein. Immunohistofluorescence localization of ASAL depicted the expected expression patterns regulated by each promoter type. In-planta bioassay studies revealed that transgenic ASAL adversely affect survival, growth and population of BPH and GLH. GLH resistant T₁ plants were further evaluated for the incidence of tungro disease, caused by co-infection of GLH vectored Rice tungro bacilliform virus (RTBV) and Rice tungro spherical virus (RTSV), which appeared to be dramatically reduced. The result presented here is the first report of such GLH mediated resistance to infection by RTBV/RTSV in ASAL expressing transgenic rice plant.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

Physiology of rice tungro virus disease: Proline accumulation due to infection

Tungro virus infection stimulates proline accumulation in leaves of rice ( Oryza sativa L.), especially in a sensitive cultivar, Taichung Native 1. Disease-induced proline accumulation increases with the severity of the disease. Proline also accumulates in senescing, detached healthy rice leaves. The magnitude of proline accumulation in these leaves was further accentuated by ABA and retarded by kinetin. In the absence of drought stress, virus infection induces severe symptoms (stunting) in a drought tolerant cultivar (Lalnakanda 41) when compared to cultivars with intermediate (MW 10) and high sensitivity (Cauvery) to drought. Thus tungro virus mimics water stress in inducing proline accumulation in rice leaves. In both cases a common factor, ABA, may mediate proline accumulation. In drought stress, proline accumulation is associated with tolerance, while in virus stress, proline accumulation is connected with sensitivity. It is, therefore, clear that proline cannot always act to relieve physiological stress.     

Responses and adaptation by Nephotettix virescens to monogenic and pyramided rice lines with Grh‐resistance genes

The green leafhopper, Nephotettix virescens (Distant) (Hemiptera: Cicadellidae), occasionally damages rice in Asia either directly, by feeding on the host phloem, or indirectly by transmitting tungro virus. We assessed the nature of resistance against the leafhopper in monogenic and pyramided near‐isogenic rice lines containing the resistance genes Grh2 and Grh4. Only the pyramided line was resistant to leafhopper damage. Leafhopper nymphs and adults had high mortality and low weight gain when feeding on the pyramided line and adults laid few eggs. In contrast, although there was some minor resistance in 45‐day‐old plants that possessed either Grh2 or Grh4 genes, the monogenic lines were generally as susceptible to the leafhopper as the recurrent parent line Taichung65 (T65). Resistance in the pyramided line was stable as the plant aged and under high nitrogen, and affected each of five Philippine leafhopper populations equally. Furthermore, in a selection study, leafhoppers failed to adapt fully to the pyramided resistant line: nymph and adult survival did improve during the first five generations of selection and attained similar levels as on T65, but egg‐laying failed to improve over 10 generations. Our preliminary results suggested that resistance was associated with physiological costs to the plants in some experiments. The results of this study demonstrate the success of pyramiding resistance genes through marker‐assisted breeding, to achieve a strong and potentially durable resistance. We discuss the utility of gene pyramiding and the development of near‐isogenic lines for leafhopper management.     

辽宁地区水稻资源抗稻瘟病基因的检测分析

为了明确辽宁地区水稻资源中抗稻瘟病基因的分布情况及抗病效应,选取辽宁地区水稻资源176份,鉴定了抗稻瘟病基因pi21、Pi36、Pi37、Pita、Pid2、Pid3、Pi5及Pib在这些材料中的分布情况,并接种鉴定了这些材料对稻瘟病的抗性。结果表明:176份供试材料中,83份对稻瘟病表现抗病,栽培稻、杂草稻及农家种中抗病品种所占的比率分别为41.48%、1.14%及4.54%。抗稻瘟病基因pi21、Pi36和Pi37在所有参试材料中均未检测到,且分别有74份、49份、47份、52份及89份材料携带Pita、Pid2、Pid3、Pi5及Pib的抗病等位基因。抗病基因绝大部分分布在栽培种中,农家种和杂草稻中分布较少。不含有抗稻瘟病基因和只携带单个抗病基因的材料对稻瘟病的抗性均较差,而抗病基因聚合可不同程度提高材料的抗性。经检测,不含有本试验鉴定的pi21等8个已克隆抗病基因的材料共32份,其中表现抗病的占21.87%;只携带1个抗稻瘟病基因的材料为52份,表现抗病的占17.31%;携带2个抗稻瘟病基因的材料为39份,表现抗病的占69.23%,其中以携带Pita+Pi5的材料最多(14份),且均表现抗病;携带3个抗稻瘟病基因的材料为31份,表现抗病的占77.42%,以携带Pita+Pid3+Pi5的材料抗性最强;携带4个抗稻瘟病基因的水稻材料22份,表现抗病的占72.73%,携带5个抗病基因的水稻材料未检测到。     

QTL analysis of resistance to the rice blast pathogen in barley (Hordeum vulgare)

Barley is compatible with the rice blast pathogen (Pyricularia oryzae Cav.). Fiftyfour barley cultivars of diverse geographic origin and pedigree were inoculated with three isolates of the rice blast pathogen. All barley genotypes showed blast disease symptoms when inoculated at the seedling stage with each of the three isolates. However, one genotype showed quantitative resistance to all three isolates and three genotypes showed quantitative resistance to one or two of the isolates. By inoculating a set of doubled-haploid lines derived from the cross ’Harrington’ (susceptible) and ’TR306’ (resistant) with isolate Ken 54–20, we mapped quantitative trait loci (QTLs) determining seedling stage blast resistance. At all QTLs, TR306 contributed the resistance alleles. The four QTLs, when considered jointly, explained 43.6% of the phenotypic variation in blast symptom expression. A comparison of the blast resistance QTLs with other disease resistance QTLs reported in this population revealed a region on chromosome 4 (4H) with multiple disease resistance loci. It will be useful to capitalize on the syntenic relationship of rice and barley and to integrate information on species-specific resistance genes with information on the reaction of the two species to the same pathogen. Received: 7 January 2000 / Accepted: 22 September 2000     

Tethered flight activity of Nephotettix virescens (Hemiptera: cicadellidae) in the Philippines

The flight potential of Nephotettix virescens (Distant), the most important vector of rice tungro virus disease, was assessed using tethered flight techniques. Most individuals tested were not willing to fly in response to stimulation, or flew for very short times. A small proportion of leafhoppers flew for long periods and one female flew for almost 7 h, indicating the potential for long distance dispersal of insects and inoculum. Few individuals flew before four days of age and thereafter flight profiles were similar for insects aged between four and 12 days. Mature females were more flight willing when kept as adults in mixed groups with males than when caged separately. There was no consistent effect on flight performance when insects were reared on rice varieties with different levels of leafhopper resistance. The flight activity of N. virescens was greater when leafhoppers were reared on mature, compared with young, rice plants. Leafhoppers reared through one generation on tungro-diseased rice plants were less willing to fly than individuals maintained on healthy plants of the same age and variety, whereas those tested after a 24-h access period to tungro-diseased plants were more flight-willing. The results are discussed in relation to the spread of tungro and to management interventions for the control of the disease.