Molecular characterization of the CP gene and 3'UTR of Chilli veinal mottle virus from South and Southeast Asia

Twenty-four isolates of Chilli veinal mottle virus (ChiVMV) from China, India, Indonesia, Taiwan and Thailand were analysed to determine their genetic relatedness. Pathogenicity of virus isolates was confirmed by induction of systemic mosaic and/or necrotic ringspot symptoms on Capsicum annuum after mechanical inoculation. The 3' terminal sequences of the viral genomic RNA were determined. The coat protein (CP) coding regions ranged from 858 to 864 nucleotides and the 3' untranslated regions (3'UTR) from 275 to 289 nucleotides in length. All isolates had the inverted repeat sequence GUGGNNNCCAC in the 3'UTR. The DAG motif, conserved in aphid-transmitted potyviruses, was observed in all isolates. All 24 isolates were considered as belonging to ChiVMV because of their high CP amino acid and nucleotide identity (more than 94·8 and 89·5%, respectively) with the reported ChiVMV isolates including the pepper vein banding virus (PVBV), the chilli vein-banding mottle virus (CVbMV) and the CVbMV Chiengmai isolate (CVbMV-CM1). Based on phylogenetic analysis, ChiVMV isolates including all 24 isolates tested, PVBV, CVbMV and CVbMV-CM1 can be classified into three groups. In addition, a conserved region of 204 amino acids with more than 90·2% identity was identified in the C terminal of the CP gene of ChiVMV and Pepper veinal mottle virus (PVMV), and may explain the serological cross reaction between these two viruses. The conserved region may also provide useful information for developing transgenic resistance to both ChiVMV and PVMV.     

A classification of <Emphasis Type="Italic">Pepper yellow mosaic virus</Emphasis> isolates into pathotypes

Pepper yellow mosaic virus (PepYMV) is the most important potyvirus infecting sweet pepper in Brazil. In this study, twenty isolates of PepYMV were obtained from commercial sweet pepper crops. To confirm virus identity, the coat protein gene was completely sequenced for eleven of these isolates, and partially sequenced for the other nine isolates. The amino acid identities obtained were above 93% when compared with the sequence of a characterized PepYMV isolate (AF348610). Extracts of Nicotiana tabacum cv. TNN plants infected with the different isolates were used to inoculate the differential series of Capsicum spp cultivars containing the genes pvr2 ¹ , pvr2 ² , pvr2 ³ , pvr2 ⁴ , and Pvr4. Using the same criteria established for Potato virus Y (PVY), fourteen isolates of PepYMV could be classified as known pathotypes described for PVY, that is: 1.2 (2 isolates), 1.3 (6) and 1.2.3 (6). The remaining six isolates, 1.3 (2) and 1.2.3 (4) could not be classified into the typical pathotypes of PVY because they were also virulent on Serrano Criollo de Morellos—334 (C.M 334) which carries the pvr2 ³ and Pvr4 genes. To classify the PepYMV into pathotypes and counter the biological diversity found in this species we propose the utilization of 2^x for the ability to overcome the correspondent allele of the pvr2 locus and 4 for the capacity to break down the Pvr4 gene. Using this criterion we could classify the PepYMV into five pathotypes: 2¹.2²; 2¹.2³; 2¹.2².2³; 2¹.2³. 4 and 2¹.2².2³. 4.     

Two Amino Acid Substitutions in the Coat Protein of Pepper mild mottle virus Are Responsible for Overcoming the L(4) Gene-Mediated Resistance in Capsicum spp

ABSTRACT The Capsicum spp. L genes (L(1) to L(4)) confer resistance to tobamoviruses. Currently, the L(4) gene from Capsicum chacoense is the most effective resistance gene and has been used widely in breeding programs in Japan which have developed new resistant cultivars against Pepper mild mottle virus (PMMoV). However, in 2004, mild mosaic symptoms began appearing on the leaves of commercial pepper plants in the field which possessed the L(4) resistance gene. Serological and biological assays on Capsicum spp. identified the causal virus strain as a previously unreported pathotype, P(1,2,3,4). PMMoV sequence analysis of the virus and site-directed mutagenesis using a PMMoV-J of the P(1,2) pathotype revealed that two amino acid substitutions in the coat protein, Gln to Arg at position 46 and Gly to Lys at position 85, were responsible for overcoming the L(4) resistance gene.     

Survey of viruses infecting open‐field pepper crops in Côte d'Ivoire and diversity of Pepper veinal mottle virus and Cucumber mosaic virus

The prevalence of viruses in pepper crops grown in open fields in the different agro‐ecological zones (AEZs) of Côte d'Ivoire was surveyed. Pepper veinal mottle virus (PVMV; genus Potyvirus) and Cucumber mosaic virus (CMV; genus Cucumovirus) were the most frequent viruses among those surveyed, while tobamoviruses (genus Tobamovirus) were detected at low frequency. PVMV showed a high heterogeneity across AEZs, which may be related to climatic, ecological or agronomical conditions, whereas CMV was more homogeneously distributed. The molecular diversity of CMV and PVMV were analysed from partial genome sequences. Despite the low number of CMV isolates characterized, two molecular groups were revealed, one corresponding to subgroup IA and the other to reassortants between subgroups IA and IB. RNAs 1 and 3 of the reassortants clustered with the IB subgroup of CMV isolates, whereas their RNA 2 clustered with the IA subgroup. Importantly, RNA 1 of CMV isolates of the IB subgroup has been shown to be responsible for adaptation to pepper resistance. The diversity of PVMV in the VPg‐ and coat protein‐coding regions revealed multiple clades. The central part of the VPg showed a high level of amino acid diversity and evidence of positive selection, which may be a signature of adaptation to plant recessive resistance. As a consequence, for efficient deployment of resistant pepper cultivars, it would be desirable to examine the occurrence of virulent isolates in the CMV or PVMV populations in Côte d'Ivoire and to follow their evolution as the resistance becomes more widely deployed.     

Durability of natural and transgenic resistances in rice to <Emphasis Type="Italic">Rice yellow mottle virus</Emphasis>

A monogenic recessive resistance to Rice yellow mottle virus (RYMV) found in the Oryza sativa indica cultivar Gigante and in a few Oryza glaberrima cultivars provided a higher level of resistance than either a polygenic partial resistance found in some japonica cultivars which delayed symptom expression or transgenic resistances which were partial and temporary. This high resistance was overcome by several isolates, but the percentage of such virulent isolates in the fields was low. There was no relationship between the virulence of an isolate towards the high resistance and its aggressiveness in other cultivars. Isolates with either of the two components of pathogenicity – virulence and aggressiveness – were found in each strain and in all regions of Africa, in both wild and cultivated grass species. There was no loss of fitness of resistance-breaking (RB) isolates as they were not counter-selected, impaired or outperformed after serial passages in susceptible cultivars, even in mixture with avirulent quasi-isogenic wild type isolates. Resistance breaking was highly dependent on the amount of virus inoculated and on the mode of transmission. Implications of these results for the durability of the resistances to RYMV and for the development of integrated disease management strategies are discussed.     

Emergence of Resistance-breaking Isolates of Rice yellow mottle virus during Serial Inoculations

Two sources of resistance to Rice yellow mottle virus were challenged in host passage experiments. Pronounced changes in pathogenicity occurred over serial passages of virus isolates inoculated to partially or highly resistant cultivars. The changes encompassed the known existing pathogenic variability of field isolates. Ultimately, the high resistance of the Oryza indica cv. Gigante was overcome and the partial resistance of the O. sativa japonica cv. Azucena broke down. The effect was resistance-specific as different isolates overcame partial and high resistance, and may also be allele-specific as different isolates overcame the resistance of cultivars carrying the same resistance gene. The ability of isolates to break resistance was not linked to a high initial pathogenicity of the isolates and did not result in higher virus content in the infected plants. Implications for resistance breeding and deployment are discussed.     

辣椒疫病抗性资源‘CM334’的抗性遗传分析

采用经典遗传分析方法,对来源于美国辣椒疫病抗性资源 ‘CM334’的疫病抗性遗传规律进行了研究。试验将‘CM334’与疫病高感自交系‘949’配制杂交组合,并构建杂交组合的6个世代（P1,P2,F1,F2,B1和B2）,用苗期伤根灌根接种法对其各世代群体植株进行抗性鉴定, 并进行χ2的适合性测验。结果表明: ‘CM334’的抗疫病性状遗传符合一对显性基因控制模式。     

Occurrence and distribution of viruses infecting tomato and pepper in Alibori in northern Benin

In surveys conducted in 2011 and 2012 to identify the viruses causing diseases on pepper and tomato in the department of Alibori in northern Benin, 451 samples of pepper and tomato were analyzed by ELISA using 11 specific antibodies. The highest virus incidence among the surveyed districts was recorded on pepper in Malanville (56.18%), followed by Karimama (39.32%). The most frequently found viruses were Pepper veinal mottle virus (PVMV), Cucumber mosaic virus (CMV), and Potato virus Y-necrotic (PVY-n), accounting respectively for 22.39%, 21.73% and 15.96% of the collected samples. Tomato yellow leaf curl virus (TYLCV) was detected in only 2.43% of the samples, whereas Alfalfa mosaic virus (AMV), Chilli veinal mottle virus (ChiVMV), Tomato mosaic virus (ToMV) and Tomato spotted wilt virus (TSWV) were not detected in any of the samples tested. Double and triple infections involving different virus combinations were found, respectively, in 14.86% and 4% of the samples. Five plant species (Euphorbia hirta Linnaeus, Moringa oleifera Lam, Leucas martinicencis (Jacquin) R. Brown, Combretum micranthum G. Don, Abelmoschus esculentus L. Moench.) out of 30 samples belonging to 13 botanical families, collected within or nearby tomato and pepper fields, were found infected with PVMV, PVY-n, and CMV. Control measures to reduce the impact of viruses on pepper and tomato production are discussed. This is the first report of viruses infecting pepper and tomato in Benin.     

Differentiation of pathotypes of lettuce mosaic virus

Differential interactions between six crisphead cultivars of lettuce and five isolates of lettuce mosaic virus (LMV) have identified a novel resistance factor in the cultivar Ithaca. The LMV isolates could be grouped into three pathotypes, two of which have not been identified previously. One of these, pathotype III represented by an isolate from Spain, was virulent on all of the cultivars. There were differences in aggressiveness between isolates of the same pathotype.     

The 5' Third of Cauliflower mosaic virus Gene VI Conditions Resistance Breakage in Arabidopsis Ecotype Tsu-0

ABSTRACT Arabidopsis thaliana ecotypes vary in their responses to viruses. In this study, we analyzed the variation in response of A. thaliana ecotype Tsu-0 to Cauliflower mosaic virus (CaMV). This ecotype was previously reported to be resistant to two CaMV isolates (CM1841 and CM4-184), but susceptible to W260. In this study, we show that Tsu-0 is resistant to four additional CaMV isolates. CaMV propagated within the rosette leaves of Tsu-0 plants, but did not appear to spread systemically into the inflorescence. However, virus viability in rosette leaves of Tsu-0 plants apparently was not compromised because infectious CaMV could be recovered from these organs. W260 overcomes Tsu-0 resistance by a passive mechanism (i.e., this virus avoids activating plant defenses). The portion of the viral genome responsible for W260 resistance breakage was mapped to the 5' third of gene VI, which we have termed RBR-1. This region is also responsible for controlling the ability of CaMV to infect different types of solanaceous plants. Hence, the pathways by which plants of different families interact with CaMV may be conserved through evolution.     

Symptom expression and variation of rose mosaic

Three isolates ofPrunus necrotic ringspot virus (PNRV) causing line pattern in rose and one causing yellow mosaic were compared on four greenhouse and on five outdoor rose cultivars with an isolate of the virus causing Stecklenberger disease in morello and with an isolate of apple mosaic virus (AMV) from apple. All PNRV isolates were readily transmissible through budding in rose (up to 100%). AMV was hard to transmit from apple to rose, but as easily from rose to rose as the PNRV isolates. In the greenhouse, first symptoms were produced 28 days after budding. Budding of outdoor roses in early September usually gave first symtoms next spring, but sometimes not until late during the second year after budding. In the course of time symptom production was erratic and often on a few leaves only. Nature and severity of symptoms greatly depended on cultivar and to a lesser extent on the isolate used. Symtomatologically all isolates, including AMV, behaved like members of a continuum, with AMV in certain cultivars causing characteristic rose (yellow) mosaic but usually being more virulent on rose.     

云南美人蕉病毒病病原鉴定

In this study,the causal agents were identified from Canna indica viral diseased plants in Yunnan Province.The diseased C.indica plants mainly exhibited the symptoms like veinal chlorosis and yellowing,streak mosaic or interveinal chlorosis,while older leaves always showed veinal necrosis as well as chlorosis.Viral pathogens were detected by RT-PCR/PCR in 24 diseased C.indica samples collected from Kunming and Yuxi City in Yunnan Province.The results indicated that the main C.indica-infecting viruses were canna yellow mottle virus (CaYMV),bean yellow mosaic virus (BYMV),sugarcane mosaic virus (SCMV).CaYMV showed the highest detection rate of 87.5 %,whereas,the BYMV had the lowest rate of 16.7% in the 24 samples.Co-infections of CaYMV+SCMV,CaYMV+BYMV and CaYMV+SCMV+BYMV were also detected in the diseased samples.However,cucumber mosaic virus (CMV),tobamovirus,luteovirus,orthotospovirus,begomovirus and umbravirus were not detected in these samples.This is the first report of CaYMV and SCMV infecting C.indica in Yunnan province.     

云南美人蕉病毒病病原鉴定

In this study,the causal agents were identified from Canna indica viral diseased plants in Yunnan Province.The diseased C.indica plants mainly exhibited the symptoms like veinal chlorosis and yellowing,streak mosaic or interveinal chlorosis,while older leaves always showed veinal necrosis as well as chlorosis.Viral pathogens were detected by RT-PCR/PCR in 24 diseased C.indica samples collected from Kunming and Yuxi City in Yunnan Province.The results indicated that the main C.indica-infecting viruses were canna yellow mottle virus (CaYMV),bean yellow mosaic virus (BYMV),sugarcane mosaic virus (SCMV).CaYMV showed the highest detection rate of 87.5 %,whereas,the BYMV had the lowest rate of 16.7% in the 24 samples.Co-infections of CaYMV+SCMV,CaYMV+BYMV and CaYMV+SCMV+BYMV were also detected in the diseased samples.However,cucumber mosaic virus (CMV),tobamovirus,luteovirus,orthotospovirus,begomovirus and umbravirus were not detected in these samples.This is the first report of CaYMV and SCMV infecting C.indica in Yunnan province.     

辣椒上烟草轻型绿花叶病毒的鉴定

 辣椒源自南美洲，属于茄科辣椒属（Capsicum L.），为重要经济作物。病毒病是影响辣椒生产的主要病害，侵染辣椒的病毒有40余种［1］，烟草轻型绿花叶病毒（Tobacco mild green mosaic virus, TMGMV）是近年来在辣椒上发生和危害报道较多的病毒之一。TMGMV是McKinney［2］于1935年在烟草属植物（Nicotiana gluanca）上首次发现的，为烟草花叶病毒属（Tobamovirus）成员。除辣椒外，番茄［3］、凤仙花、蓝眼菊和矮牵牛也是TMGMV的自然寄主。     

深度测序发现贵阳发生的辣椒病毒病由多种病毒复合侵染所致

2016年9月贵州省贵阳市发生严重的辣椒病毒病,症状复杂,主要表现为植株矮化,叶片黄化、花叶、皱缩、畸形以及枯死斑,果实有坏死斑等,根据症状难以判断病毒种类。本文采用小RNA深度测序技术对田间自然发病的2株辣椒标样进行了毒源鉴定,发现样品1由蚕豆萎蔫病毒2号(Broad bean wilt virus2,BBWV2)、辣椒脉斑驳病毒(Chilli veinal mottle virus,ChiVMV)、黄瓜花叶病毒(Cucumber mosaic virus,CMV)和辣椒内源RNA病毒(Bell pepper endornavirus,BPEV)4种病原复合侵染;样品2中除鉴定到上述4种病毒外,还检测到马铃薯Y病毒(Potato virusY,PVY)。进一步通过反转录PCR(RT-PCR)对深度测序结果进行了验证,证明其准确可靠。其中4个辣椒标样中均有的辣椒内源RNA病毒(BPEV)为贵州省首次报道。多种病毒复合侵染是辣椒产量和品质的重要限制因素之一,是辣椒生产的主要威胁。     

Effect of rotation of canola (Brassica napus) cultivars with different complements of blackleg resistance genes on disease severity

Blackleg disease (phoma stem canker) caused by the fungus Leptosphaeria maculans is a major disease of canola (oilseed rape, Brassica napus) worldwide. Canola plants in pots were exposed to blackleg‐infested stubble of canola with different complements of resistance genes and then assessed for disease. Plant mortality was reduced when plants were exposed to stubble from a cultivar with a different complement of resistance genes compared to stubble of a cultivar with the same resistance gene. These findings were consistent with 7 years of field surveys, which showed that changes in selection pressure as a result of extensive sowing of cultivars with major‐gene resistance, termed ‘sylvestris resistance’, dramatically influenced the frequency of virulent isolates in the population towards particular resistance genes, and therefore disease severity. All these data were supported by PCR‐genotyping surveys of fungal populations whereby the frequency of virulence alleles of avirulence genes AvrLm1 and AvrLm4 changed significantly depending on the resistance gene present in the cultivar from which the isolates were cultured. This is the first example of a study showing that sowing of canola cultivars with different complements of resistance genes in subsequent years, i.e. rotation of resistance genes, minimizes disease pressure by manipulating fungal populations. This approach provides a valuable disease management strategy for canola growers and is likely to be applicable to other plant diseases.     

Molecular Variability of the Capsid Protein of the Prune Dwarf Virus

Sequences of the capsid protein gene and the preceding intergenic region of eleven isolates of prune dwarf virus from central Europe were determined. The isolates were obtained from plum, cherry and peach trees. Comparison of all sequenced isolates (including two sequences published previously) revealed high (88%) conservation of the capsid protein gene. The highest degree of identity was observed in the C-terminal half, where only 13 amino acid substitutions could be observed in contrast to the N-terminal half with 22 substitutions. No reasonable correlation between amino acid substitutions and host species and/or geographic origin of the isolates was observed. Alignment with capsid protein genes of other ilarviruses revealed apple mosaic virus, elm mottle virus, lilac ring mottle virus and prunus necrotic ringspot virus as the most related to prune dwarf virus. Unlike the isolates of related prunus necrotic ringspot virus all the isolates of prune dwarf virus shared extensive conservation of the intergenic region. Portions of RNA3 were selected for design of universal primers for PCR detection.     

Biological and molecular characterization of a new cucurbit-infecting tobamovirus

ABSTRACT An uncharacterized virus was isolated from greenhouse-grown cucumber plants. Biological and serological data described in the present study indicated that the virus belonged in the genus Tobamovirus. The host range of the virus included several plant species within the family Cucurbitaceae. The virus designated Cucumber fruit mottle mosaic virus (CFMMV) causes severe mottling or mosaic on cucumber fruits, and its fast spread within greenhouses could lead to significant economic losses in cucumber crops. The genome of CFMMV has been completely sequenced and its genome organization was typical of a Tobamovirus. However, its sequence was distinct from other described viruses within the group of cucurbit-infecting Tobamoviruses. Comparisons of sequences and phylogenetic analysis suggested that the cucurbit-infecting Tobamoviruses be separated into two subgroups: subgroup I comprising the strains and isolates referred to in the literature as Cucumber green mottle mosaic virus (CGMMV) (CV3, CV4, CGMMV-W, CGMMV-SH, and CGMMV-Is) and subgroup II comprising CFMMV, Kyuri green mottle mosaic virus (KGMMV), and the Yodo strain of CGMMV, which is closely related to KGMMV and may be considered a strain of it.