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Leaf Curl Virus (leaf + curl_virus)
Kinds of Leaf Curl Virus Selected AbstractsGenome Organization of an Infectious Clone of Tomato Leaf Curl Virus (Philippines), a New Monopartite Begomovirus*JOURNAL OF PHYTOPATHOLOGY, Issue 11-12 2002Tatsuya Kon Abstract Complete nucleotide sequence of infectious cloned DNA of Tomato leaf curl virus from Philippines (ToLCV-Ph) was determined. The single circular DNA molecule comprises 2755 nucleotides. ToLCV-Ph DNA contains six open reading frames (ORFs) each capable of encoding proteins with a molecular weight greater than 10 kDa. A partial dimeric ToLCV-Ph DNA clone was constructed in a binary vector and used to agroinoculate tomato plants (Lycopersicon esculentum Mill. cv. Zuikou 102). Typical leaf curl symptoms were observed, showing that the single DNA component is sufficient for infectivity. In total nucleotide sequence comparisons with other geminiviruses, ToLCV-Ph was most closely related to Ageratum yellow vein virus (AYVV) (79% identity), ToLCV-Laos (78%), Soyabean crinkle leaf virus -Thailand (78%) and ToLCV-Taiwan (77%). The significant but relatively low sequence identity in the genomic DNA between ToLCV-Ph and other geminiviruses suggests that it is a distinct geminivirus in the genus Begomovirus. [source] Situation of the whiteflies Bemisia tabaci and Trialeurodes vaporariorum in protected tomato crops in Algarve (Portugal),EPPO BULLETIN, Issue 1 2002N. E. Ramos Protected tomato is the most important horticultural crop in the Algarve (south of Portugal). However, the growing area has decreased by almost 48% since 1995, mainly as a result of the pests Bemisia tabaci and Trialeurodes vaporariorum and the epidemics of Tomato yellow leaf curl virus (TYLCV), a Begomovirus transmitted by B. tabaci. Both whiteflies are vectors of economically important viruses. Recently, Tomato chlorosis virus (ToCV), a member of the genus Crinivirus, transmitted by both B. tabaci and T. vaporariorum, was reported infecting tomato crops in Algarve. A study was carried out to evaluate the dynamics of whitefly populations on tomato crops in Algarve. Population counts of B. tabaci were high in the first months of autumn, then decreased until January, when numbers of T. vaporariorum became higher. Counts of B. tabaci then increased again. [source] THE PEST STATUS OF BEMISIA TABACI IN CHINA AND NON-CHEMICAL CONTROL STRATEGIES,INSECT SCIENCE, Issue 3 2001REN Shun-xiang AbstractBemisia tabaci (Gennadius) has been considered as a serious pest in all of tropical, subtropical and temperate regions of the world. B. tabaci first recorded as early as in 1940s in China and has been reported as a pest of various crops in 22 provinces or cities. But only recently it has become a severe problem for vegetable and ornamental crops in Guangdong and Beijing. In China B. tabaci is known to transmit at least 5 plant viruses, including tomato yellow leaf curl virus (TYLCV), tomato leaf curl virus (TomLCV), squash leaf curl virus (SqLCV-C). So far, approximately 18 parasitoids, 17 predators and 1 pathogenic fungus were recorded in China. This paper presents an overview of B. tabaci as a pest and virus vector in China, with special attention given to non-chemical control strategies. [source] Molecular Characterization of two Distinct Begomoviruses from Ageratum conyzoides and Malvastrum coromandelianum in ChinaJOURNAL OF PHYTOPATHOLOGY, Issue 11-12 2006J. F. Huang Abstract Two weed samples, G52 from Ageratum conyzoides and G87 from Malvastrum coromandelianum, showing leaf curling and vein thickening symptoms were collected in Nanning, Guangxi Province, China. The complete nucleotide sequences of DNA-A-like molecules of G52 and G87 were determined to be 2735 and 2745 nucleotides respectively. Both DNA-A molecules have a genomic organization typical of begomoviruses and share 73.4% sequence identity with each other. Sequence comparisons showed that the DNA-A of G52 and G87 were most closely related to those of Ageratum yellow vein virus (AYVV; 85% sequence identity) and Tobacco leaf curl Yunnanvirus (75.7% sequence identity) respectively. Further sequence comparisons showed that G52 has arisen by recombination among viruses related to AYVV, Papaya leaf curl China virus and an unidentified Begomovirus species. The molecular data suggest that G52 and G87 are two distinct begomoviruses, for which the names Ageratum leaf curl virus for G52 and Malvastrum leaf curl virus for G87 are proposed. The satellite DNA, molecule was only found to be associated with G87. G87 DNA, consists of 1354 nucleotides, and shares the highest nucleotide sequence identity (68.9%) with that associated with Sida yellow vein China virus. A defective DNA, molecule was also found to be associated with G87. [source] Molecular Characterization of a Strain of Squash Leaf Curl China Virus from the PhilippinesJOURNAL OF PHYTOPATHOLOGY, Issue 10 2003T. Kon Abstract The complete nucleotide sequence of infectious cloned DNA components (A and B) of the causal agent of squash leaf curl disease in the Philippines was determined. DNA-A and DNA-B comprise 2739 and 2705 nucleotides, respectively; the common region is 174 bases in length. Five ORFs were found in DNA-A and two in DNA-B. Partial dimeric clones containing DNA-A and DNA-B, constructed in a binary vector and transformed into Agrobacterium tumefaciens, induced systemic infection in agro-inoculated pumpkin plants (Cucurbita moschata). The total DNA-A sequence was most closely related to that of Squash leaf curl China virus (SLCCNV) (88% identity), although the existence of B component of SLCCNV has not been reported. The deduced coat protein was like that of SLCCNV (98% amino acid sequence identity) and the Philippines virus has low sequence identity to Squash leaf curl virus (SLCV) and Squash mild leaf curl virus (SMLCV) (63 and 64% total nucleotide sequence identities, respectively). From these results, we propose that the Philippines virus be designated Squash leaf curl China virus -[Philippines] (SLCCNV-[PH]). [source] Genome Organization of an Infectious Clone of Tomato Leaf Curl Virus (Philippines), a New Monopartite Begomovirus*JOURNAL OF PHYTOPATHOLOGY, Issue 11-12 2002Tatsuya Kon Abstract Complete nucleotide sequence of infectious cloned DNA of Tomato leaf curl virus from Philippines (ToLCV-Ph) was determined. The single circular DNA molecule comprises 2755 nucleotides. ToLCV-Ph DNA contains six open reading frames (ORFs) each capable of encoding proteins with a molecular weight greater than 10 kDa. A partial dimeric ToLCV-Ph DNA clone was constructed in a binary vector and used to agroinoculate tomato plants (Lycopersicon esculentum Mill. cv. Zuikou 102). Typical leaf curl symptoms were observed, showing that the single DNA component is sufficient for infectivity. In total nucleotide sequence comparisons with other geminiviruses, ToLCV-Ph was most closely related to Ageratum yellow vein virus (AYVV) (79% identity), ToLCV-Laos (78%), Soyabean crinkle leaf virus -Thailand (78%) and ToLCV-Taiwan (77%). The significant but relatively low sequence identity in the genomic DNA between ToLCV-Ph and other geminiviruses suggests that it is a distinct geminivirus in the genus Begomovirus. [source] Tomato yellow leaf curl virus, the intracellular dynamics of a plant DNA virusMOLECULAR PLANT PATHOLOGY, Issue 1 2003Yedidya Gafni SUMMARY Tomato yellow leaf curl virus is a geminivirus, transmitted by whitefly ( Bemisia tabaci ) and causing the most destructive disease of tomato throughout the Mediterranean region, the Middle East and the tropical regions of Africa and Central America. Affected plants produce either no fruits or a few small fruits. Since it is an ssDNA virus which replicates in the host cell nucleus, the molecular mechanisms involved in the viral nuclear import have been the focus of our studies in recent years and results as well as prospects will be discussed. Taxonomy:Tomato yellow leaf curl virus (TYLCV) is a ssDNA plant virus, a member of the family Geminiviridae , of the genus Begomovirus. Physical properties: ,TYLCV, like all members of Geminiviridae, has geminate (twinned) particles, 18,20 nm in diameter, 30 nm long, apparently consisting of two incomplete T = 1 icosahedra joined together in a structure with 22 pentameric capsomers and 110 identical protein subunits (Fig. 1). Figure 1. Particles of TYLCV. Electron micrograph of purified, negatively stained TYLCV particles. Bar = 100 nm. Disease symptoms: ,Symptoms become visible in tomato in approximately 2,3 weeks after infection (Fig. 2). Leaf symptoms include chlorotic margins, small leaves that are cupped, thick and rubbery. The majority (up to 90%) of flowers abscise after infection, and therefore few fruits are produced. In Israel and elsewhere, weeds bridge the gap as potential perennial host and source of the virus between tomato growing seasons. Figure 2. Tomato yellow leaf curl symptoms on tomato plant. Leaves show yellowing on the edges accompanied by upward curling. Disease control: ,Control of TYLCV is currently based on insecticide treatments and/or physical barriers against the insect vector (Bemisia tabaci), and on tomato breeding programs based on introgression of resistance or tolerance from wild species to cultivated tomato. Useful website: , Pyramiding of genes conferring resistance to Tomato yellow leaf curl virus from different wild tomato speciesPLANT BREEDING, Issue 6 2008F. Vidavski Abstract Tomato (Solanum lycopersicum) production in tropical and subtropical regions of the world is limited by the endemic presence of Tomato yellow leaf curl virus (TYLCV). Breeding programmes aimed at producing TYLCV-resistant tomato cultivars have utilized resistance sources derived from wild tomato species. So far, all reported breeding programmes have introgressed TYLCV resistance from a single wild tomato source. Here, we tested the hypothesis that pyramiding resistances from different wild tomato species might improve the degree of resistance of the domesticated tomato to TYLCV. We have crossed TYLCV-resistant lines that originated from different wild tomato progenitors, Solanum chilense, Solanum peruvianum, Solanum pimpinellifolium, and Solanum habrochaites. The various parental resistant lines and the F1 hybrids were inoculated in the greenhouse using viruliferous whiteflies. Control, non-inoculated plants of the same lines and hybrids were exposed to non-viruliferous whiteflies. Following inoculation, the plants were scored for disease symptom severity, and transplanted to the field. Resistance was assayed by comparing yield of inoculated plants to those of the control non-inoculated plants of the same variety. Results showed that the F1 hybrids between the resistant lines and the susceptible line suffered major yield reduction because of infection, but all hybrids were more resistant than the susceptible parent. All F1 hybrids resulting from a cross between two resistant parents, showed a relatively high level of resistance, which in most cases was similar to that displayed by the more resistant parent. In some cases, the hybrids displayed better levels of resistance than both parents, but the differences were not statistically significant. The F1 hybrid between a line with resistance from S. habrochaites and a line with resistance from S. peruvianum (HAB and 72-PER), exhibited the lowest yield loss and the mildest level of symptoms. Although the resistance level of this F1 hybrid was not statistically different from the level of resistance displayed by the 72-PER parent itself, it was statistically better than the level of resistance displayed by the F1 hybrids between 72-PER and any other resistant or susceptible line. [source] Tomato leaf curl geminivirus in Australia: occurrence, detection, sequence diversity and host rangePLANT PATHOLOGY, Issue 3 2003J. Stonor The occurrence of whitefly transmitted geminiviruses in Australia was studied using a mixed DNA probe capable of detecting a range of distinct geminiviruses. The only geminivirus species detected was Tomato leaf curl virus (TLCV), which is spread across a vast geographical region of far-northern coastal Australia, an area inhabited by the Australasian-Oceania biotype of Bemisia tabaci. The newly introduced silverleaf whitefly, B. tabaci biotype B, forms high population densities in the eastern coastal region of Queensland and is currently located approximately 150 km from the nearest known TLCV-infected area. The viral host range appeared to be narrow and of 58 species of crop plants and weeds inoculated using the B biotype, only 11 became infected with the virus, including five that did not show foliar symptoms. A DNA fragment of 694 nt, including the complete C4 open reading frame (ORF), the overlapping N-terminal part of the C1 ORF and the viral iterons involved in replication, was amplified from 11 TLCV field isolates and sequenced. Sequence analysis revealed an overall sequence variation of up to 14% in this region, as well as the presence of distinct viral iterons. [source] Low frequency of horizontal and vertical transmission of two begomoviruses through whiteflies exhibits little relevance to the vector infectivityANNALS OF APPLIED BIOLOGY, Issue 1 2010J. Wang Transmissions of plant viruses between individuals of their vector insects through mating are rare events. Recently, three begomoviruses were found to be transmitted between males and females of the whitefly Bemisia tabaci through mating, and two viruses were shown to be transmitted transovarially to progeny. However, results between reports were not consistent. Here we examined the horizontal and vertical transmission of Tomato yellow leaf curl virus (TYLCV) and Tomato yellow leaf curl China virus (TYLCCNV) by the B and Q biotypes of B. tabaci, using virus isolates and whitefly colonies established recently in China. Both TYLCV DNA and TYLCCNV DNA were shown to be transmitted horizontally and vertically by each of the two biotypes of the whitefly, but frequency of transmission was usually low. In transovarial transmission, virus DNA was detected in eggs and nymphs but not in the adults of the first generation progeny, except in the combination of TYLCV and Q biotype whitefly where 2,3% of the offspring adults contained the virus DNA. We also showed that the first generation adults, which developed from eggs of viruliferous whiteflies, were not infective to plants. These results demonstrated that for the viruses and whiteflies tested here low frequency of horizontal and vertical transmission can be expected but these two modes of transmission are unlikely to have much epidemiological relevance in the field. [source] Differential indirect effects of two plant viruses on an invasive and an indigenous whitefly vector: implications for competitive displacementANNALS OF APPLIED BIOLOGY, Issue 3 2009J. Liu Abstract The role of vector,begomovirus,plant interactions in the widespread invasion by some members of the whitefly species complex Bemisia tabaci is poorly understood. The invasive B biotype of B. tabaci entered China in the late 1990s and had become the predominant or only biotype of the whitefly in many regions of the country by 2005,2006. Meanwhile epidemics of begomoviruses have been observed in many crops including tomato for which Tomato yellow leaf curl China virus (TYLCCNV) and Tomato yellow leaf curl virus (TYLCV) have been identified as two major disease-causing agents. Here, we conducted laboratory experiments to compare the performance of the invasive B and indigenous ZHJ1 whitefly biotypes on uninfected, TYLCCNV-infected and TYLCV-infected plants of tomato cv. Hezuo903, a cultivar that has been widely cultivated in many regions of China. The infection of tomato plants by either of the viruses had no or only marginal effects on the development, survival and fecundity of the B biotype. In contrast, survival and fecundity of the ZHJ1 biotype were significantly reduced on virus-infected plants compared to those on uninfected plants. Populations of the B biotype on uninfected and TYLCCNV-infected plants increased at similar rates, whereas population increase of the ZHJ1 biotype on TYLCCNV-infected plants was affected adversely. These asymmetric responses to virus infection of tomato plants between the B and ZHJ1 biotypes are likely to offer advantages to the B biotype in its invasion and displacement of the indigenous biotype. [source] The circulative pathway of begomoviruses in the whitefly vector Bemisia tabaci, insights from studies with Tomato yellow leaf curl virusANNALS OF APPLIED BIOLOGY, Issue 3 2002HENRYK CZOSNEK Summary Our current knowledge concerning the transmission of begomoviruses by the whitefly vector Bemisia tabaci is based mainly on research performed on the Tomato yellow leaf curl virus (TYLCV) complex and on a number of viruses originating from the Old World, such as Tomato leaf curl virus, and from the New World, including Abutilon mosaic virus, Tomato mottle virus, and Squash leaf curl virus. In this review we discuss the characteristics of acquisition, transmission and retention of begomoviruses by the whitefly vector, concentrating on the TYLCV complex, based on both published and recent unpublished data. We describe the cells and organs encountered by begomoviruses in B. tabaci. We show immunolocalisation of TYLCV to the B. tabaci stylet food canal and to the proximal part of the descending midgut, and TYLCV-specific labelling was also associated with food in the lumen. The microvilli and electron-dense material in the epithelial cells of the gut wall were also labelled by the anti TYLCV serum, pointing to a possible virus translocation route through the gut wall and to a putative site of long-term virus storage. We describe the path of begomoviruses in their vector B. tabaci and in the non-vector whitefly Trialeurodes vaporariorum, and we follow the rate of virus translocation in these insects. We discuss TYLCV transmission between B. tabaci during mating, probably by exchange of haemolymph. We show that following a short acquisition access to infected tomato plants, TYLCV remains associated with the B. tabaci vector for weeks, while the virus is undetectable after a few hours in the non-vector T. vaporariorum. The implications of the long-term association of TYLCV with B. tabaci in the light of interactions of the begomovirus with insect receptors are discussed. [source] |