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Spot Virus (spot + virus)
Kinds of Spot Virus Selected AbstractsViruses of pome fruit trees in SyriaEPPO BULLETIN, Issue 1 2006F. Ismaeil A survey was conducted to evaluate the sanitary status of pome fruit trees in Syria during spring 2003 and 2004 in 6 governorates: Damascus, Al-Qunaitara and Al-Sweida (Southern region), Homs and Hama (Central region) and Latakia (Costal Western region), as the main production areas of pome fruits. Leaf samples from 1077 apples, 54 pears and 14 quince were collected and tested for the presence of Apple chlorotic leaf spot virus (ACLSV), Apple stem grooving virus (ASGV) and Apple mosaic virus (ApMV) in 70 commercial orchards and 3 varietal collections by ELISA. Results showed that the virus infection rates were 34 and 2% in apple and pear, respectively. Quince trees were found to be virus tested free. ACLSV was prevailing on apple with 34%, whereas ASGV and ApMV were found in 2 and 0.2% of tested trees, respectively. Pear trees were infected only with ACLSV (2%). 21 apples and 15 pears representative budwood samples were indexed by grafting on the following indicators: (i) Malus pumila cvs. Virginia Crab and Radiant for apple and (ii) M. pumila cv. V. Crab and Pyrus communis cv. Nouveau Poiteau for pear. The virus infection rates by woody indexing were much higher than ELISA, Apple stem pitting virus (ASPV) and ASGV were found in 86 and 82% of apple tested samples, whereas they were 80 and 60% of pear tested samples, respectively. Additional RT-PCR testing carried out for a limited number of samples confirmed the high incidence of ACLSV ASPV, ASGV and the presence of ApMV. This is the first report on pome fruit viruses in Syria, indicating an unsatisfactory sanitary status of the industry. As a consequence, a certification program is recommended for producing locally healthy propagating material. [source] Biology of the European large raspberry aphid (Amphorophora idaei): its role in virus transmission and resistance breakdown in red raspberryAGRICULTURAL AND FOREST ENTOMOLOGY, Issue 1 2009Lindsay S. McMenemy Abstract 1,The European large raspberry aphid Amphorophora idaei Börner is the most important vector of viral diseases afflicting commercially grown red raspberry (Rubus idaeus L.) in Northern Europe, with European raspberry production amounting to 416 000 tonnes per annum. This review synthesizes existing knowledge on its biology and interactions with other organisms, including its host plant and the viral pathogens it vectors. 2,Information about trophic interactions with other insect herbivores and natural enemies is reviewed. Vine weevils Otiorhynchus sulcatus compromise aphid resistance in some raspberry cultivars, increasing A. idaei abundance by 80%. Parasitoids show mixed success in parasitizing A. idaei, although Aphidius ervi attack rates more than doubled when A. idaei fed on a partially susceptible raspberry cultivar, compared with a resistant variety. These findings are discussed in the context of potential biological control as part of an integrated pest and disease management framework. 3,Amphorophora idaei transmits four known viruses: Black raspberry necrosis virus, Raspberry leaf mottle virus, Raspberry leaf spot virus and Rubus yellow net virus, with A. idaei taking as little as 2 min to transmit some viruses. 4,Existing control strategies, including resistant cultivars, insecticides and eradication of disease from parent plants, are described. In particular, strong selection pressures have resulted in A. idaei overcoming genetic resistance in many raspberry cultivars and most insecticides are now ineffective. 5,Future directions for the sustained control of A. idaei are suggested, taking into consideration the possible effects of climate change and also changes in agronomic practices in U.K. agriculture. [source] An effective system for detecting Iris yellow spot virus transmission by Thrips tabaciPLANT PATHOLOGY, Issue 3 2010T. Inoue A simple, effective and convenient laboratory leaf system was developed to detect transmission of Iris yellow spot virus (IYSV) by thrips. It was shown that IYSV was transmitted highly efficiently by adults and also by larvae of five thelytokous populations of Thripstabaci from distinct areas in Japan: over all these populations, transmission efficiency of adults ranged from 20·4% (19/93) to 41·1% (76/185) and that of larvae from 17·3% (14/81) to 44·1% (67/152). Finally, it was demonstrated that IYSV infection was not detrimental to the development and fecundity of thrips until early adulthood. Larval mortalities of virus-exposed thrips were higher than in their unexposed counterparts in all three populations, but the differences were not significant. The results demonstrated that T. tabaci populations have considerable potential to cause outbreaks of IYSV and spread the disease because of their efficient transmission of the virus. [source] Characterization of Passionfruit severe leaf distortion virus, a novel begomovirus infecting passionfruit in Brazil, reveals a close relationship with tomato-infecting begomovirusesPLANT PATHOLOGY, Issue 2 2010S. S. Ferreira Molecular and biological characterization of the begomovirus isolate BR:LNS2:Pas:01, obtained from yellow passionfruit plants in Livramento de Nossa Senhora, Bahia state, Brazil, was carried out. Sequence analysis demonstrated that the BR:LNS2:Pas:01 DNA-A had highest nucleotide sequence identity with Tomato chlorotic mottle virus (77%) and had five ORFs corresponding to the genes cp, rep, trap, ren and ac4. The DNA-B had highest nucleotide sequence identity with Tomato yellow spot virus (74%) and two ORFs corresponding to the genes mp and nsp. These identity values indicate that this isolate represents a new begomovirus species, for which the name Passionfruit severe leaf distortion virus (PSLDV), is proposed. Phylogenetic analysis clustered the PSLDV DNA-A and -B in a monophyletic branch with Brazilian tomato-infecting begomoviruses. The isolate's host range was restricted to species from the Passifloraceae and Solanaceae. PSLDV-[BR:LNS2:Pas:01] was capable of forming pseudorecombinants with tomato-infecting begomoviruses, reinforcing its close relationship with these viruses and suggesting a possible common origin. However, the virus was not capable of infecting tomato. [source] First report of Melon necrotic spot virus on melon in TunisiaPLANT PATHOLOGY, Issue 2 2008S. Yakoubi No abstract is available for this article. [source] New severe strains of Melon necrotic spot virus: symptomatology and sequencingPLANT PATHOLOGY, Issue 5 2005C. Kubo New strains of Melon necrotic spot virus (MNSV), designated MNSV-YS and MNSV-KS, caused much more severe growth retardation on melon plants than MNSV-NH, which was previously reported as the most severe strain of MNSV in Japan. MNSV-YS spread much more quickly than MNSV-NH in infected plants, and induced more severe growth retardation, even though the appearance of necrotic lesions on inoculated cotyledons was much slower. MNSV-KS had properties intermediate between those of the other two strains. The results suggest that faster-spreading strains can multiply more rapidly as a result of lower levels of activity in inducing necrotic lesions in melon plants. The complete sequences of MNSV-YS and MNSV-KS were determined, and an RT,PCR,RFLP method based on these sequences was successfully developed to detect and discriminate between the three strains. [source] The competence of four thrips species to transmit and replicate four tospovirusesPLANT PATHOLOGY, Issue 2 2004T. Nagata The tospoviruses Tomato spotted wilt virus (TSWV), Tomato chlorotic spot virus (TCSV), Groundnut ringspot virus (GRSV) and Chrysanthemum stem necrosis virus (CSNV) are well-known pathogens on tomato in Brazil. The thrips species Frankliniella occidentalis, F. schultzei, Thrips tabaci and T. palmi were studied for their competence to transmit these tospoviruses. Frankliniella occidentalis transmitted all four tospoviruses with different efficiencies. Frankliniella schultzei transmitted TCSV, GRSV and CSNV. Although F. schultzei has been reported as a vector of TSWV, the F. schultzei population in the present study did not transmit the TSWV isolate used. A population of T. tabaci known to transmit Iris yellow spot virus (onion isolate) did not transmit any of the studied tospoviruses, and nor did T. palmi. Replication of these tospoviruses could be demonstrated by ELISA, not only in the thrips species that could transmit them, but also in those that could not. The results strongly suggest that competence to transmit is regulated not only by the initial amount of virus acquired and replication, but also by possible barriers to virus circulation inside the thrip's body. [source] Identification of Dictyothrips betae as the vector of Polygonum ring spot virusANNALS OF APPLIED BIOLOGY, Issue 2 2010M. Ciuffo Dictyothrips betae (Thysanoptera: Thripidae) is the predominant thrips species on Polygonum convolvulus and Polygonum dumetorum plants infected with a recently described tospovirus species, Polygonum ring spot virus (PolRSV). Laboratory transmission experiments (leaf disk assays) with adults collected directly in the field demonstrated the competence of this thrips to transmit PolRSV, although only at a rate of 4%. However, this increased to 16% using newly emerged larvae fed on infected leaves. Frankliniella occidentalis and Thrips tabaci failed to transmit PolRSV in leaf disk assays. Reverse transcription-polymerase chain reaction (RT-PCR) with specific primers for the N protein and Western blot analysis of adult thrips to detect the N protein confirmed the presence of the virus in D. betae individuals after feeding for at least 5 days on healthy plants. For molecular identification purposes partial sequences of mitochondrial cytochrome c oxidase subunit I (COI), nuclear 28S ribosomal DNA and the elongation factor-1, (EF-1,) from D. betae were cloned. COI sequence was also used for deriving a phylogenetic tree, including D. betae. The results confirmed a relationship between this species and tospovirus-transmitting insects of the genus Thrips. [source] Sequence similarities between Raspberry leaf mottle virus, Raspberry leaf spot virus and the closterovirus Raspberry mottle virusANNALS OF APPLIED BIOLOGY, Issue 3 2010W.J. McGavin A sequencing study was performed to determine the relationship between Raspberry mottle virus (RMoV), a newly identified tentative closterovirus found in the United States, and Raspberry leaf mottle virus (RLMV) and Raspberry leaf spot virus (RLSV), which have been known for many years to be components of Raspberry mosaic disease (RMD) in the UK and Europe but which have not been characterised at the molecular level. Cloning and sequencing of cDNAs amplified by reverse transcription-PCR revealed the presence of closteroviruses with high sequence similarity to RMoV in infected plants from the SCRI Rubus virus collection, as well as in a number of samples collected from RMD-symptomatic raspberry plants located at different farms in Scotland and England. These results suggest that RMoV, RLMV and RLSV are isolates of the same virus and we propose that they all should be referred to as RLMV, which was the first of these viruses to be described. Many of the field samples were also infected with a second closterovirus isolate, parts of which could be amplified using RLMV-derived primers. The coat protein amino acid sequences of RLMV and the second virus (PM1) were only 78% identical, even though helicase domain and RNA-dependent RNA polymerase (RDRP) domain sequences were more than 97% identical between RLMV and PM1. [source] | ||||||||||