Impact of Raspberry Bushy Dwarf Virus, Raspberry Leaf Mottle Virus, and Raspberry Latent Virus on Plant Growth and Fruit Crumbliness in Red Raspberry (Rubus Idaeus L.) 'Meeker' PDF Download
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Author: Diego F. Quito-Avila Publisher: ISBN: Category : Closteroviruses Languages : en Pages : 138
Book Description
The United States is the third-largest producer of raspberries in the world. Washington State leads the nation in red raspberry (Rubus idaeus L.) production. 'Meeker', the most grown red raspberry cultivar in the Pacific Northwest (Washington, Oregon and British Columbia, Canada) is highly susceptible to Raspberry crumbly fruit, a virusinduced disease that produces drupelet abortion and reduces fruit quality and yield. The disease has long been attributed to Raspberry bushy dwarf virus (RBDV), a pollen-and-seed transmitted virus found in most commercial raspberry fields around the world. In recent years, an increased severity of crumbly fruit was observed in areas where two additional viruses were common. One of these viruses, Raspberry leaf mottle virus (RLMV), was characterized recently and shown to be a novel closterovirus transmitted by the large raspberry aphid Amphorophora agathonica Hottes. The second virus, Raspberry latent virus (RpLV) was a tentative member of the family Reoviridae whose characterization remained to be completed. To investigate the role of these two new viruses in the crumbly fruit disorder, 'Meeker' raspberry infected with single or mixtures of the three viruses, in all possible combinations, were generated by graft inoculation. Eight treatments, including a virus free control, were planted in the field at the Northwestern Research and Extension Center in Mt. Vernon, WA. Plant growth and fruit crumbliness were evaluated during establishment and the second year. Simultaneously, the characterization of RpLV, at the genetic and biological level, was completed. RpLV is a novel member of the plant Reoviridae composed of 26,128 nucleotides divided into 10 genomic dsRNA segments. Analysis of the RNA dependent RNA polymerase (RdRP) indicated that RpLV was related most closely to members of the genus Oryzavirus. However, the genomic terminal regions, conserved at the genus level in reoviruses, did not show homology to those of oryzaviruses, suggesting that RpLV may be a member of a new genus. It was found later, that RpLV was transmitted by A. agathonica. As all other plant reoviruses are transmitted by leaf- and planthoppers, these findings strongly support the creation of a new genus in the plant Reoviridae for the classification of RpLV. Real-time quantification of viral titers in single or mixed infections revealed that the titer of RBDV was enhanced ~400-fold when the virus was found in coinfections with RLMV. Interestingly, plants co-infected with these two viruses showed significant reduction in plant growth during the establishment and second year. Crumbly fruit was more severe in plants infected with the three viruses compared to the virus-free control. Taken together, this work presents valuable information about the interactions between three important raspberry viruses and their effect on plant growth and fruit crumbliness in 'Meeker', the most important red raspberry cultivar in the Pacific Northwest.
Author: Diego F. Quito-Avila Publisher: ISBN: Category : Closteroviruses Languages : en Pages : 138
Book Description
The United States is the third-largest producer of raspberries in the world. Washington State leads the nation in red raspberry (Rubus idaeus L.) production. 'Meeker', the most grown red raspberry cultivar in the Pacific Northwest (Washington, Oregon and British Columbia, Canada) is highly susceptible to Raspberry crumbly fruit, a virusinduced disease that produces drupelet abortion and reduces fruit quality and yield. The disease has long been attributed to Raspberry bushy dwarf virus (RBDV), a pollen-and-seed transmitted virus found in most commercial raspberry fields around the world. In recent years, an increased severity of crumbly fruit was observed in areas where two additional viruses were common. One of these viruses, Raspberry leaf mottle virus (RLMV), was characterized recently and shown to be a novel closterovirus transmitted by the large raspberry aphid Amphorophora agathonica Hottes. The second virus, Raspberry latent virus (RpLV) was a tentative member of the family Reoviridae whose characterization remained to be completed. To investigate the role of these two new viruses in the crumbly fruit disorder, 'Meeker' raspberry infected with single or mixtures of the three viruses, in all possible combinations, were generated by graft inoculation. Eight treatments, including a virus free control, were planted in the field at the Northwestern Research and Extension Center in Mt. Vernon, WA. Plant growth and fruit crumbliness were evaluated during establishment and the second year. Simultaneously, the characterization of RpLV, at the genetic and biological level, was completed. RpLV is a novel member of the plant Reoviridae composed of 26,128 nucleotides divided into 10 genomic dsRNA segments. Analysis of the RNA dependent RNA polymerase (RdRP) indicated that RpLV was related most closely to members of the genus Oryzavirus. However, the genomic terminal regions, conserved at the genus level in reoviruses, did not show homology to those of oryzaviruses, suggesting that RpLV may be a member of a new genus. It was found later, that RpLV was transmitted by A. agathonica. As all other plant reoviruses are transmitted by leaf- and planthoppers, these findings strongly support the creation of a new genus in the plant Reoviridae for the classification of RpLV. Real-time quantification of viral titers in single or mixed infections revealed that the titer of RBDV was enhanced ~400-fold when the virus was found in coinfections with RLMV. Interestingly, plants co-infected with these two viruses showed significant reduction in plant growth during the establishment and second year. Crumbly fruit was more severe in plants infected with the three viruses compared to the virus-free control. Taken together, this work presents valuable information about the interactions between three important raspberry viruses and their effect on plant growth and fruit crumbliness in 'Meeker', the most important red raspberry cultivar in the Pacific Northwest.
Author: Danielle Lightle Publisher: ISBN: Category : Amphorophora Languages : en Pages : 105
Book Description
In recent years, red raspberry production in Washington and British Columbia has been severely limited by a newly emerged virus complex that causes symptoms of crumbly fruit. The complex is comprised of three viruses: Raspberry bushy dwarf virus (RBDV), Raspberry leaf mottle virus (RLMV) and Raspberry latent virus (RpLV). Both RLMV and RpLV are transmitted by the aphid Amphorophora agathonica Hottes. The objectives of this work were to monitor seasonal phenology of A. agathonica and study the aphids' behavior on infected plants as well as resistant red and black raspberry cultivars. The lower developmental threshold of A. agathonica was calculated to be 2.7°C and field populations in northern Washington began increasing rapidly at approximately 800 growing degree days and peaked at approximately 1000 degree days. Evaluations of aphid performance on infected plants revealed that single infection plants (RLMV or RpLV) and co-infected plants (RLMV+RpLV) significantly increased aphid longevity over the healthy controls, while the co-infected plants also significantly increased aphid fecundity. Electrical penetration graph (EPG) studies of A. agathonica feeding behavior showed no differences in feeding between healthy and infected plants. However, EPG studies revealed two distinct mechanisms of resistance against A. agathonica in red and black raspberry. The red raspberry resistance gene Ag1 results in extended periods of salivation in the phloem sieve elements with little subsequent phloem ingestion, a behavior commonly associated with plant defense mechanisms related to a phloem recognition factor. Three novel aphid-resistant black raspberry selections were also studied. Aphids feeding on the resistant black raspberries were unlikely to salivate in the phloem sieve elements, which may point to a mechanism that causes aphids to be unable to recognize when they have punctured the sieve elements. Overall, this research discovered new information about A. agathonica biology, feeding behavior, and interactions with viruses that can be incorporated into future management strategies.
Author: Michael A. Ellis Publisher: Amer Phytopathological Society ISBN: 9780890541210 Category : Science Languages : en Pages : 100
Book Description
Diseases caused by biotic factors. Cane and foliar diseases caused by fungi. Fruit and flower diseases caused by fungi. Rust diseases. Root and crown diseases caused by fungi. Diseases caused by bacteria. Diseases caused by viruses and viruslike agents. Aphid-transmitted diseases. Leafhopper-transmitted diseases. Nematode-transmitted diseases. Pollen-transmitted diseases. Viral diseases with unknown methods of natural spread. Nematods parasites. Arthropod pests. Insects that damage roots and crowns. Insects that damage fruit. Scarab beetles. Insects and mites that damage foliage. Insects that damage cenes. Insect contaminants of mechanically harvested fruit. Disorders caused by abiotic factors. Nutritional disorders. Herbicide injury. Preemergent herbicides. Postemergent herbicides. Correcting herbicide excesses. Environmental stress. Effects of cultural practices on disease. Development of healthy planting materials.
Author: Lindsay Sara Mcmenemy Publisher: ISBN: Category : Languages : en Pages :
Book Description
Plants come under attack by a variety of organisms, including insects and pathogenic microorganisms such as viruses. Plant viruses can interact indirectly with their vectors by inducing changes to plant chemistry which may alter its attractiveness as a host for herbivore vectors. Using red raspberry as a study system, this study aimed to investigate the host plant mediated interactions occurring between the large raspberry aphid, Amphorophora idaei, and two of the viruses that it transmits, Black raspberry necrosis virus (BRNV) and Raspberry leaf mottle virus (RLMV). In whole plant bioassays, BRNV and RLMV-infected plants were shown to be initially more attractive to A. idaei and aphids remained on the initially selected host plant for a period of approximately 30 minutes. In addition, A. idaei took three days longer to reach reproductive maturity compared with those feeding on non-infected plants, suggesting a virally-induced manipulation of aphid behaviour whereby a deceptive attraction of the vector to a host plant found to be nutritionally poor, presumably acts to promote virus transmission. Investigations of the underlying plant chemistry revealed that raspberry viruses may be capable of facilitating aphid feeding by reducing leaf phenolic concentration when aphids are feeding and that infection with BRNV and RLMV resulted in significantly elevated levels of carbon and free amino acids in the leaves. While increased concentrations of amino acids might be expected to promote aphid performance, the amino acid composition was dominated by glutamate (77% of total content of infected plants), a previously suggested indicator of reduced host-plant suitability for aphids. Volatile entrainments from virus-infected plants showed elevated levels of the green leaf volatile (Z)-3-hexenyl acetate. Bioassays subsequently revealed that this compound acted as an aphid attractant at a concentration of 50 ng ml-1 but that aphid behaviour was unaffected by lower concentrations. The combined utilisation of PCR diagnostics developed from newly sequenced viral genomes and the implementation of a non-invasive, targeted method of sampling plant headspace volatiles enabled this study to provide novel insights into the nature of host plant mediated interactions between aphids and the viral pathogens that they transmit.
Author: Diego F. Quito-Avila
Author: Diego F. Quito-Avila
Author: Carlyle Wilson Bennett
Author: United States. Science and Education Administration
Author: 
Author: Danielle Lightle
Author: Richard H. Converse
Author: Irving E. Melhus
Author: J. R. Van Haarlem
Author: Michael A. Ellis
Author: Lindsay Sara Mcmenemy