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Sense and antisense oligonucleotide inhibition of the Odontoglossum ringspot virus (ORSV) coat protein gene via microprojectile bombardment of orchid callus tissue

A major goal of our laboratory is to confer resistence specifically to the Odontoglossum ringspot virus [ORSV; sometimes referred to as tobacco mosaic virus strain O (TMV-O)] in orchids. The chosen strategy may also provide cross-protection to other pathogens. The experimental design for the entire project is presented here along with the results obtained in several preliminary experiments performed in this research. Our approach involved RT-PCR amplification of the viral coat protein gene with gene-specific primers and digestion of the cDNAs into oligonucleotides. These fragments were cloned into the selectable vector pG35barB (which confers herbicide resistence) in both sense and antisense orientations. The cloned DNA was coated with tungsten beads and shot into orchid callus tissue using a makeshift biolistic gun. Tranformant callus cells were selected for by herbicide resistance. Unfortunately the potential transformants became contaminated with fungus and could nto be analyzed to determine which oligonucleotide was received and the effect each oligonucleotide had on pathogen resistance. Due to the uncertainty of the relatedness between ORSV and TMV-O, we also sequenced the coat protein gene of TMV-O and compared the amino acid sequence with those of several strains of ORSV: the Japanese strain had the highest percent amino acid similarity (99.4%), the Type strain the second highest (98.7%), and the Korean strain the lowest (96.9%). It was concluded that TMV-O is most likely one strain of ORSV, the Japanese strain. / Department of Biology

Identiferoai:union.ndltd.org:BSU/oai:cardinalscholar.bsu.edu:handle/186523
Date January 1999
CreatorsCarroll, Audra L.
ContributorsVann, Carolyn N.
Source SetsBall State University
Detected LanguageEnglish
Formatxi, 60 leaves : ill., charts ; 28 cm.
SourceVirtual Press

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