Differentially expressed genes of Sophrolaeliacattleya Ginny Champion "Riverbend" in response to the odontoglossum ringspot virus

Schuck, Heather A.

January 2000

Due to the rapid destruction of native orchid habitats it has become necessary to house many endangered orchid species in greenhouse environments where enhanced spread of viral disease occurs due to the close contact between plants. This research was concerned with the construction of a library of genes whose expression is induced in response to viral challenge. In uncovering the genes that are activated during plant-pathogen interactions, it may be possible to manipulate these pathways to develop virus resistant orchids. Furthermore, this research will contribute additional information for the existing framework of plant-pathogen interactions of all plant species.In order to construct a library of genes expressed in response to viral infection, suppression subtractive hybridization was performed using the PCR-Select cDNA Subtraction Kit (CLONTECH, Palo Alto, CA) on Sophrolaeliacattleya Ginny Champion 'Riverbend' clones. RNA was isolated from plants that had been inoculated with the Odontoglossum ringspot virus (ORSV) and from control plants that had not been inoculated with ORSV. Following reverse transcription-PCR (RT-PCR) to obtain cDNA, cDNAs of the tester population (those cDNAs containing differentially expressed messages in response to ORSV) and the driver population (reference cDNAs from uninfected plants) were obtained. The two different cDNA populations are mixed together and hybridized. The sequences common to both populations were subtracted, leaving only the differentially expressed sequences available for PCR amplification.A library containing these genes was constructed, and one clone, chosen at random, was sequenced. Based on homology comparisons to known genes, we have cloned a gene that may contain a nucleotide binding site similar to that of the tobacco N gene, important for plant resistance to pathogens. In the near future, this clone will be used to construct probes for use in northern analysis to determine the timing and localization of the products of this gene. This information will aid in characterizing the function of the orchid N-gene and identifying other members of this signal cascade. In addition, many other clones await sequencing and similar characterization. / Department of Biology

Tobacco mosaic virus -- Control.

Comparing orchid transformation using agrobacterium tumefaciens and particle bombardment

Parsons, Stephen H.

January 1995

The Wheeler Orchid Collection is home to some of the most endangered species of orchids in the world. This fantastic reservoir of endangered species has been enhanced and broadened by its function as a plant rescue station for the U.S. customs service. Unfortunately, this responsibility increases the risk of bringing orchids, which harbor contageous diseases, into the greenhouse where sap transmitted diseases such as the Tobacco Mosaic Virus (TMV), can run rampant. Although manipulation of orchid characteristics is typically done by classical plant breeding techniques, genetic engineering is emerging as a useful technique for the introduction of desirable traits into the orchid genome. Through the use of genetic engineering techniques it may be possible to mitigate the symptoms associated with this destructive virus. Virus resistance may be achieved through the expression of either the sense or antisense viral coat protein gene in orchid tissues if an efficient means of orchid transformation is developed. In this research two transformation protocols were examined for their ability to efficiently transform orchid tissue. The first transformation protocol explored utilized the native ability of Aq bacterium tumefaciens to incorporate DNA into host plants to achieve transformation. The second mechanism explored was particle bombardment transformation.Many strains of A. tumefaciens were employed using direct exposure of Cattleya_ orchid protocorm and callus tissue. Particle bombardment using DNA coated 0.5 um diameter tungsten particles and high pressure helium tank acceleration was employed. The particle bombardment procedure employed the pG35barB plasmid which confers herbicide resistance to the herbicide basta when integrated and expressed in plant tissues.GUS fluorescence assays and PCR analysis indicate that T-DNA is present in orchid tissues, while Southern blot analysis was unable to display that integration had occurred. Particle bombardment yielded herbicide resistant orchid tissues which have yet to be analyzed by Southern blot analysis to confirm integration due to limited tissue quantities. / Department of Biology

Bacterial transformation.

Tobacco mosaic virus -- Control.

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

Carroll, Audra L.

January 1999

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

Oligonucleotides.

Tobacco mosaic virus -- Control.

Orchids -- Genetic engineering.

Agrobacterium tumefaciens mediated transformation of orchid tissue with the sense and antisense coat protein genes from the odontoglossum ringspot virus

Hutchinson, Chad M.

January 1992

This research was an attempt to use a dicot transformation vector to transform a monocot. The initial purpose of this thesis was to transform orchids with the sense and antisense coat protein genes from the Odontoglossum ringspot virus (ORSV) in an effort to mitigate viral symptoms in transgenic plants using the transformation vector, Agrobacterium tumefaciens. However, it soon became apparent that much time would be needed to develop a transformation protocol. The transformation vectors used included the Agrobacterium tumefaciens disarmed strain LBA4404 with the binary plasmid pB1121, the disarmed strain At699 with the binary plasmid pCNL65, and the wild-type strain Chry5. The marker gene on the binary plasmids of both disarmed strains was p-glucuronidase (GUS).Several transformation protocols were used in an effort to determine if this transformation system would work on orchids. Transformation was not achieved even though a number of experimental conditions were varied. These included using two different types of orchid tissue, callus and protocorms; using two different species of orchids, Cattleya Chocolate Drop x Cattleytonia Kieth Roth and Cymbidium maudidum; varying the time the plant tissue was exposed to the bacteria from 1 hour to 96 hours; performing experiments with and without the wound signal molecule acetosyringone; and exposing the tissue to the virulent strains of A. tumefaciens mentioned previously.This research also developed GUS assay conditions necessary to decrease the number of false positives due to bacterial contamination. These conditions included chloramphenicol in the GUS assay buffer. / Department of Biology

Tobacco mosaic virus -- Control.

Bacterial transformation.

Genetic transformation.

Orchids -- Genetic engineering.