Type of Document Dissertation Author Zhao, Chengsong Author's Email Address firstname.lastname@example.org URN etd-06122005-230659 Title Identifying and characterizing genes that regulate vascular tissue-specific functions Degree PhD Department Horticulture Advisory Committee
Advisor Name Title Beers, Eric P. Committee Chair Keywords
Date of Defense 2005-06-03 Availability unrestricted AbstractVascular tissues provide both the mechanical support to the plant body and the conducting cells for the transport of water, mineral solutes, hormones and other signaling molecules, amino acids, and sugars. To identify genes that may regulate vascular tissue-specific functions, we isolated xylem, phloem-cambium, and nonvascular tissues from the Arabidopsis root-hypocotyl, performed a genome-wide comparative analysis of tissue-specific transcripts using the 24K Affymetrix Arabidopsis ATH1 Genome Array (24K GeneChip), and identified potential genes that are required for xylem and phloem differentiation or tissue-specific functions.
Based on this comparative analysis, two phloem-specific G2-like transcription factors, MYR1 and MYR2, and a xylem-specific NAC domain family member, XND1, were selected for further characterization. Under continuous light, myr2 plants flowered early, while myr1 plants did not differ significantly from wild type controls. However, double mutant myr1myr2 plants exhibited a novel phenotype characterized by elongated petioles, semi-erect leaf orientation, and suppression of lateral shoot outgrowth. These characteristics are reminiscent of yucca, a dominant Arabidopsis mutant with elevated levels of free auxin. Preliminary results indicated that like yucca, myr1myr2 plants were more resistant than wt plants to 5-mT, a toxic tryptophan analog, suggesting that MYR1 and MYR2 may be involved in regulating tryptophan-dependent auxin biosynthesis. Overexpression of any one of MYR1 isoforms resulted in a phenotype that in some cases resembled that observed in the double mutant, indicating that the regulation mediated by MYR1 and MYR2 may depend on formation of specific heterodimers consisting of isoforms of MYR1 and/or MYR2, and that the dimerization was susceptible to disruption both by overexpression and loss-of-function of MYR1/MYR2.
Overexpression of XND1 resulted in the absence of TEs as determined from the absence of both secondary cell wall deposition and TE death. Using 3 tissue-specific promoter-GUS lines as genetic backgrounds, we demonstrated that overexpression of XND1 suppressed only TE-specific GUS expression but not phloem-specific GUS expression. Three T-DNA/transposon insertion lines, xnd1-1, -2, and -3, were identified. Under normal conditions, xnd1 did not exhibit significantly different growth and development compared to wild type plants. However, preliminary data indicated that xnd1 plants were ABA and cold hypersensitive. Yeast-two hybrid screening using the N-terminal portion of XND1 as bait identified a novel RING finger protein, At3g62970 that may function as the ubiquitin ligase (E3). These results suggested that XND1 functions as a negative regulator of xylem cell differentiation, and that the regulation mediated by XND1 may be integrated with the ubiquitin/26S proteasome pathway.
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