INVESTIGATING EVOLUTION OF PLANT DEVELOPMENT IN BASAL ANGIOSPERMS
Open Access
- Author:
- Bliss, Barbara Joanne
- Graduate Program:
- Biology
- Degree:
- Doctor of Philosophy
- Document Type:
- Dissertation
- Date of Defense:
- September 08, 2008
- Committee Members:
- Hong Ma, Dissertation Advisor/Co-Advisor
Hong Ma, Committee Chair/Co-Chair
Claude Walker Depamphilis, Committee Chair/Co-Chair
Siela Maximova, Committee Member
Paula Mc Steen, Committee Chair/Co-Chair - Keywords:
- AAGP
FGP
horticulture
TCP
basal angiosperms
Aristolochia fimbriata
genome size
transformation
regeneration - Abstract:
- Understanding the evolution of modern plants requires integrating findings from several disciplines, including plant physiology and development, molecular genetics, and genomics. Observations from model and non-model plants are brought together in a phylogenetic framework to derive hypotheses about how plant development evolved to generate the abundant diversity we see today. Testing those hypotheses requires a plant model system with the appropriate phylogenetic perspective: that of a basal lineage. The greatest diversity of plants today is among the angiosperms (flowering plants), a lineage which arose only about 160 million years ago. The most successful of these are the monocot and core eudicot flowering plant lineages, from which current plant model experimental systems are derived. For questions about the evolution of angiosperm development, a plant model from among the basal lineages is required. In addition to phylogenetic perspective, model systems possess features and degrees of availability, representation, and utility not found in other members of the taxa to which they belong. For all organisms, culturing requirements are central determinants of utility, but for studying the evolution of plant development, amenability to studies employing methods of genomics, genetics, molecular and developmental biology are also required. This dissertation describes the search for and selection of a proposed basal angiosperm experimental model, Aristolochia fimbriata, along with the development of initial technologies required for testing hypotheses about the evolution of plant development. Culturing, hand pollination, genetic transformation, and in vitro micropropagation and regeneration methods are described herein. Genes involved in flower form and architecture have been particularly important in the evolution of angiosperm diversity. The TCP gene family, so named for its founding members (TEOSINTE BRANCHED 1, CYCLOIDEA, PROLIFERATING CELL FACTOR) has been shown to play important roles in evolution of form in both monocots and eudicots. Prior functional and phylogenetic analyses of this gene family revealed clades of TCP genes with two different kinds of gene function. Since then, additional sequence data from basal lineages and new studies providing insight into TCP gene function have become available. Together, these warrant an updated phylogeny and review of this important gene family. Preliminary phylogenetic analyses of the TCP gene family is described as a foundation for conducting future expression and functional analyses. A. fimbriata has floral and vegetative features that will facilitate evaluating the role of TCP genes in evolution of angiosperm form, and advance the use of this species as a basal angiosperm model system.