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Abstract
Shoot branching is a primary contributor to plant architecture, evolving independently in flowering plant sporophytes and moss gametophytes. Mechanistic understanding of branching is largely limited to flowering plants such as Arabidopsis, which have a recent evolutionary origin. We show that in gametophytic shoots of Physcomitrella, lateral branches arise by re-specification of epidermal cells into branch initials. A simple model co-ordinating the activity of leafy shoot tips can account for branching patterns, and three known and ancient hormonal regulators of sporophytic branching interact to generate the branching pattern- auxin, cytokinin and strigolactone. The mode of auxin transport required in branch patterning is a key divergence point from known sporophytic pathways. Although PIN-mediated basipetal auxin transport regulates branching patterns in flowering plants, this is not so in Physcomitrella, where bi-directional transport is required to generate realistic branching patterns. Experiments with callose synthesis inhibitors suggest plasmodesmal connectivity as a potential mechanism for transport.
Original language | English |
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Journal | eLife |
Volume | 4 |
DOIs | |
Publication status | Published - 2015 |
Keywords
- Biological Transport
- Body Patterning
- Bryopsida
- Cytokinins
- Gene Expression Regulation, Plant
- Indoleacetic Acids
- Lactones
- Models, Biological
- Morphogenesis
- Mutation
- Plant Epidermis
- Plant Growth Regulators
- Plant Proteins
- Plant Shoots
- Plants, Genetically Modified
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