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Control of Growth and Development. Chapter 15. Developmental Processes. Present knowledge of plant hormone and light regulation (especially at the molecular level) is to a large extent the result of: 1) research on Arabidopsis thaliana and
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Control of Growth and Development Chapter 15
Developmental Processes • Present knowledge of plant hormone and light regulation (especially at the molecular level) is to a large extent the result of: 1) research on Arabidopsis thaliana and 2) our ability to transform plants using the Agrobacteriumsystem.
Arabidopsis thalianaWeed (of no agricultural importance)Economical reasons to study Arabidopsis: 1) Small size (+/- 30 cm tall at the end of its life cycle)2) Short life cycle (+/- 6 weeks from start of germination to next generation of seeds)3) Small genome* (complete DNA sequence is known): 125 million base pairs.* Combined sequence of all of the chromosomes.
Arabidopsis growth chamber Up to 1000 individual plants grown to maturity.
Agrobacterium tumefaciens • Plant transformation: inserting a piece of foreign DNA into a plant chromosome to allow the plant to make a foreign protein. • Most plant transformation technologies use the plant pathogen Agrobacterium tumefaciens.
Crown galls are formed when Agrobacterium tumefaciensinfects wounded plant tissue. The wounds often occur around the crown (area between stem and root), but can also be higher on the stem, like the gall on this wallnut tree. The gall tissue grows actively in the laboratory. Crown galls can be considered the plant equivalent of tumors (mammalian carcinogenesis). Fig. 17-5, p. 281
Genetic engineering by Agrobacterium tumefaciens 1 Plant tissue is wounded. 2 Plant secretes acetosyringone, a chemical that attracts Agrobacterium tumefaciens. Agrobacterium 3 Bacteria swim to wound and attach to cell walls of wounded cells. Ti plasmid 4 Agrobacterium cell injects a specialized piece of DNA into a plant cell. This DNA fragment is incorporated into a plant chromosome. plant cell nucleus 5 Stimulated by auxin and cytokinin produced by the enzymes coded in this piece of DNA, the plant cell repeatedly divides, forming a tumor. 6 The growing tumor serves as a sink for phloem transport. Nutrients delivered by the phloem are in part used to make opines, which are secreted. Bacteria living in the spaces between the plant cells take up the opines and catabolize them (break them into components to use for growth). Fig. 17-7, p. 282
Transforming a plant cell by using Agrobacterium Gene to be introduced in plant cell (for example: a gene that encodes the Luciferase protein) Plant Cell Agrobacterium + Modified Ti-plasmid Nucleus Transformed Plant Cell Agrobacterium Plant cell makes luciferase protein
Example of genetically engineered plant:Tobacco plant glows in the dark because the new gene that was inserted (which came from a firefly) produces the enzyme luciferase. By using an appropriate cytokinin to auxin ratio (see lecture on Plant Hormones) we can produce an adult plant starting from a single cell. Fig. 17-8, p. 282
Plants compared to animals Juvenile Growth and development Adult
Plants compared to animals Animals Plants Most development happens pre-birth Most development happens post-”birth” Cells (can) move during development Cells cannot move. Direction of cell division determines development Determinate growth pattern Mostly indeterminate growth pattern Limited environmental adaptations Flexible development in response to environmental changes
Stages in Differentiation • Meristem cells: after cell division, one daughter cell remains meristematic (undifferentiated) to maintain meristem size and the other daughter cell has committed to differentiation. Division of this second daughter cell will yield new cells that are even more differentiated (more specialized). Through such cell divisions and differentiation processes, plant organs (leafs, roots, etc…) are formed. Meristem cell Differentiated cell Meristem cell Differentiated cell Differentiated cell Meristem cell Differentiated cell
Stages in Differentiation • Plant organ: collection of differentiated cells, each cell having its own specific task depending on its position within the organ. Meristem cell Differentiated cell Meristem cell Differentiated cell Differentiated cell Meristem cell Differentiated cell • Cell differentiation leading to plant organ formation (leaf, root, flower, etc…)
Stages in Differentiation • Under certain conditions (see lectures on hormones), a differentiated cell can dedifferentiate and regain the characteristics of a meristematic cell (or a zygote, which is the ultimate meristematic cell). Meristem cell Dedifferentiation Differentiation Differentiated cell Meristem cell Differentiated cell Differentiated cell Meristem cell Differentiated cell
RNA Central dogma of Molecular Biology DNA TRANSCRIPTION REPLICATION + TRANSLATION mRNA Ribosome protein
Gene H Gene G Gene E Gene F Gene D Gene C Gene B Gene A RNA-H RNA-G RNA-F RNA-E RNA-D RNA-B RNA-A RNA-C Chromosomes contain many genes that can be expressed PROTEIN-B PROTEIN-A PROTEIN-F PROTEIN-H PROTEIN-D PROTEIN-C PROTEIN-E PROTEIN-G
Plant Cell-X Differential Gene Expression and Cell Differentiation Plant Cell-Y PROTEIN-B PROTEIN-D PROTEIN-C PROTEIN-A PROTEIN-H PROTEIN-H PROTEIN-F PROTEIN-C PROTEIN-G Plant Cell-X differs from Plant Cell-Y because it makes a different combination of proteins (a result of differential gene expression). Proteins are the main determinants of a cell’s characteristics (structure, biochemical abilities, etc….).
EXAMPLE of Differential Signaling LIGHT and COTYLEDON IDENTITY signals COTYLEDONS LIGHT and HYPOCOTYL IDENTITY signals HYPOCOTYL DARKNESS and ROOT IDENTITY signals ROOT
EXAMPLE of Differential Gene Expression Number of genes expressed in different plant organs (cotyledons, hypocotyls, roots) and under different environmental conditions (light versus dark) Venn diagrams display the gene sets that are specifically expressed (non-overlapping) and those that are expressed regardless of the plant organ or environmental condition (overlaps) From Ma et al., 2005. Plant Physiology
Arabidopsis thaliana Homo sapiens Genome size:135 million base pairs 3 billion base pairs Number of genes:27,00019,000 (number of proteins) Complexity of the protein collection made by plants is comparable to what is made by humans. Since proteins to a large extent determine the characteristics of a cell (and thus of a multicellular organism), we can conclude that the growth and development of higher plants is at least as complex as mammalian development. Plants compared to Animals