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Chapter 36 Vegetative plant development

Chapter 36 Vegetative plant development. 36.1. Plant Embryo Development Establishes a Basic Body Plan. 36.1 – establishing the root-shoot axis. In plants, 3D shape and form arise by regulating the amount and pattern of cell division

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Chapter 36 Vegetative plant development

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  1. Chapter 36 Vegetative plant development

  2. 36.1 Plant Embryo Development Establishes a Basic Body Plan

  3. 36.1 – establishing the root-shoot axis • In plants, 3D shape and form arise by regulating the amount and pattern of cell division • As plant development proceeds, cells with multiple potentials are mainly restricted to meristem regions • Meristem – tissue in all plants consisting of undifferentiated cells • Many meristems have been established by the time embryogenesis ends and the seed becomes dormant • Apical meristems establish the root shoot axis • 3 basic tissue systems are established: dermal, ground, and vascular • While the embryo is developing, a food supply that will support the embryo during germination is established, and ovule tissue differentiates to form a hard, protective covering around the embryo • Seed enters dormant phase, signaling the end of embryogenesis

  4. 36.1 – establishing the root-shoot axis – early cell division and patterning • The 1st division of the zygote in a flowering plant generates cells with 2 different fates: • Daughter cell is small with dense cytoplasm and becomes an embryo • Daughter cell is larger, forms elongated structure called a suspensor – links the embryo to the nutrient tissue of the seed

  5. 36.1 – establishing the root-shoot axis – early cell division and patterning • Investigating mechanisms for establishing asymmetry in plant embryo development is difficult. One approach has been to use fucus as a model system • Genetic approaches make it possible to explore asymmetric development in angiosperms and to study mutants

  6. 36.1 – Establishing 3 Tissue Systems • 3 tissues differentiate while the plant embryo is still in the globular stage (b)  • Dermal tissue • Produces cells that protect the plant from desiccation • Formed from photoderm • Ground tissue • Function in food and water storage • Formed from a ground meristem • Vascular tissue • Responsible for water and nutrient transport • Formed from procambium

  7. 36.1 – Establishing 3 tissue systems – root and shoot formation • Root-shoot axis is established during the globular stage • Both the shoot and the root meristems are apical meristems but their formation is controlled independently

  8. 36.1 – establishing 3 tissue systems - morphogenesis • Globular stage gives rise to a heart-shaped embryo with 2 bulges – dicots and monocots • These bulges are cotyledons • Produced by embryonic cells • Process is called morphogenesis • The position of the cell plate determines the direction of division • Microtubules guide cellulose deposition as the cell wall forms around the outside of a new cell • Determines the cell’s final shape

  9. 36.1 – establishing 3 tissue systems – food storage • Throughout embryogenesis, starch, lipids, and proteins are produced • The sporophyte transfers nutrient via the suspensor in angiosperms • Seeds have stored nutrients to aid in germination until the growing sporophyte can photosynthesize

  10. 36.2 The seed protects the dormant embryo form water loss

  11. 36.2 – how seeds form • Development of the embryo is stopped soon after the meristems and cotyledons differentiate • The integuments (outer cell layers of the ovule) develop into a seed coat which ecloses the seed with its dormant embryo and stored food

  12. 36.2 – how seeds form – adaptive importance of seeds • Seeds are important adaptively in 4 ways: • Seeds maintain dormancy under unfavorable conditions and postpone development until better conditions arise • Seeds afford maximum protection to the young plant at its most vulnerable stage of development • Seeds contain stored food that permits a young plant to develop before photosynthetic activity begins • Seeds are adapted for dispersal, facilitating the migration of plant genotypes into new habitats

  13. 36.3 Fruit formation enhances the dispersal of seeds

  14. 36.3 – how fruits form • Fruits that contain seeds are defined as mature ovaries • Fruits form in many ways and exhibit a wide array of adaptations for dispersal • 3 layers of ovary wall can have distinct fates, which account for the diversity of fruit types • Fruits contain 3 genotypes in one package

  15. 36.3 – how fruits form – the dispersal of fruits • Fruits exhibit a wide array of specialized dispersal methods • Fruits with fleshy coverings normally are dispersed by birds or other vertebrates • Fruits with hooked spines are often disseminated by mammals • Other fruits such as maples have wings that aid in their distribution by the wind • Coconuts and other beach plants are regularly spread throughout a region either by water or African swallow

  16. 36.4 Germination initiates post-seed development

  17. 36.4 – mechanisms of germination • Germination – the emergence of the radicle (first root) through the seed coat • The sporophyte pushes through the seed coat, root grows down, shoot grows up • The shoot becomes photosynthetic and the postembryonic phase of growth and development begins • Germination begins when a seed absorbs water and its metabolism resumes • Many seeds will not germinate unless they have been stratified – held for periods of time at low temperatures • Germination can occur over a wide temperature range (5 to 30 degrees celcius) • In some species, a significant fraction of a season’s seeds remain dormant

  18. 36.4 – mechanisms of germination - utilization of reserves • Germination requires the utilization of metabolic reserves stored in the starch grains of amyloplasts (colorless plastids that store starch) and protein bodies • Fats and oils produce glycerol and fatty acids which yield energy through cellular respiration • Embryo produces gibberellic acid, a hormone, that signals the outer later of the endosperm called the aleurone to produce amylase • Enzyme breaks down the endospermic starch into sugars • Abscisic acid, another hormone, can inhibit starch breakdown • Emergence of the embryonic root and shoot from the seed during germination varies widely • In most plants, the root emerges before the shoot appears and anchors the young seedling in the soil

  19. Shoot development for (a) a eudicot, the common bean and (b) a monocot, corn

  20. Hormonal regulation of seedling growth

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