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Lesson Overview

Lesson Overview. 24.3 Plant Hormones. THINK ABOUT IT. How do roots “know” to grow down, and how do stems “know” to grow up? How do the tissues of a plant determine the right time of year to produce flowers?

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Lesson Overview

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  1. Lesson Overview 24.3 Plant Hormones

  2. THINK ABOUT IT • How do roots “know” to grow down, and how do stems “know” to grow up? How do the tissues of a plant determine the right time of year to produce flowers? • In short, how do the collections of cells in a plant manage to act together as a single organism? Is something carrying messages from cell to cell?

  3. Hormones • What roles do plant hormones play?

  4. Hormones • What roles do plant hormones play? • Plant hormones serve as signals that control development of cells, tissues, and organs. They also coordinate responses to the environment. • The opposing effects of plant hormones contribute to the balance necessary for homeostasis.

  5. Hormones • Hormones are chemical signals produced by living organisms that affect the growth, activity, and development of cells and tissues within them. They also coordinate responses to the environment. • In plants, hormones may act on the same cells in which they are made, or they may travel to different cells and tissues, as seen in the figure.

  6. Hormones • One mechanism of hormone action in plants is shown. • In this case, hormone-producing cells in a mature flower release hormones that travel into flower buds and inhibit development. • Once the mature flower is done blooming, production of the inhibiting hormone will decline, and the flower bud can then begin its bloom.

  7. How Hormones Act • The portion of an organism affected by a particular hormone is known as its target cell. • To respond to a hormone, a cell must contain hormone receptors—usually proteins—to which hormone molecules bind.

  8. How Hormones Act • The response that results will depend on what kinds of receptors are present in the target cell. • Depending on the receptors present, a given hormone may affect roots differently than the way it affects stems or flowers—and the effects may change as the developing organs add or remove receptors.

  9. Auxins • Charles Darwin and his son Francis explored the mechanism behind a grass seedling’s tendency to bend toward light. The results of their experiments suggested that the tip of the seedling somehow senses light. • The Darwins hypothesized that the tip produces a substance that regulates cell growth.

  10. Auxins • Auxins stimulate cell elongation and the growth of new roots, among other roles that they play. • They are produced in the shoot apical meristem and transported to the rest of the plant.

  11. Auxins and Cell Elongation • One of the effects of auxins is to stimulate cell elongation. • When light hits one side of the shoot, auxins collect in the shaded part of the shoot. • This change in concentration stimulates cells on the dark side to lengthen, causing the shoot to bend away from the shaded side and toward the light.

  12. Auxins and Branching • Auxins also regulate cell division in meristems. Growth at lateral buds is inhibited by auxins. • Because auxins move out from the apical meristem, the closer a bud is to the stem’s tip, the more it is inhibited. Lateral buds near the apex grow more slowly than those near the base of the plant. This phenomenon is called apical dominance.

  13. Auxins and Branching • If you snip off the tip of a plant, the lateral buds begin to grow more quickly and the plant becomes bushier. • This is because the apical meristem—the source of the growth-inhibiting auxins—has been eliminated.

  14. Cytokinins • Cytokinins are plant hormones that are produced in growing roots and in developing fruits and seeds. • Cytokinins stimulate cell division, and they interact with auxins to control the growth of new organs in injured plants and to balance root and shoot growth. • Cytokinins also delay the aging of leaves and play important roles in the early stages of plant growth.

  15. Cytokinins • Cytokinins often produce effects opposite to those of auxins. • Auxins stimulate the initiation of new roots, and they inhibit the initiation and growth of new shoot tips. Cytokinins do just the opposite. • If a tree is cut down, the stump will often make new shoots because cytokinins accumulate near the cut, while auxins move away.

  16. Gibberellins • Hormones called gibberellins stimulate growth and can influence various developmental processes. • Gibberellins promote germination of plants, and may cause dramatic increases in size, particularly in stems and fruits. • Gibberellins are found in the meristems of shoots, roots, and seed embryos.

  17. Abscisic Acid • Gibberellins interact with another hormone, abscisic acid, to control seed dormancy. • Abscisic acid inhibits cell division, thereby halting growth. • Abscisic acid are found in the terminal buds and seeds.

  18. Abscisic Acid • When seed development is complete, abscisic acid stops the seed’s growth and shifts the embryo into a dormant state. • The embryo rests until environmental events shift the balance of hormones. Such events may include a strong spring rain that washes abscisic acid away. Without the opposing effect of abscisic acid, the gibberellins can signal germination. • Abscisic acid and gibberellins have opposite effects, much like auxins and cytokinins.

  19. Ethylene • In response to auxins, fruit tissues release small amounts of the hormone ethylene, which stimulates fruits to ripen.

  20. Ethylene • Ethylene also causes plants to seal off and drop organs that are no longer needed, for example, petals after flowers have been pollinated, leaves in autumn, and ripened fruits. • Ethylene signals cells at the base of the structure to seal off from the rest of the plant by depositing waterproof materials in their walls.

  21. Tropisms and Rapid Movements • What are some examples of environmental stimuli to which plants • respond?

  22. Tropisms and Rapid Movements • What are some examples of environmental stimuli to which plants • respond? • Plants respond to environmental stimuli such as light, gravity, and touch.

  23. Tropisms • Plants respond to environmental stimuli such as light, gravity, and touch. • Plants have sensors that detect the direction of stimuli and signal elongating organs to orient their growth toward or away from these stimuli. • These growth responses are called tropisms.

  24. Light • The tendency of a plant to grow toward a light source is called phototropism. • Changes in the concentration of auxins are responsible for phototropism. • Experiments have shown that auxins migrate toward shaded tissue, possibly due to changes in membrane permeability in response to light.

  25. Gravity • Auxins also affect gravitropism, the response of a plant to gravity. • Auxins migrate to the lower sides of horizontal roots and stems. • In horizontal stems, the migration causes the stem to bend upright. In horizontal roots, however, the migration causes roots to bend downward.

  26. Touch • Some plants respond to touch, a process called thigmotropism. • Vines and climbing plants exhibit thigmotropism when they encounter an object and wrap around it. • Other plants, such as grape vines, have extra growths called tendrils that emerge near the base of the leaf and wrap tightly around any object they encounter.

  27. Rapid Movements • Some plant responses are very rapid. • A mimosa plant will respond to being touched by folding in its leaves quickly. • This response is produced by decreased osmotic pressure in cells near the base of each leaflet.

  28. Rapid Movements • The carnivorous Venus’ flytrap also demonstrates rapid responses. • When an insect lands on a flytrap’s leaf, it triggers sensory cells on the inside of the leaf, sending electrical signals from cell to cell. • A combination of changes in osmotic pressure and cell wall expansion causes the leaf to snap shut, trapping the insect inside.

  29. Response to Seasons • How do plants respond to seasonal changes?

  30. Response to Seasons • How do plants respond to seasonal changes? • Photoperiod is a major factor in the timing of seasonal activities such as flowering and growth. • As cold weather approaches, deciduous plants turn off photosynthetic pathways, transport materials from leaves to roots, and seal off leaves from the rest of the plant.

  31. Photoperiod and Flowering • Many plants respond to the relative lengths of light and darkness, a stimulus called the photoperiod. • Photoperiod is a major factor in the timing of seasonal activities such as flowering and growth, as shown in the figure.

  32. Photoperiod and Flowering • A plant pigment called phytochrome is responsible for photoperiodism. • Phytochrome absorbs red light and activates a number of signaling pathways within plant cells. Plants respond to regular changes in these pathways.

  33. Winter Dormancy • Phytochrome also regulates the changes in activity that prepare many plants for dormancy as winter approaches. • As cold weather approaches, deciduous plants turn off photosynthetic pathways, transport materials from leaves to roots, and seal off leaves from the rest of the plant.

  34. Leaf Loss • Many flowering plants lose their leaves during the colder months. • The phytochrome in leaves absorbs less light as days shorten and nights become longer. • Auxin production drops, but the production of ethylene increases.

  35. Leaf Loss • As chlorophyll breaks down, other pigments—including yellow and orange carotenoids—become visible for the first time. • The brilliant reds come from anthocyanin pigments that are freshly made.

  36. Changes to Meristems • Hormones produce important changes in apical meristems. • Meristems produce thick, waxy scales that form a protective layer around new leaf buds. • Enclosed in its coat of scales, a terminal bud can survive cold winter days.

  37. Changes to Meristems • At the onset of winter, xylem and phloem tissues pump themselves full of ions and organic compounds. • The resulting solution acts like antifreeze in a car, preventing the tree’s sap from freezing.

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