1 / 57

Cell expansion plays a major role in growth

Cell expansion plays a major role in growth. Root cells expand their volume 50 times by expanding lengthwise but not widthwise. In roots, cell expansion plays a major role in growth. Two competing plant hormones determine the direction of cell expansion:.

heribertob
Download Presentation

Cell expansion plays a major role in growth

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Cell expansion plays a major role in growth Root cells expand their volume 50 times by expanding lengthwise but not widthwise

  2. In roots, cell expansion plays a major role in growth Two competing plant hormones determine the direction of cell expansion: GA (gibberellic acid) promotes growth along the length Ethylene promotes growth along the width

  3. Auxin and Cytokinin control shoot and root growth High levels of Cytokinin and low levels of Auxin promote shoot development (stems with leaves) High levels of Auxin and low levels of Cytokinin promote root development

  4. The Miller-Skoog Experiment: Cloning • Place single cell on medium with high levels of Cytokinin and low levels of Auxin to promote shoot development (stems with leaves) • Place shoots on medium with high levels of Auxin and low levels of Cytokinin to promote root development at the base of the shoot • Transfer rooted shoots to soil and grow plants to maturity

  5. Figure 38.2 Review of an idealized flower

  6. Pollination is the first step of the fertilization process.

  7. The pollen “germinates” and grows down into the ovary where fertilization of the egg occurs.

  8. Even at this one cell stage the embryo reveals polarity. The first cell division is asymmetric, producing a small apical cell and a larger basal cell.

  9. The apical cell will later give rise to the entire “embryo proper”. The basal cell will give rise to a small umbilical cord-like structure called the suspensor.

  10. The small apical cell divides several times to generate the globular embryo. All cells of this embryo appear morphologically similar.

  11. Several divisions later morphological asymmetry is seen in the heart shaped embryo.

  12. Arabidopsis embryogenesis

  13. Arabidopsis embryogenesis

  14. Cotyledons (seed leaves) Shoot Apical Meristem Hypocotyl (seedling stem) Root Root Apical Meristem

  15. Plant Stem Cells: Shoot and root meristem Weigel and Jürgens, 2002; Bowman and Eshed, 2000; Nakajima and Benfey, 2002

  16. What is a shoot apical meristem? -a group of undifferentiated “stem” cells -stem cells renew themselves while generating lateral organs off the flanks - located at the tips of growing shoots - 3 types: vegetative, inflorescence, floral

  17. Gerd Jurgens searched for embryo pattern mutants. • Soak seeds in a mutagen • Grow plants to maturity • These plants would be carriers of mutations (m/+) • When these carriers self-fertilize, the resulting • embryos would be: +/+, m/+, m/m • Mutants similar to gap mutants in flies were identified, lacking regions of the embryo, including the apical structures, the stem (hypocotyl) and root

  18. Embryo Pattern Mutants

  19. Organization of the SAM Fletcher 2003

  20. L1 and L2 cells divide anticlinally: perpendicular to the surface These divisions contribute to surface growth without increasing the number of cell layers

  21. L3 cells divide in both planes to add additional cell layers to the shoot.

  22. Organization of the SAM Fletcher 2003

  23. Shoot Apical Meristem The shoot apical meristem can be divided into distinct zones.

  24. -stem cells Shoot Apical Meristem The central zone is maintained as a pool of undifferentiated stem cells.

  25. -peripheral zone Shoot Apical Meristem The peripheral zone is the site of organ initiation.

  26. -stem cells -peripheral zone Shoot Apical Meristem As cell divisions occur in the central zone, the resulting cells are pushed into the peripheral zone where they are incorporated into organ primordia.

  27. Dividing Stem Cells are Pushed into the Peripheral Zone

  28. -stem cells -peripheral zone Shoot Apical Meristem The central zone cells will give rise to all of the above-ground organs of the mature plant.

  29. -stem cells -peripheral zone Shoot Apical Meristem How is the stem cell population maintained throughout the life of the plant?

  30. -stem cells -peripheral zone Shoot Apical Meristem A feedback loop between organ initiation (peripheral zone) and the stem cell (central zone) population regulates the size of the meristem.

  31. Genes Controlling Meristem Development Normal heart- stage embryo WUS or STM mutant embryo WUSCHEL and SHOOTMERISTEMLESS mutants fail to develop a shoot apical meristem.

  32. STM and WUS mutants do not form a shoot apical meristem

  33. Genes Controlling Meristem Development Normal heart- stage embryo WUS or STM mutant embryo CLV1 or CLV3 mutant embryo CLAVATA1 and CLAVATA3 mutants develop a greatly enlarged shoot apical meristem.

  34. CLV1 mutants have a larger meristem and make more stem cells wt clv1

  35. CLV3 mutants make more stem cells and resemble CLV1 mutants Fletcher et al., 1999

  36. Genes Controlling Meristem Development • STM and WUS are required to form and maintain the stem cell population

  37. Genes Controlling Meristem Development • STM and WUS are required to form and maintain the stem cell population • CLV1 and CLV3 are required to prevent the over-proliferation of the undifferentiated stem cell population

  38. Genes Controlling Meristem Development • STM and WUS are homeobox genes and encode proteins that function as transcription factors

  39. Genes Controlling Meristem Development • STM and WUS are homeobox genes and encode proteins that function as transcription factors • CLV1 encodes a receptor protein

  40. Genes Controlling Meristem Development • STM and WUS are homeobox genes and encode proteins that function as transcription factors • CLV1 encodes a receptor protein • CLV3 encodes a small protein that functions as a signaling molecule that binds to the CLV1 receptor

  41. CLV / WUS Interactions CLV3 is expressed in the L1 and L2 cell layers of the central zone

  42. CLV / WUS Interactions CLV1 and WUS are expressed in a small domain of L3 cells in the central zone

  43. CLV / WUS Interactions CLV3 expression is lost in WUS mutants. Therefore, WUS activates CLV3 expression.

  44. CLV / WUS Interactions The expression domain of WUS is greatly enlarged in CLV1 and CLV3 mutants. Therefore, CLV1 and CLV3 negatively regulate (repress) WUS expression.

  45. CLV / WUS Interactions CLV3 binds to and activates the CLV1 receptor, which then represses WUS expression.

  46. CLV / WUS Interactions WUS is part of an “organizing center” that promotes stem cell proliferation in overlying cells.

  47. CLV / WUS Interactions A feedback loop between CLV and WUS maintains the stem cell population throughout the life of a plant.

  48. Genetic Interactions between STM and CLV • The greatly enlarged meristems that form in clv mutants are largely suppressed when the activity of STM is reduced (for example, in stm/+ plants).

  49. Genetic Interactions between STM and CLV • The greatly enlarged meristems that form in clv mutants are largely suppressed when the activity of STM is reduced (for example, in stm/+ plants). • Similarly, the loss of shoot meristems in stm mutants is restored in plants that have reduced CLV activity (for example in clv/+ plants).

More Related