Gymnosperm18 withgneto


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Gymnosperm18 withgneto

  1. 1. Gymnosperms Chapter 18
  2. 2. Two major groups of vascular plants: <ul><li>A. Seedless plants - reproduce via spores </li></ul><ul><li>B. Seed plants - reproduce via seeds </li></ul><ul><li>1. Seed = a structure in which the embryo (the young sporophyte) is shed from the parent plant, enclosed within a resistant coat, together with a supply of food that aids its establishment </li></ul><ul><li>2. The majority of extant plants are seed plants </li></ul>
  3. 3. Seeds <ul><li>Consist of an embryo </li></ul><ul><li>Stored food </li></ul><ul><li>Seed coat </li></ul><ul><ul><li>Modern seed plant the ovule consist of a nucellus envelope by one or two integuments with a micropyle (apical opening) </li></ul></ul><ul><ul><li>When fertile the nucellus contains a megagametophyte composed of nutritive tissue and archegonia </li></ul></ul><ul><ul><li>After fertilization the integuments develop into a seed coat; a seed is formed </li></ul></ul>
  4. 4. Characteristics of seed plants: <ul><li>A. Megaphylls </li></ul><ul><li>B. Heterospory </li></ul><ul><li>C. A reduced megagametophyte retained within the megaspore </li></ul><ul><li>D. A megaspore retained within a fleshy megasporangium called a nucellus </li></ul><ul><li>E. Pollen - a structure which carries the male gamete to the female gamete </li></ul><ul><li>Seed plants do not require water for fertilization </li></ul>
  5. 5. Evolution of an ovule <ul><li>Retention of the megaspores within the megasporangium (fleshy nucellus)- the megasporangium no longer releases the spores </li></ul><ul><li>Reduction of megaspore mother cells to one functional megaspore in the megasporangium </li></ul><ul><li>Formation of an endosporic (within the wall) megagametophyte that is no longer free-living- retained within the megasporangium </li></ul>
  6. 6. Evolution of an ovule <ul><li>Development of the embryo (young sporophyte) within the megagametophyte retained within the megasporangium </li></ul>
  7. 7. Evolution of an ovule <ul><li>Formation of an integument that completely envelops the megasporangium except for the micropyle </li></ul><ul><li>Modification of the apex of the megasporangium to receive microspores or pollen grains </li></ul>
  8. 8. Evolution of seeds <ul><li>A. The seed habit arose by 365 million years ago via fusion of vegetative tissues around the megasporangium </li></ul><ul><li>1. This additional protective layer is called an integument </li></ul><ul><li>2. The integument has a small opening, the micropyle , through which fertilization takes place </li></ul><ul><li>3. Ovule = an integumented megasporangium </li></ul><ul><li>4. Following fertilization the integument will become the seed coat </li></ul>
  9. 9. Classification <ul><li>A. There are five phyla of extant seed plants: </li></ul><ul><li>1. Four of the phyla have naked ovules borne on modified sporopylls. These are called &quot; gymnosperms &quot; = “naked seed” </li></ul><ul><li>2. In the remaining phylum (Anthophyta) the ovules are enclosed within a protective structure called an ovary (flower like reprodcutive structures) </li></ul>
  10. 10. PHYLA OF GYMNOSPERMS <ul><li>Cycadophyta (cycads) </li></ul><ul><li>Ginkophyta (maidenhair tree or Ginko) </li></ul><ul><li>Coniferophyta or Pinophyta (conifers) </li></ul><ul><li>Gnetophyta (gnetophytes) </li></ul>
  11. 11. Coniferophyta <ul><li>I. Coniferophyta - commonly called conifers </li></ul><ul><li>A. About 50 genera and 550 species </li></ul><ul><li>B. Common members include the pines, hemlocks, spruces, firs, yews, cypresses, junipers and redwoods </li></ul><ul><li>C. Conifers are most common at the higher higher latitudes, towards the poles </li></ul><ul><li>D. Conifers arose by 300 million years ago </li></ul>
  12. 14. <ul><li>E. Conifers include some of the largest organisms on earth, e.g. Coast redwoods may reach 380 feet tall and giant sequoias may reach diameters of 36 feet. A bristlecone pine, dated at 4,900 years old, is one of the oldest organisms on earth. </li></ul><ul><li>F. Conifers are one of the most economically important groups of plants. They supply building materials and paper pulp </li></ul>
  13. 15. <ul><li>All conifers are woody and they have a bifacial vascular cambium that produces xylem to the inside and phloem to the outside </li></ul>
  14. 16. <ul><li>1. As the tree grows the center xylem becomes lignified to provide additional support </li></ul><ul><li>2. Lignin is a chemical deposited in the secondary walls </li></ul><ul><li>a. Heartwood = center, nonfunctional, lignified secondary xylem </li></ul><ul><li>b. Sapwood = outer, functional, non-lignified secondary xylem </li></ul>
  15. 17. <ul><li>3. With initiation of secondary growth the epidermis is replaced by a periderm produced by the cork cambium </li></ul><ul><li>a. Bark = all tissue external to the vascular cambium. </li></ul>
  16. 18. Longleaf pines
  17. 19. Foliar unit
  18. 20. Open seed cone
  19. 21. Pine seedling
  20. 22. <ul><li>G. Most conifers are evergreen, but there are a few deciduous species, e.g. bald cypress and larch </li></ul>
  21. 23. Swamp bald cypress
  22. 24. Common bald cypress
  23. 25. Larch meadow
  24. 27. Fir
  25. 29. Juniper
  26. 30. Sequoiadendron
  27. 31. Broken branch
  28. 34. Dawn redwood
  29. 35. Conifer reproduction <ul><li>1. Megasporangia and microsporangia are borne in separate megastrobili and microstrobili (cones) </li></ul>
  30. 36. Ovulating pine cones
  31. 37. <ul><li>2. Microstrobili (male cones) are relatively small and they dry up and wither away shortly after shedding their pollen. The strobili consist of a central axis with pairs of microsporangia on the underside of microsporophylls . Within the immature microsporangia microsporocytes (microspore mother cells) undergo meiosis to produce four haploid microspores . Each microspore develops into a winged pollen grain which consists of: </li></ul>
  32. 38. <ul><li>a. Two prothallial cells </li></ul><ul><li>b. One generative cell </li></ul><ul><li>c. One tube cell </li></ul><ul><li>d. This four celled pollen grain is the immature male gametophyte. The pollen is shed at this stage and it carried by the wind to an immature megastrobilus (female cone) </li></ul>
  33. 39. <ul><li>3. During the spring pollination season the megastrobili (female cones) have their cone scales open. The pollen in the wind is caught and held by a sticky secretion. As the secretion dries up the pollen is drawn into the micropyle . The cone scales then grow together </li></ul>
  34. 41. Pollen cone
  35. 44. <ul><li>4. The pollen tube begins to digest through the nucellus towards the developing megagametophyte </li></ul>
  36. 46. Another Pine life cycle figure
  37. 47. <ul><li>5. Twelve months after pollination the generative cell divides to form a sterile cell and a spermatogenous cell </li></ul><ul><li>a.  The spermatogenous cell then divides to produce two sperm cells. At this stage the male gametophyte is mature </li></ul>
  38. 48. <ul><li>6. Megastrobili (female cones) are larger than the microstrobili. A pair of ovules sit on top of a seed-scale complex which is subtended by a sterile bract. Each ovule contains a multicellular nucellus surrounded by a thick integument with an opening ( micropyle ) facing inward </li></ul>
  39. 49. <ul><li>7. Each nucellus contains a megasporocyte (megaspore mother cell) which undergoes meiosis to produce four haploid cells. Three degenerate and the remaining one develops into the megagametophyte over a six month period. This takes place up to six months after pollination. Development of the megagametophyte is therefore a full year behind formation of the pollen responsible for its fertilization </li></ul>
  40. 50. <ul><li>8. At 13 months after pollination, inside the megagametophyte, a large number of free nuclear divisions take place, forming 2,000 free nuclei. Then cell walls form to make solid tissue. This gametophytic tissue will become the stored food inside the mature seed </li></ul>
  41. 51. <ul><li>9. 15 months after pollination 2 - 3 archegonia, each containing an egg, form. At this time the pollen tube reaches the archegonia and it discharges both sperm nuclei into the archegonia. One sperm fertilizes the egg, the other degenerates </li></ul>
  42. 52. <ul><li>10. As the developing zygote divides to form the embryo four tiers of cells are produced. These form suspensors which push the developing embryo deep into the gametophyte tissue (developing stored food). Simultaneously the integument forms the seed coat </li></ul>
  43. 53. <ul><li>11. The seeds mature and they are shed during the second autumn, when the cone scales open. Therefore if takes about 2 1/2 years from pollination to the shedding of seeds </li></ul>
  44. 56. Gnetophtya <ul><li>Welwitschia mirablis </li></ul>
  45. 57. Gnetophyta <ul><li>Liana </li></ul>
  46. 58. Gneto Leaves <ul><li>Gnetophyta can have opposite or whorled type leaves also here is an Example of Strap like leaves Welwitschia Mirablis </li></ul>
  47. 59. Leaves continue <ul><li>Angiosperm-like Leaves of Gnetum </li></ul><ul><ul><li>Gnetaceae </li></ul></ul>
  48. 60. <ul><li>Scale-like Leaves of Ephedra </li></ul>
  49. 61. Ginkophyta
  50. 62. Cycadophyta