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Reading: Seed Plants

  • Page ID
    7686
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    Gymnosperms

    The four phyla of gymnosperms are cycads, ginkgo, gnetophytes, and conifers.

    Gymnosperms have naked seeds. The seeds of angiosperms are contained within a fruit.

    Gymnosperm Diversity

    We will examine conifers in some detail during this lab class but will use photographs on the Internet to study the other three divisions. Click on the links below to view photographs of them.

    Cycads

    Cycads re cone-bearing palmlike plants found mainly in tropical and subtropical regions today. They were very numerous in the Mesozoic Era.

    Ginkgo

    There is only one species of Ginkgo left. It survived due to Chinese planting them along roadsides. Click here for information and photographs.

    Conifers

    Conifers are the largest group of gymnosperms. They include evergreen trees such as pine, cedar, spruce, fir, and redwood trees. Examine the leaves of pine on display.

    The leaves of conifers are needle-like and are adapted for dry conditions such as hot summers or freezing winters. Needles lose water slower than broad, flat leaves and therefore do not need to be shed during seasons when water is scarce, so most conifers are evergreen.

    Reproduction in Pine

    Life Cycle of Seed Plants

    Seed plants are heterosporous—they have two different spore sizes: megaspores and microspores.

    The generalized life cycle of plants has been modified (below) to illustrate plants which have separate male and female gametophytes (megagametophyte and microgametophyte) produced by different sized spores (megaspores and microspores).

    Meiosis produces megaspores and microspores. These become megagametophytes and microgametophytes respectively, which then produce eggs and sperm. The eggs undergo fertilization and become a seed. The seed becomes a sporophyte, which then undergoes meiosis. The cycle continues from generation to generation. Generation N is the megagametophyte and microgametophyte and 2N is the sporophyte.

    The evolutionary trend from nonvascular plants to seedless vascular plants to seed plants has been a reduction in the size of the gametophyte. In seed plants, the gametophyte is usually microscopic and is retained within the tissues of the sporophyte.

    The megasporangium is surrounded by layers of sporophyte tissue called the integument. The integument and structures within (megasporangium, megaspore) are the ovule.

    Microspores germinate within the sporophyte tissue and become pollen grains. The microgametophyte is contained within the tough, protective coat of the pollen grain.

    The entire microgametophyte (pollen grain) is transferred to the vicinity of the megagametophyte by a process of pollination. Wind or animals usually accomplish this transfer.

    When pollen reaches the female gametophyte, it produces an elongate structure (pollen tube) that grows to the egg cell. Sperm are transferred directly through this tube to the egg. The advantage of this process is that sperm do not have to swim long distances as they do in seedless plants.

    Seeds

    Seeds contain the sporophyte embryo, food for the embryo, and a protective coat.

    The embryo within the seed is dormant; it can survive for long periods without additional food or water. When conditions become favorable, the embryo resumes growth as the seed germinates.

    1. Draw the life cycle of pine and include the following terms: eggs, embryo, fertilization, megagametophyte, megasporangium, megaspore, meiosis, microgametophyte, microsporangium, microspores, and zygote.
    2. Observe the pine pollen cones on display. Is this structure haploid or diploid?
      Pine pollen cones
    3. View a slide showing a section (l.s.) of a pine pollen cone. Identify the microsporangium. Identify the microgametophytes. What is another name for microgametophyte?
      Pine staminate cone at X 40. There is an arrow pointing to a single pollen grain (microgametophyte). The grain has two "wings" which aid it in being dispersed by the wind.
    4. View a pine seed cone on display. Are there any seeds within the cone?
      seed cone
    5. View a slide showing a longitudinal section of a pine seed cone. Identify the integument, ovule, megasporangium, and megagametophyte. Which of these structures is part of the sporophyte? Which are haploid? Which are diploid?
      Pine seed (ovulate) cone at X 40. The structure within the integument is the ovule. It will become the seed. It contains the megasporangium and megagametophyte.
      Pine Seed Cone at X 40. Eggs will be produced in a specific region in the center of the seed; the cells appear thicker than in other sections of the seed.
    6. View the pine seeds on display. From your drawing of the life cycle of pine, identify the structures that are part of the seed.
      Pine seeds

    Angiosperms

    Create another diagram of the life cycle of seed plants that includes the following terms: eggs, embryo, fertilization, megagametophyte, megasporangium, megaspore, meiosis, microgametophyte, microsporangium, microspores, and zygote. This diagram will be used as a reference when viewing the reproductive structures of angiosperms.

    Flower Parts

    1. Obtain a monocot flower such as lily and identify the following structures: anther, filament, stamen, stigma, style, ovary, pistil, petals, sepals. State the function of each of these structures.
      Photograph of a lily. The anther, filament, stigma, and style are labeled. There are several filaments all surrounding the style, which is thicker than the filaments. The anthers produce pollen and form a T on top of the filaments. The stigma sits atop the style.
    2. Remove the petals, stamens and pistil.
      A flower has been dismantled. The stamens and pistil of a flower lay on a table. The stamen consists of a filament and an anther. The pistil consists of the stigma, the style, and the ovary at the bottom, just above the stem.
    3. How many petals are present? How many sepals? Is lily a monocot or a eudicot? List three characteristics that can be used to distinguish between monocots and eudicots.

    Within the Ovary

    1. Use a scalpel to cut a thin cross section slice from the ovary. This can be done by cutting across the ovary and then slicing a thin section next to the first cut. Use a dissecting microscope to determine the number of carpels within the ovary. Identify the ovules. Which structures on the life cycle diagram are found within the ovules?
      Cross section of a lily ovary at X 40. The ovary is a sort of three-leafed clover shape. Within each "leaf" there are two ovules.
    2. View a prepared slide of a lily mature female gametophyte. Identify the megagametophyte, Find the megagametophyte on the life cycle diagram. Try to find an egg and polar nuclei.
      Egg, Micropyle, and the Polar nucleus.

    The photograph below shows a megaspore mother cell. It will divide by meiosis to produce megaspores.

    Within the Anther

    1. Use a scalpel to cut a thin cross-section of a lily anther and view it under a dissecting microscope. Identify the microsporangium. Are pollen grains visible? What structures on the life cycle diagram are contained within the anther?
      Meiosis occurs within the anther to produce microspores. Microspores undergo mitosis to produce microgametophytes (pollen grains).
    2. If you were unable to get a good view of a lily anther in the dissection above, view a prepared slide of a lily anther c.s. and identify the microsporangium and pollen grains. Find where these two structures are located on your life cycle diagram.
      Cross section of a lily anther at X 40. The Microsporangium labeled.
    3. View a slide of lily pollen. identify the two nuclei.
      lilypollen
    4. View slides of germinated pollen. Note the three nuclei within the pollen tubes. One is a tube nucleus. It directs the growth of the pollen tube. The other two are sperm.

    After Fertilization: Embryonic Development

    1. View a slide of a Capsella early embryo. Identify the suspensor and cotyledons. Is Capsella a monocot or a eudicot?
      Sheperd's purse capsella embryo at X 100.
    2. View a slide of a Capsella mature embryo. Identify the cotyledons, the tip of the growing root (root apical meristem) and the tip of the growing shoot (shoot apical meristem).
      Sheperd's purse capsella embryo at X 100.
    3. Obtain a bean seed that has been soaking in water. Cut the seed in half so that each cotyledon is visible and examine it using a dissecting microscope. Identify the embryo.
      Bean cut in half. The Plumules are along the outer edge of the bean. The cotyledons are in the center.
    4. Obtain a corn that has been soaking in water and cut it lengthwise. Use a dissecting microscope to identify the embryo, the cotyledon, and the endosperm.
      Corn seed showing embryo, cotyledon, and endosperm
    5. Observe beans and corn on display that have been recently germinated. Identify the cotyledons on the beans. Can you see cotyledons on the corn? Can you identify the coleoptile?
      Eudicot (bean) and monocot (corn) seedlings. Bean (left) is a eudicot. Notice that the two cotyledons are still attached just below the leaves. Corn (right) is a monocot. The coleoptile is a protective leaf that wraps around the shoot of a germinating monocot seed.
      Corn Germination
      beangermination

    Fruits

    Angiosperms are distinguished from Gymnosperms in that the seeds are enclosed in a covering called the fruit.

    Observe peas. Peas are seeds contained within a pod (fruit).

    Peas

    Observe the sliced tomato. It is produced from several fused carpels. Can you see the carpels? How many are there?

    Tomato showing fused carpels

    Observe a strawberry or a blackberry. These fruits are formed from a single flower that contained many pistals.

    Blackberry

    Observe a pineapple. This fruit is produced by the fusion of many flowers. Can you see each individual fruit?

    Three views of a pineapple; the view get closer to the fruit.


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    This page titled Reading: Seed Plants is shared under a CC BY license and was authored, remixed, and/or curated by Lynette Hauser.

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