1. Growth & Reproduction in Plants 18. 4 – 18.8

2. Flowers have several roles in plant reproduction.

3. 18.4 The flower is the chief structure for sexual reproduction

5. Sepals leaf-like structures located at point where flower is connected to main support structure grow in a ring around outside of flower surround and protect flower bud during development usually green but some flowers are brightly colored and closely resemble flower’s petals

6. 18.4 The flower is the chief structure for sexual reproduction Petals usually brightly colored helps flower attract pollinators long and thin  short and broad

7. 18.4 The flower is the chief structure for sexual reproduction Stamens male reproductive parts filament: long, thin stalk anther: head-like top where pollen grains are produced

9. 18.4 The flower is the chief structure for sexual reproduction Carpel female reproductive structure stigma ◦flat, sticky surface at top of carpel ◦functions as landing pad for pollen style ◦holds the stigma high out of the center of the flower ◦long thin structure that leads down to the ovary ovules ◦produce female gametes (eggs) ◦after egg is fertilized, ovule develops into a seed

10. 18.4 The flower is the chief structure for sexual reproduction

12. Take-home message 18.4 Flowers are plant structures specialized for sexual reproduction. Most flowers have the same fundamental structures: sepals, petals, stamens, and a carpel.

13. 18.5 The male reproductive structure produces pollen grains.

14. spores: haploid cells produced by meiosis in plants microspores: spores produced in anthers megaspores: spores produced in ovules

15. 18.5 The male reproductive structure produces pollen grains. as anther grows, 4 chambers form— sometimes called “spore sacs” each is filled with diploid cells called microspore mother cells

16. 18.5 The male reproductive structure produces pollen grains. microspore mother cells divide by meiosis; each produces 4 haploid microspores. microspores then quickly divide by mitosis  two-cell grain of pollen w/complex, water-tight, sticky surface

17. 18.5 The male reproductive structure produces pollen grains. two-celled structure is the pollen grain containing 2 haploid cells one cell will eventually grow to form a pollen tube, aiding in fertilization. other will divide once to produce two sperm cells.

18. 18.5 The male reproductive structure produces pollen grains.

19. A pollen grain contains two haploid cells. One forms a tube used as a conduit for fertilization. The other cell divides once and forms two sperm cells.

20. 18.5 The male reproductive structure produces pollen grains. The pollen on this nose hair may be flushed from the body by mucus (or a sneeze)! Sometimes the reaction is extreme.

22. Take-home message 18.5 The male reproductive structure produces pollen grains, each grain a two-cell structure that is water-tight and has a sticky surface. One of the cells in the pollen grain will form a pollen tube, and the other will divide to produce two sperm cells.

23. 18.6 Female gametes develop in embryo sacs.

24. Within the ovary 1 or more diploid cells differentiate into ovules each ovule is made of outer protective cells that surround megaspore mother cell (diploid egg-producing cell megaspore mother cell undergoes meiosis to produce haploid megaspores

25. 18.6 Female gametes develop in embryo sacs. Within a flower 1 of haploid megaspores undergoes mitosis several times to produce embryo sac (structure in which fertilization will occur) embryo sac: 7 cells 6 of these cells—including one that is the egg—have haploid nuclei central cell: 7 th cell w/2 distinct haploid nuclei embryo sac waits for male gamete to arrive

26. 18.6 Female gametes develop in embryo sacs.

27. Take-home message 18.6 Within the ovary, diploid cells differentiate into ovules, each of which is a group of outer protective cells around a diploid egg-producing cell, which undergoes meiosis to produce haploid megaspores. One of these megaspores undergoes mitosis several times to produce the embryo sac, the structure that contains the egg and is the place where fertilization will occur.

28. Pollination, fertilization, and seed dispersal often depend on help from other organisms.

29. 18.7 Plants need help getting the male gamete to the female gamete for fertilization. green algae release gametes into water mosses and ferns must rely on the presence of water for transporting male gametes to female gametes, otherwise gametes dry out  mosses and ferns must live in moist habitats or reproduce when moisture is available

31. 18.7 Plants need help getting the male gamete to the female gamete for fertilization. process involves enlisting animals to carry the male gametes plant attracts animal with its flower ◦visual cues (color, shape) ◦olfactory cues (smell) ◦tactile cues (soft, bristly, hard, rough, smooth) pollination: pollen grain from a plant must journey to the stigma of another plant of the same species

32. 18.7 Plants need help getting the male gamete to the female gamete for fertilization. ~10% of plant species achieve pollination by wind (grasses, pine trees) or water (eelgrass) slim chance that—through random luck—some of pollen will land on female reproductive organs of another plant of same species astronomically low probability of any one pollen grain actually doing that  plants respond by producing ~ 10,000,000 pollen grains/plant

34. 18.7 Plants need help getting the male gamete to the female gamete for fertilization. wide variety of pollinators: birds (mostly hummingbirds), bees, flies, beetles, butterflies, moths, and even some mammals (mostly bats) strong coevolution between plants and pollinators ◦plants have become more and more effective at attracting the pollinators and deterring other species from visiting the flower ◦pollinators have become more and more effective at exploiting resources offered by plants

35. Take-home message 18.7 Plants usually utilize trickery or bribery to get the assistance of animals in carrying the male gametes to the female gametes. There has been strong coevolution between plants and their animal pollinators.

36. 18.8 18.8 Fertilization occurs after pollination. pollination brings male and female gametes close to each other, but it isn’t quite fertilization fertilization requires that male and female gametes fuse so that genetic material can be combined

38. 18.8 18.8 Fertilization occurs after pollination. Within 12 to 36 hours of pollen landing on stigma 1 cell in pollen grain starts to grow into a pollen tube by an elongation of tube cell (not mitosis) stretches and pushes through stigma takes sperm-producing cell farther and farther down style toward ovary

39. 18.8 18.8 Fertilization occurs after pollination. cells within the style, which is part of the female reproductive structure (the carpel), test the tube cell to check whether it is too closely related to the plant on which the pollen has landed (as it would be if the plant self-pollinated). If the tube cell is too closely related, it is killed—often by a chemical reaction initiated by the cells of the style, breaking down the cytoskeleton of the pollen tube. If it is not too closely related, the pollen tube is allowed to continue growing toward the ovary.