1 / 22

Life Cycles: Meiosis and the Alternation of Generations

Life Cycles: Meiosis and the Alternation of Generations. Chapter 12. Life Cycles. Transfer of genetic information from parent to offspring Two types of reproduction Asexual reproduction Sexual reproduction. Alternation of Generations. Refers to creation of both diploid and haploid bodies

card
Download Presentation

Life Cycles: Meiosis and the Alternation of Generations

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. Life Cycles: Meiosis and the Alternation of Generations Chapter 12

  2. Life Cycles • Transfer of genetic information from parent to offspring • Two types of reproduction • Asexual reproduction • Sexual reproduction

  3. Alternation of Generations • Refers to creation of both diploid and haploid bodies • Cherry tree life cycle • Cherry tree • Diploid part of life cycle • Referred to as sporophyte • Makes reproductive units called spores • Spores – one celled reproductive unit that can develop into new plant without mating with another organism

  4. Alternation of Generations • Forms two kinds of spores • One kind develops into male haploid plant that makes gametes called sperm cells • Other kind develops into female haploid plant that makes a gamete called an egg

  5. Alternation of Generations • Male gametophyte formation occurs in pollen sacs of anthers • Meiospores (produced by meiosis) divide by mitosis to form male gametophyte → pollen grain • Pollen grains released from anther • Pollen reaches stigma of female flower part • Pollen grain grows pollen tube • Contains two sperm nuclei (male gametophyte is now mature)

  6. Alternation of Generations • Female gametophyte formation occurs in ovary • Chambers of ovary lined with ovules • Single ovule undergoes meiosis, produces 4 haploid cells • 3 of the 4 cells degenerate • 1 remaining cell matures into female spore (meiospore) • Meiospore remains in ovule where it divides by mitosis • Resulting cells divide 2 more times by mitosis to make a 7-celled female gametophyte

  7. Alternation of Generations • Pollination • Transfer of pollen to tip of pistil • Pollen tube reaches egg • One sperm fuses with egg to form zygote • Plasmogamy → fusion of cytoplasmic contents • Karyogamy → fusion of nuclei • Other sperm fuses with polar nuclei to form endosperm

  8. Alternation of Generations • Zygote divides mitotically • Forms embryo within seed coat • Small sporophyte that will become cherry tree when seed germinates

  9. Embryophytes • Embryophytes • Plants that shelter their offspring as embryos within parental body

  10. Sexual Cycles • Sexual reproductive cycles can be of two types • Heterosporic • Makes two kinds of spores and gametophytes • One spore produced in large numbers • Small enough to be carried far away • One spore too heavy to travel • Contains plenty of food

  11. Sexual Cycles • Homosporic • Makes one kind of spore and gametophyte • Spores too small to travel far • Most mosses and plants such as ferns • Plants not important in our food supply except as emergency foods

  12. Heterospory Makes 2 kinds of spores and gametophytes 1 spore produced in large numbers and small enough to be carried far away, other spore too heavy to travel far but contains plenty of food Seeds produced are part of our basic food supply Homospory Makes 1 kind of spore and gametophyte Spores too small to travel far Only important in human food supply as emergency food Comparison of Heterospory and Homospory

  13. Types of Life Cycles • Zygotic or gametic life cycle • Life cycle that lacks sporophyte • No multicellular 2n stage • Example: Chlamydomonas (green alga) • Sporic life cycle • Life cycle that includes alternating sporophyte and gametophyte bodies • All embryophytes, mosses

  14. Zygotic of Gametic Life Cycle • Gametophytes • Single, motile cells with haploid nucleus • Genetically exist as plus or minus mating types • Gametophyte nucleus occasionally undergoes mitosis and produces haploid spores • Parent cell bursts • Releases spores that develop into new gametophyte generation cell

  15. Zygotic of Gametic Life Cycle • Plus and minus mating types can mate • Plasmogamy and karyogamy occur • Results in 2n zygote • Zygote eventually undergoes meiosis • Releases haploid cells • Each cell matures into either a plus or minus gametophyte generation cell

  16. Gametic Life Cycle • Example: Fucus (brown alga) • Begins with multicellular sporophyte • Large and complex • Within body cavities of sporophyte • Cells enlarge, become sporangia, nuclei of cells undergo meiosis • 1 type of sporangium produces large meiospores • Other type of sporangium produces small meiospores

  17. Gametic Life Cycle • Large meiospore differentiates into female gametophyte (egg) • Smaller meiospores differentiate into male gametophytes (sperm) • Gametes released into surf in large numbers • Eggs from one parent and sperm from another parent fuse • Egg and sperm from same plant not attracted to each other

  18. Gametic Life Cycle • Plasmogamy and karyogamy occur • Zygote begins to divide and grows into sporophyte • Sporophyte enlarges, sinks to bottom, attaches to rock, grows into maturity • Only haploid phase is a single-celled gamete • No multicellular gamete generation in a gametic life cycle

  19. Dominant Diploid Generation • Gametic and zygotic life cycles common among algae but absent from any more advanced plants • Sporic life cycles are rule among complex terrestrial plants • Increasing dominance by sporophyte in groups more recent in fossil record

  20. Dominant Diploid Generation • Diploid condition • Permits recessive genes to be carried along from generation to generation • Could be valuable to species future • No recessive genes in haploid cells of gametophytes • Only 1 set of chromosomes • Every gene’s expression shows through in this phase

  21. Dominant Diploid Generation • Dominance • Means sporophyte lives longer, is larger, is more structurally complex, and is more independent than gametophyte

More Related