Plant Evolution & Diversity – Ch. 22-25 Kingdom Protista: Algae & Protozoa • Organisms in this Kingdom don’t fit clearly into what we call plant, animal, or fungi. • Most diverse eukaryotic Kingdom (>60,000 species). • We are interested in this Kingdom because of the Chlorophytes & Charophyceans - green algae. The line between Kingdom Protista and Kingdom Plantae is still being discussed…… Fig 29.4 Origin of Plants Characteristics of Green Algae - Chlorophytes • . • Can live symbiotically with fungi as lichens Fig 28.30 Volvox - freshwater Ulva – sea lettuce Caulerpa - intertidal Characteristics of Green Algae - Charophyceans • • fresh water ponds They are considered to be the closest ancestors of true plants. Evidence: Plants • So how are they different from Charophyceans?? What challenges did plants face when they “moved” onto land? Adaptation to life on Land: 1. . 2. . 3. . 4. Multicellular gametangia 5. Multicellular, dependent embryos 1. Apical Meristems – 2. Alternation of Generations • 2 multicellular life stages: 1. Sporophyte: • Diploid • Divides by meiosis to form spores • Spores – haploid cells that can grow into a new, multicellular, haploid organism (the gametophyte) without fusing to another cell. 2. Gametophyte: • Haploid • Divides by mitosis to form the gametes (egg and sperm) • Egg & sperm fuse to form the diploid zygote, which divides by mitosis to form the sporophyte 3. Spores produced in sporangia • Sporangia = • diploid cells within the sporangia divide by meiosis to form the haploid spores sporocytes 4. Multicellular gametangia • • Gametangia = 2 types of gametangia: 1. Archegonia – 2. Antheridia – • Sperm travel to the egg, fertilizing it within the archegonia. 5. Multicelluar, dependent embryos • Zygote divides by mitosis to become the sporophyte. Other examples of adaptations to life on land: (not all plants have the following): 1. Cuticle – 2. Secondary compounds – 3. Roots – 4. Shoots - stems and leaves to make food. 5. Stomata – openings in the leaf surface to allow gas exchange for photosynthesis and to regulate water loss. More Adaptations 4. . 5. A vascular system that transports food & water from roots to shoots and vice versa. Fig 29.7 Nonvascular Land Plants: Bryophytes • • Earliest land plants 3 Phyla: 1. Hepatophyta – 2. Anthocerophyta – 3. Bryophyta • . • • Peat moss (sphagnum): doesn’t decay rapidly, stores 400 bil tons of carbon Gametophyte is the dominant generation: Moss life cycle Fig 29.8 Phylum Hepatophyta – liverworts Phylum Anthocerophyta – hornworts Phylum bryophyta - mosses Peat bogs – sphagnum moss Fig 29.10 Vascular Plants • Vascular tissue: – Xylem = water & mineral transport – Phloem = food (carbohydrates) transport • . Seedless Vascular Land Plants -Egg & sperm need moist environment to fertilize (similar to bryophytes) Two phyla of seedless vascular plants: 1. Phylum Lycophyta (Club Mosses) - flammable spore clouds - were tree-like in the Carboniferous period Phylum Lycophyta: clubmosses, spikemosses, quillwarts 2. Phylum Pterophyta a) Whisk ferns – b) Horsetails – c) Ferns – produce clusters (sori) of sporangia on underside of leaves (fronds) Phylum Pterophyta: ferns, horsetails, whisk ferns Fig 29.12 Life cycle of a fern Forests of the Carboniferous period (290-360 mil years ago): • Heat + pressure + time ----> coal • Pulled lots of CO2 out of atmosphere, cooling the earth & forming glaciers • Larger species died out when climate became drier Terrestrial Adaptations of Seed Plants 1. Seeds replace spores as main means of dispersal. • Why? 2. Gametophytes became reduced and retained within reproductive tissue of the sporophyte 3. Heterospory – 4. Zygote develops into an embryo packaged with a food supply within a protective seed coat. 5. Pollen & Pollination - freed plants from the requirement of water for fertilization. 1. Seeds replace spores as main means of dispersal. • old way (ferns & mosses) = • new way: the sporophyte RETAINS its spores within the sporangia & the tiny gametophyte develops within the spore. • ovule = • after fertilization, the ovule becomes the seed • seed = sporophyte embryo + food supply (mature ovule tissues) 2. Reduction of the gametophyte: Similar to Fig 30.2 3. Separate male & female gametophytes • Old way: sporangia spores bisexual gametophyte (antheridia sperm, archegonia -> eggs) • New way: • Microsporangia microspores male gametophyte sperm 4. Ovules and seed production • Ovule = • After fertilization, embryo develops, ovule becomes a seed Fig 30.3 5. Pollen & Pollination • Microsporangia microspores male gametophyte sperm • Pollen = • Pollination = • Pollen tube brings sperm to egg within the ovule Two types of seed plants: 1. Gymnosperms •Evolved first •“naked seed” – • 2. Angiosperms •Evolved from gymnosperms Gymnosperms • Four phyla: 1. Ginkophyta – 2. Cycadophyta – 3. Gnetophyta – 4. Coniferophyta – Dominate forests of the N. hemisphere Most are evergreen Needle-shaped leaves to reduce water loss during drought Phylum Cycadophyta Phylum Ginkophyta Phylum Gnetophyta Phylum Coniferophyta Fig 30.6 Angiosperms • One phylum: Anthophyta • 2 classes: monocots & dicots. 1. Monocots 2. Eudicots Evolutionary success of Angiosperms due to: 1. . 2. Flowers – attract pollinators 3. Fruits – many forms for variety of dispersal mechanisms Fig 30.3 Notice the triploid stage! •Each pollen grain (male gametophyte) produces two sperm •Sperm travel down the pollen tube & into the ovule. •Double fertilization – •Ovule matures into the seed – contains sporophyte embryo & endosperm (food). •Ovary (female sporangium tissues) matures into the fruit. Ch. 9: flowers, fruits: Angiosperm Reproduction The parts of a flower are typically attached to the: pedicel – the stalk of a single flower. It attaches the flower to the plant. Flower parts occur in 4 sections: 1. Sepals – 2. Petals – a typically colored or white, delicate structure. Petals function to attract pollinators. 3. Each male flower part is called a stamen. The stamen is composed of: 1. Filament – 2. Anther – a collection of pollen sacs that sits on top of the filament. Each female part is called a pistil. Pistil = the female reproductive organ, consisting of: 1. Stigma – 2. Style – 3. Ovary – the base of the pistil, contains the ovules. (Mature ovules are seeds and mature ovary is the fruit) The Angiosperm Life Cycle • Male gametophyte = • Female gametophyte = embryo sac, develops in the ovule of the ovary. Produces egg Development of Male Gametophyte (Pollen) • • Anther is composed of pollen sacs (sporangium). Each microspore divides by mitosis to make 2 cells: 1. Generative cell – 2. Tube cell – will make pollen tube • The 2 cells enclosed in thick wall => pollen grain Development of the Female Gametophyte (Embryo Sac) • Ovule = female sporangium • Only one megaspore survives and divides by mitosis 3 times to make 8 haploid nuclei. Embryo Sac = female gametophyte Antipodal cells 2 polar nuclei Egg Synergid cells Fig 38.4 Angiosperm Reproduction 1. Pollen grain lands on stigma (= pollination) 2. . 3. . 4. Sperm travel down pollen tube and enter embryo sac 5. Double fertilization – • Egg + sperm zygote • 2 polar nuclei + sperm 3n nucleus that becomes the endosperm Fig 38.6 Double fertilization Maturation • Endosperm begins to divide to form structure that provides nutrients to developing embryo • Ovule is now a seed – dehydrates & becomes dormant (low metabolism, no growth). • Ovary tissues divide & mature into fruit Flowers are diverse……. Complete flower = Incomplete flower = lacks one of the above parts Inflorescence types: Inflorescence = the entire flowering part of a plant 1. Spike = 2. 3. 4. 5. Raceme = single flowers on pedicels along the rachis Panicle = a much-branched inflorescence Solitary flower Many more!! Fruit types Fruit = . *the primary function of a fruit is seed dispersal