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Plants without Seeds: From Water to Land

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Title: Plants without Seeds: From Water to Land


1
Plants without Seeds From Water to Land
2
28 Plants without Seeds From Water to Land
  • 28.1 How Did the Land Plants Arise?
  • 28.2 How Did Plants Colonize and Thrive on Land?
  • 28.3 What Features Distinguish the Vascular
    Plants?
  • 29.4 What Are the Major Clades of Seedless
    Plants?

3
28.1 How Did the Land Plants Arise?
  • Land plants are monophyletic, all descend from a
    single common ancestor.
  • One synapomorphy Development from an embryo
    protected by tissues of the parent plant.
  • Also called embryophytes.

4
28.1 How Did the Land Plants Arise?
  • Land plants retain derived features they share
    with green algae
  • Chlorophyll a and b
  • Starch as a storage product
  • Cellulose in cell walls

5
Figure 28.1 What Is a Plant?
6
28.1 How Did the Land Plants Arise?
  • Plants can be defined in several ways
  • Streptophytes include land plants and closely
    related green algae
  • Green plantsstreptophytes plus all other green
    algae. All have chlorophyll b

7
28.1 How Did the Land Plants Arise?
  • There are ten major clades of land plants.
  • Vascular plants, or tracheophytes (seven
    clades)all have conducting cells called
    tracheids.
  • The seven groups of vascular plants constitute a
    clade.

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9
28.1 How Did the Land Plants Arise?
  • Nonvascular land plants The remaining three
    cladesliverworts, hornworts, and mosses.
  • These groups do not form a clade.

10
28.1 How Did the Land Plants Arise?
  • The closest relatives of the land plants are the
    Coleochaetales and the Charales.
  • Both retain eggs in the parental organism, as do
    land plants.

11
28.1 How Did the Land Plants Arise?
  • Charales is thought to be the sister group of
    land plants based on synapomorphies
  • Plasmodesmata
  • Branching, apical growth
  • Similar peroxisome contents, mechanics of mitosis
    and cytokinesis, and chloroplast structure

12
Figure 28.2 The Closest Relatives of Land Plants
13
28.2 How Did Plants Colonize and Thrive on Land?
  • Plants first appeared on land between 400 and 500
    million years ago.
  • Adaptations were needed to survive in a dry
    environment.
  • Large plants needed a way to transport water to
    all parts of the plant.
  • They also needed structural support and methods
    to disperse gametes.

14
28.2 How Did Plants Colonize and Thrive on Land?
  • Characteristics of land plants
  • The cuticlewaxy covering that retards water loss
  • Stomataopenings in stems and leaves regulate
    gas exchange (except liverworts)
  • Gametangia enclosing gametes

15
28.2 How Did Plants Colonize and Thrive on Land?
  • Embryos in a protective structure
  • Pigments that protect against UV radiation
  • Spore walls containing sporopolleninprotects
    from dessication and decay
  • Mutualistic relationships with fungi that promote
    nutrient uptake from soil

16
28.2 How Did Plants Colonize and Thrive on Land?
  • Ancient plants contributed to soil formation.
  • Acids secreted by plants help break down rock.
  • Organic material from dead plants contributes to
    soil structure.

17
28.2 How Did Plants Colonize and Thrive on Land?
  • Nonvascular land plants (liverworts, mosses, and
    hornworts) are thought to be similar to the first
    land plants.
  • They have only a thin cuticle and grow in moist
    environments in dense mats.
  • They are small, there is no system to conduct
    water from soil to plant body parts.

18
28.2 How Did Plants Colonize and Thrive on Land?
  • The growth pattern of nonvascular plants allows
    water to move through mats by capillary action.
  • Minerals can be distributed through the small
    plants by diffusion.

19
28.2 How Did Plants Colonize and Thrive on Land?
  • Many can grow on marginal surfaces, including
    tree trunks, rocks, even buildings.
  • This ability results from a mutualistic
    relationship with fungi called glomeromycetes.
  • The earliest plants were colonized with these
    fungithey promote absorption of water and
    minerals.

20
28.2 How Did Plants Colonize and Thrive on Land?
  • All land plants have a life cycle with
    alternation of generations.
  • Includes multicellular diploid and multicellular
    haploid stages
  • Gametes are produced by mitosis. Meiosis produces
    spores that develop into haploid organisms

21
Figure 28.3 Alternation of Generations in Plants
22
28.2 How Did Plants Colonize and Thrive on Land?
  • The multicellular diploid plant is the sporophyte
    (spore plant).
  • Cells in sporangia undergo meiosis to produce
    haploid, unicellular spores.
  • Spores develop into a multicellular haploid
    plantthe gametophyte (gamete plant).

23
28.2 How Did Plants Colonize and Thrive on Land?
  • Gametophytes produce haploid gametes by mitosis.
  • Fusion of gametes (syngamy, or fertilization)
    results in a diploid zygote.
  • The zygote develops into the multicellular
    sporophyte.

24
28.2 How Did Plants Colonize and Thrive on Land?
  • There is a trend toward reduction of the
    gametophyte generation in plant evolution.
  • In nonvascular plants the gametophyte is larger,
    longer-lived, and more self-sufficient than the
    sporophyte.
  • In plants that appeared later, this is reversed.

25
28.2 How Did Plants Colonize and Thrive on Land?
  • In nonvascular plants, the gametophyte generation
    is the familiar, photosynthetic form.
  • The sporophyte may or may not be photosynthetic,
    but is always nutritionally dependent on the
    gametophyte, and is permanently attached.

26
Figure 28.4 A Moss Life Cycle (Part 1)
27
28.2 How Did Plants Colonize and Thrive on Land?
  • The haploid gametophyte produces gametes in
    specialized sex organs called gametangia.
  • Female Archegoniumproduces one egg.
  • Male Antheridiumproduces many sperm with two
    flagella each.

28
Figure 28.4 A Moss Life Cycle (Part 2)
29
28.2 How Did Plants Colonize and Thrive on Land?
  • Sperm must swim to archegonium, or be carried
    there by raindrop splashes.
  • Egg or archegonium releases chemical attractants
    for sperm.
  • Cells in archegonium break down to form a
    water-filled canal through which sperm travel.
  • Water is required for all these events.

30
28.2 How Did Plants Colonize and Thrive on Land?
  • Egg and sperm form a diploid zygote.
  • Zygote develops into a multicellular, diploid
    sporophyte embryo.
  • Base of archegonium grows to protect embryo
    during early development.
  • Sporophyte remains attached to gametophyte by the
    foot.

31
28.3 What Features Distinguish the Vascular
Plants?
  • Vascular plants include the club mosses, ferns,
    conifers, and angiosperms (flowering plants).
  • The vascular system consists of tissue
    specialized for the transport of materials.
  • Xylem conducts water and minerals from soil up to
    the rest of the plant.

32
28.3 What Features Distinguish the Vascular
Plants?
  • Some xylem cell walls have lignin, which also
    provides support.
  • Phloem conducts products of photosynthesis
    throughout the plant.

33
28.3 What Features Distinguish the Vascular
Plants?
  • A single event probably launched the vascular
    plants
  • In the mid-Silurian (430 Mya), the sporophyte
    generation of a now extinct plant produced a new
    cell type, the tracheid.
  • Tracheids are the principal water-conducting
    elements of xylem in all vascular plants.

34
28.3 What Features Distinguish the Vascular
Plants?
  • Evolution of tracheids had two important
    consequences
  • Transport of water and minerals
  • Rigid structural supportallows plants to grow
    tall and compete for light, and aid in spore
    dispersal
  • Tracheids set the stage for the invasion of land

35
28.3 What Features Distinguish the Vascular
Plants?
  • Vascular plants also have a branching,
    independent sporophyte.
  • A branching sporophyte can produce more spores
    and develop in complex ways.
  • Mature sporophyte is nutritionally independent
    from the gametophyte.

36
Figure 28.5 The Evolution of Plants
37
28.3 What Features Distinguish the Vascular
Plants?
  • First vascular plants were successful on land
    because of the cuticle and protective layers for
    the gametangia, and because of the absence of
    herbivores.
  • First fossils are from the Silurian. They made
    land more hospitable for animalsamphibians and
    insects arrived soon after plants.

38
Ch. 28 Opener 1 Making It on Land
39
28.3 What Features Distinguish the Vascular
Plants?
  • Trees appeared during the Devonian. In the
    Carboniferous period (359297 Mya), forests of
    lycophytes (club mosses), horsetails, and tree
    ferns flourished in tropical swamps.
  • Plant parts were buried in the swamps, and over
    millions of years, high pressure and temperature
    transformed them into coal.

40
Figure 28.6 Reconstruction of an Ancient Forest
41
28.3 What Features Distinguish the Vascular
Plants?
  • During the Permian, the continents came together
    to form Pangaea.
  • Extensive glaciation occurred late in the
    Permian.
  • Lycophytefern forests were replaced by
    gymnosperms.
  • A different group of seed plants (angiosperms)
    overtook the landscape about 65 million years ago.

42
28.3 What Features Distinguish the Vascular
Plants?
  • Earliest vascular plants (now extinct)
  • Rhyniophytes (Silurian) had a simple vascular
    system and dichotomous branching, but lacked
    leaves and roots.
  • They were anchored by rhizomes (horizontal
    portions of stem) and rhizoids (water-absorbing
    filaments).

43
Figure 28.7 An Ancient Vascular Plant Relative
44
28.3 What Features Distinguish the Vascular
Plants?
  • Lycophytes (club mosses) first appeared in the
    Silurian.
  • Monilophytes (ferns and fern allies) appeared in
    the Devonian.
  • These groups had true roots and leaves, and two
    types of spores.

45
28.3 What Features Distinguish the Vascular
Plants?
  • Monilophytes and seed plants form a clade called
    euphyllophytes.
  • Synapomorphies include overtopping growthnew
    branches grow beyond the othersan advantage in
    the competition for light.

46
28.3 What Features Distinguish the Vascular
Plants?
  • Roots probably originated from a rhizome or stem.
    Fossil evidence supports this hypothesis.
  • Underground and aboveground stems would be
    subjected to very different selection pressures,
    and the two have evolved distinctive structures.

47
28.3 What Features Distinguish the Vascular
Plants?
  • Leaf A flattened photosynthetic structure
    arising from a stem or branch has true vascular
    tissue
  • Microphyllssmall, one vascular strand
    (lycophytes). May have originated as sterile
    sporangia
  • Megaphyllslarger, more complex (monilophytes and
    seed plants)

48
Figure 28.8 The Evolution of Leaves (A)
49
28.3 What Features Distinguish the Vascular
Plants?
  • Megaphylls may have arisen from reduced and
    flattened branching stems.
  • Flat plates of photosynthetic tissue developed
    between branches, and the end branches became the
    leaf veins.
  • Advantage Increased photosynthetic surface area.

50
Figure 28.8 The Evolution of Leaves (B)
51
28.3 What Features Distinguish the Vascular
Plants?
  • Small megaphylls first appeared in the Devonian.
    Large megaphylls did not appear until the
    Carboniferous.
  • One theory High CO2 concentrations in the
    Devonian reduced selection for stomata. Fewer
    stomata were needed to take up CO2.

52
28.3 What Features Distinguish the Vascular
Plants?
  • Stomata also allow heat to be lost by the
    evaporation of water.
  • If megaphylls had grown large during this time,
    with few stomata, it would have resulted in
    overheating.

53
Figure 28.9 CO2 Levels and the Evolution of
Megaphylls (Part 1)
54
Figure 28.9 CO2 Levels and the Evolution of
Megaphylls (Part 2)
55
28.3 What Features Distinguish the Vascular
Plants?
  • The most ancient vascular plants were
    homosporousa single type of spore.
  • The spores produce one type of gametophyte that
    has both archegonium and antheridium.

56
Figure 28.10 Homospory and Heterospory (Part 1)
57
28.3 What Features Distinguish the Vascular
Plants?
  • Heterosporous plants produce two types of spores
  • Megaspore develops into female gametophytethe
    megagametophyte, which produces only eggs
  • Microspore develops into male gametophytethe
    microgametophyte, produces only sperm

58
Figure 28.10 Homospory and Heterospory (Part 2)
59
28.3 What Features Distinguish the Vascular
Plants?
  • Megaspores are produced in small numbers in
    megasporangia.
  • Microspores are produced in large numbers in
    microsporangia.
  • Heterospory evolved several times.

60
28.4 What Are the Major Clades of Seedless Plants?
  • Liverworts Hepatophyta9,000 species.
  • Some have leafy gametophytes some have thalloid
    gametophytes.
  • Sporophytes are
  • very short, only
  • a few mm.

61
Figure 28.11 Liverwort Structures
62
28.4 What Are the Major Clades of Seedless Plants?
  • A stalk raises the simple sporangium above ground
    level to allow spores to be dispersed.
  • Liverworts also reproduce asexually
  • By simple fragmentation of the gametophyte
  • And by gemmaelens-shaped clumps of cells in
    gemmae cups. Gemmae are dispersed by raindrops.

63
28.4 What Are the Major Clades of Seedless Plants?
  • The mosses Bryophyta15,000 species.
  • Mosses (plus hornworts and vascular plants) have
    stomata,
  • important in water
  • and gas exchange.

64
Figure 28.12 Mosses Grow in Dense Mats
65
28.4 What Are the Major Clades of Seedless Plants?
  • Moss gametophytes begin as branched, filamentous
    structuresthe protonema.
  • Some filaments are photosynthetic, others are
    rhizoids that anchor the protonema.
  • Tips of photosynthetic filaments form buds which
    produce the leafy moss shoots.

66
Figure 28.4 A Moss Life Cycle (Part 1)
67
28.4 What Are the Major Clades of Seedless Plants?
  • Some moss gametophytes are too large to depend on
    diffusion for water transport.
  • Cells called hydroids die and provide channels
    through which water can travel.
  • Hydroids are functionally similar to tracheids.

68
28.4 What Are the Major Clades of Seedless Plants?
  • Sphagnum moss grows in cool, swampy places.
  • The upper layers of moss compress lower layers
    that are beginning to decompose, forming peat
    which can be used as a fuel.
  • Long ago, continued compression of peat led to
    the formation of coal.

69
Figure 28.13 Sphagnum Moss
70
28.4 What Are the Major Clades of Seedless Plants?
  • Hornworts Anthocerophyta100 species.
  • Gametophytes are flat plates of cells.

71
28.4 What Are the Major Clades of Seedless Plants?
  • Hornwort cells have a single, large chloroplast.
  • The sporophyte has no stalk but has a basal
    region capable of indefinite cell division.
    Sporophytes can grow up to 20 cm.
  • Hornworts have internal cavities filled with
    nitrogen-fixing cyanobacteria.

72
Figure 28.14 A Hornwort
73
28.4 What Are the Major Clades of Seedless Plants?
  • The exact evolutionary position of the hornworts
    is still unclear.
  • In some morphological analyses they are placed as
    the sister group to the mosses plus the vascular
    plants (the two groups that express apical cell
    division).

74
28.4 What Are the Major Clades of Seedless Plants?
  • In the seedless vascular plants, the large
    sporophyte is independent of the small,
    short-lived gametophyte.
  • The single-celled spore is a resting stage.
  • Must have water for at least one part of the life
    cyclefor the flagellated, swimming sperm.

75
28.4 What Are the Major Clades of Seedless Plants?
  • The lycophytes Club mosses, spike mosses, and
    quillworts 1,200 species.
  • Roots branch dichotomously leaves are
    microphylls.

76
28.4 What Are the Major Clades of Seedless Plants?
  • Some club mosses have sporangia arranged in
    clusters called strobili.
  • Others have sporangia on upper surfaces of leaves
    called sporophylls.

77
Figure 28.15 Club Mosses
78
28.4 What Are the Major Clades of Seedless Plants?
  • Lycophytes were dominant during the Carboniferous
    period.
  • One type of coalcannel coalis formed almost
    entirely from the spores of a tree lycophyte
    Lepidodendron.

79
28.4 What Are the Major Clades of Seedless Plants?
  • The monilophytesHorsetails, whisk ferns, and
    ferns, form a clade.
  • Horsetails and whisk ferns are both monophyletic,
    ferns are not.

80
28.4 What Are the Major Clades of Seedless Plants?
  • Horsetails 15 species in one genusEquisetum.
  • Silica in cell wallsscouring rushes.
  • Have true roots sporangia are on short stalks
    called sporangiophore.
  • Leaves are reduced megaphylls in whorls. Each
    stem segment grows from the base.

81
Figure 28.16 Horsetails
82
28.4 What Are the Major Clades of Seedless Plants?
  • Whisk ferns 15 species in two genera.
  • No roots but well-developed vascular system.
  • Psilotum has scales instead of leaves.
  • Tmesipteris has flattened, reduced megaphylls.

83
Figure 28.17 A Whisk Fern
84
28.4 What Are the Major Clades of Seedless Plants?
  • Whisk ferns were once thought to be descendents
    of rhyniophytes.
  • DNA analysis determined a more modern origin.
    Evolved from more complex ancestors by reduction
    or loss of megaphylls and true roots.

85
28.4 What Are the Major Clades of Seedless Plants?
  • Leptosporangiate ferns 12,000 species. Most
    ferns belong to this clade. Sporangia walls are
    only one cell thick, borne on a stalk.
  • Sporophytes have true roots, stems, and leaves.
  • Fern leaf starts development as a coiled
    fiddlehead.

86
Figure 28.18 Fern Leaves Take Many Forms
87
28.4 What Are the Major Clades of Seedless Plants?
  • Fern life cycle
  • Spore mother cells in sporangia form haploid
    spores by meiosis.
  • Spores can be blown by wind and develop into a
    gametophyte far from parent plant.

88
28.4 What Are the Major Clades of Seedless Plants?
  • Fern gametophytes produce antheridia and
    archegonia, not always at the same time or on the
    same gametophyte.
  • Sperm swim through water to an archegonium to
    fertilize egg.
  • Zygote develops into independent sporophyte.

89
Figure 28.19 The Life Cycle of a Homosporous Fern
90
28.4 What Are the Major Clades of Seedless Plants?
  • Most ferns are in shaded, moist environments
    because water is required for swimming sperm.
  • Tree ferns can reach heights of 20 m.
  • Sporangia occur on undersides of leaves in
    clusters called sori.

91
28.4 What Are the Major Clades of Seedless Plants?
  • Most ferns are homosporous two groups of aquatic
    ferns are heterosporous.
  • Some genera have a tuberous gametophyte that
    depends on a mutualistic fungus for nutrition.
  • In some genera, even the sporophyte embryo must
    be associated with the fungus before development
    can proceed.

92
28.4 What Are the Major Clades of Seedless Plants?
  • DNA research suggests that diversification of
    modern ferns is fairly recent.
  • Ferns may have taken advantage of shady
    environments created by the expansion of seed
    plant forests.
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