Bryophytes Chapter 22 Bryophytes Nearly 25 000 named
Bryophytes Chapter 22
Bryophytes • • Nearly 25, 000 named species Diverse habitats Relatively inconspicuous Ecologically important – – Alter p. H Absorb carbon Regulate nutrient cycling Colonize barren areas • Create soil • Reduce erosion
Bryophytes • Absorb and hold moisture • Intolerant of pollution – Good indicators of air and water quality • Interesting physiological adaptations – Some can survive extended periods of desiccation • Living representatives of ancient lineages of land plants
Bryophytes • Retained characteristics of algal ancestors – Nutritionally independent and complex gametophyte – Chlorophyll a and b, carotenoids, xanthophylls – Swimming sperm with two asymmetrically attached flagella – Chloroplasts with conspicuous grana – Cell walls composed of cellulose and pectin
Bryophytes • Retained characteristics of algal ancestors – Cell division present in charophytes but absent in other green algae
Bryophytes • Problems associated with life on land – Preventing death from drying out – Dispersing spores through air – Avoiding damage from weather and intense solar radiation
Sporophyte Evolution • Steps in evolution of multicellular sporophyte – Meiosis must be delayed in zygote – Zygote must undergo mitotic cell divisions to create multicellular body • Bryophytes nurture sporophyte by embedding it in tissues of gametophyte – Embryo phase retained in all extant land plants – Embryophyte name used to describe whole land plant group
Sporophyte Evolution • Value of first sporophytes which were nurtured by gametophyte – Protected spores from desiccation – Allowed bryophytes to produce more spores • Spores adapted to new environment – Lost flagella – Became coated with weather-resistant wall
Gametophyte Evolution • Multicellular gametangia surrounding gametes – Another innovation of bryophytes – Sperm cells made in globular or club-shaped sacs called antheridia – Eggs produced singly in vase-shaped gametangia called archegonia – Gametangia protect developing gametes
Stomata and Cuticle • • First appear in bryophytes Crucial adaptations to life on land Found in virtually all vascular plants Controversial as to whether bryophytes have stomata on gametophytes • Cuticle – In many bryophytes, cuticle only covers part of plant • Reduces dehydration • May also protect against ultraviolet radiation, fungal infection
Bryophytes • Common name applied to three distinct lineages of plants that lack lignified vascular tissue • Do not form a monophyletic group because vascular plants are descended from them • Three lineages – Hornworts – Liverworts – Mosses
Bryophytes • Not clear how the three lineages are related to each other and to vascular plants • Recent molecular analysis using nucleic acid sequences has revealed hornworts may represent earliest lineage • Also suggests mosses and liverworts are closely related
Bryophytes • Megafossils of bryophytes rare • Bryophyte study supports following hypotheses – Land plants evolved only once from single algal ancestor (charophyte) – First land plants were bryophytes and appeared no later than Ordovician period, about 475 million years ago
Bryophytes – Bryophytes form nonmonophyletic group – Each of three living bryophyte lineages (hornworts, liverworts, mosses) is monophyletic
Hornworts • Relatively simple • Gametophytes produce mucilage inside thallus • Ventral portion of thallus has pores – Nostoc (cyanobacteria) enter through pores, form symbiotic colonies • Nostoc is protected in hornwort gametophyte and fixes atmospheric nitrogen (which the hornwort requires)
Hornworts • Unique sporophyte – Grows continually from meristem at its base • Sporophyte consists of – Foot – Upright sporangium or capsule • Epidermis of sporophytes generally lacks chloroplasts but contains stomata • Mass of sporocytes below chlorenchyma tissue undergo meiosis to produce haploid spores
Hornworts • Sterile tissue in center of sporangium called the columella • Spores released when mature capsule tip splits into two valves • Meristematic region just above foot adds new cells to base of sporangium so more sporocytes are continually produced • If spores reach favorable environment, undergo mitosis, produce new gametophytes
Liverworts • Approximately 9, 000 species • Name comes from – Shape which resembles liver – Early belief that the plants could cure diseases of organs they resembled • Gametophyte generation is prominent phase of life cycle • Usually grow in moist, shady habitats
Liverworts • Gametophytes produce variety of volatile oils (stored in organelle called an oil body) – Give liverworts a distinctive odor – May help prevent herbivory – Some compounds show promise as antibiotics and antitumor agents • Produce simple sporophytes – Stalk called a seta – Capsule splits into four valves and releases all its spores at one time
Liverworts – Elaters • Thickened cells inside capsules • Separate spores and aid in spore dispersal
Liverworts • Thallose liverworts – About 15% of all liverwort species – Gametophytes grow Y-shaped branches by simple forking at growing tip – Degree of branching depends on growing conditions – Pores on upper epidermis serve same function as stomata
Liverworts • Thallose liverworts – Lower thallus cells modified for carbohydrate storage – Rhizoids and sheets of cells (scales) project from lower surface • Increase surface area in contact with substrate • Anchor the thallus
Liverworts • Thallose liverworts – Example: Marchantia • Reproduces asexually by two methods – Fragmentation – Gemmae » Produced in gemmae cups » Mature gemmae scattered away from thallus » Land on suitable environment can develop into gametophyte plant
Liverworts • Thallose liverworts • Sexual reproduction – Antheridiophores » Resemble tiny beach umbrellas » Produce antheridia – Archegoniophores » Resemble tiny palm trees » Produce archegonia – Sporophytes develop under archegoniophores
Liverworts • Leafy Liverworts – Largest group of liverworts (about 85% of liverwort species) – Common in humid climates – Varied environments – Distinguished from mosses by leaf arrangement – Reproduce asexually by gemmae
Liverworts • Leafy Liverworts – Sexual reproduction • Archegonia grow on short, leafy branches – Always terminal on stems where they occur • Antheridia develop in axils of leaves • Sporophytes consist of foot, seta, and sporangium
Mosses • Larger and have wider distributions than liverworts and hornworts • Divided into a number of groups – Granite mosses • Most prominent; grow on rocks in cool climates – Peat mosses • Mainly grow in acidic bogs – “True” or typical mosses • Widest habitat range and most species
Mosses • Moss life cycle • Example: Mnium – Gametophyte has three growth phases • Spore germinates to form branching, filamentous structure called a protonema • Buds form on protonema • Buds grow into upright, branching axes, with small, spirally arranged leaves and rhizoids
Mosses • Moss life cycle – Each protonema can produce many identical leafy gametophytes – As leafy gametophyte grows, cells in stems differentiate, mature into specialized tissues • Epidermal layer surrounding cortex of parenchyma tissue • Some species may have thin cuticle over parts of epidermis • No stomata
Mosses • Stem anatomy – May have central strand of conducting tissue • Could be made up of hydroids – Thin-walled, dead cells that conduct water – Resemble vessels but lack pitting and lignified walls • Some have cells called leptoids – – Resemble sieve cells of vascular plants Surround hydroids Living, but nuclei degenerate Parenchyma cells may assist leptoids (like companion cells)
Mosses • Asexual reproduction – Several methods • Protonema may continue to produce new buds • Leaf tissue placed in wet soil may produce protonemal strands • Rhizoids sometimes produce buds • Gemmae may form on rhizoids, leaves, ends of special stalks, or in gemmae cups
Mosses • Sexual reproduction – Gametangia produced at gametophyte stem tips • Gametangia often separated and held upright by sterile filaments called paraphyses – Antheridia • Release mature sperm when free water is present
Mosses • Sexual reproduction – Archegonium • • • Has long neck Thickened venter region surrounds single egg Neck opens creating canal when egg is mature Egg emits chemical attractant Sperm swim down canal toward egg Sperm fertilizes egg creating diploid zygote
Mosses • Sexual reproduction – Zygote develops into embryo that differentiates into • Foot – Penetrates through venter and into gametophyte stem • Seta – Elongates and raises yet-to-be-formed sporangium above top of gametophyte • Sporangium – Calyptra (protective covering for sporangium) » Necessary for normal growth and differentiation of sporophyte
Mosses • Sexual reproduction – Sporophyte usually contains chlorenchyma and stomata (allows photosynthesis) – Cells inside capsule undergo meiosis, for spores • Granite moss capsules open by slits • Peat moss capsules violently eject spores when dried capsule lids blow off
Mosses • Sexual reproduction • True mosses – Mature capsule forms lid (operculum) – Peristome teeth form below operculum » Sensitive to atmospheric humidity » When air is dry, peristome teeth lift out some of the spores
Mosses • Economic and ecological value – Sphagnum • Most economically important bryophyte • Superior water-holding capacity • Used as wound dressing during World War I – Acidic, sterile tissue acts as antiseptic and an absorbent • Peat – Can be cut in blocks, dried, and burned as fuel for cooking and heating
Bryophytes • Economic and ecological value – Important colonizers of bare rock and sand – May harbor symbiotic nitrogen-fixing cyanobacteria – In tundra, make up as much as 50% of aboveground biomass • Important component of food chain in ecosystem
Mosses • Economic and ecological value – Excellent experimental plants (especially mosses) • • Easy to propagate Grow in small spaces Easy to clone into sexually identical replicates Easy to observe for growth and developmental changes
The Early Tracheophytes Chapter 23
Tracheophytes • First tracheophytes were Rhyniophytes – Found in fossil beds of Rhynie, Scotland – Characteristics • • Small Lacked leaves and roots Dichotomously branching rhizomes with rhizoids attached to them Vertical aerial stems with sporangia at tips (sporophyte phase of life cycle) • Only a few gametophyte fossils have been found • Simple stem anatomy – Evidence of endosymbiotic fungi in stems
Tracheophytes – Rhyniophyte group gave rise to all other land plants • not monophyletic
Tracheophytes • Tracheophyte innovations – Important in colonization of land • Dichotomously branching sporophyte with multiple terminal sporangia • Free-living, nutritionally independent sporophyte that is prominent in the life cycle • Reduced gametophyte • Lignified vascular tissue (xylem) in sporophyte
Relationships Among Early Tracheophytes • Divided into two major clades – Lycophytes – All other tracheophytes • Two major lineages – Seed plants – Monilophytes » Ferns » Horsetails » Whisk ferns
Lycophytes • Line originated in Devonian or Silurian period • Earliest known members called Zosterophyllophyta – Now extinct – Lacked leaves and roots – Unique distinguishing morphological feature • Sporangia attached to stems in lateral rather than terminal position
Lycophytes • Line reached peak of diversity and ecological importance in Coal Age • Produce leaf called a microphyll – Defined by presence of single vascular bundle • Group today consists of three lineages – Lycopodium (and related genera) – Selaginella – Isoetes
Lycophytes • Lycopodium – Familiar as evergreen trailing plants used in making wreaths – Abundant spores • Highly flammable – Once used by magicians and photographers • Used to coat latex items – Gloves and condoms – Spores irritating to skin, so no longer used
Lycophytes • Lycopodium – Lycopodium clavatum • Experimentally shown to have hypoglycemic effects – Stem anatomy • Interconnected strands of xylem with phloem between them • Xylem has tracheids • Phloem contains sieve cells and parenchyma cells • No true endodermis
Lycophytes • Lycopodium – Roots arise at apical shoot meristem and emerge on underside of horizontal stem – Homosporous life cycle • Only one type of spore is made • Gametophytes are bisexual • Sporangia produced on top surface of sporophylls (leaves bearing sporangia) • Sporophylls may be aggregated into strobili (singular, strobilus) which are conelike structures
Lycophytes • Lycopodium – Homosporous life cycle • Haploid spores produced by meiosis inside sporangia • Spores are shed, germinate on ground, develop into gametophytes – Typically long lived, subterranean, require endosymbiotic fungi to survive • Antheridia and archegonia form on surface of gametophyte
Lycophytes • Lycopodium – Homosporous life cycle • Biflagellate sperm liberated from antheridia swim through water to fertilize eggs in archegonia • Resulting zygote develops into embryo • Embryo has – – Short primary root Leaf primordia Shoot apex Well-developed foot • Sporophyte – Initially dependent upon gametophyte, becomes self-sustaining
Lycophytes • Selaginella – Single living genus, Selaginella (spike moss) – Mainly tropical – Several commercially grown as ornamental plants • Selaginella lepidophylla (resurrection plant, rose of Jericho) • Selaginella willdenovii (peacock fern) • Selaginella braunii (treelet spike moss)
Lycophytes • Selaginella – Microphylls often arranged in four rows or ranks • One row of large leaves on either side of stem, two rows of smaller leaves on top side of stem – Stem and leaves resemble miniature cypress branches – All leaves possess ligule on top side • Ligule secretes protective fluids during leaf development
Lycophytes • Selaginella – Rhizophore • • • Organ produced at meristems at branch points Unique to Selaginella Has characteristics of both stem and root Grows downward to soil and gives rise to true roots Can give rise to stem under certain conditions
Lycophytes • Selaginella – Heterosporous life cycle • Sporophytes produce two types of spores – Megaspores produced by megasporangia – Microspores produced by microsporangia • Sporangia located in axil of sporophylls – Always aggregate into strobili
Lycophytes • Selaginella – Heterosporous life cycle • Megasporangia – Filled with diploid megasporocytes – One divides by meiosis to produce four large megaspores – Megaspores divide mitotically to form megagametophyte » When mature, spore wall cracks open » Archegonia develop in cushion of gametophyte tissue
Lycophytes • Selaginella – Heterosporous life cycle • Microsporangia – – Filled with up to several hundred diploid microsporocytes Sporocytes divide by meiosis Produce microspores Microspores divide mitotically to form microgametophyte » Layer of cells inside spore wall forming an antheridium and mass of sperm cells in center
Lycophytes • Selaginella – Heterosporous life cycle – – – Sperm liberated when microspore wall becomes wet Sperm swim toward mature archegonia Union of egg and sperm produces diploid zygote cell Diploid zygote cell divides and differentiates into embryo Embryo does not become dormant, continues to grow into fully mature sporophyte
Lycophytes • Heterospory – Probably evolved in Selaginella – Megagametophyte provides nutrition and protection for zygote, embryo, and young sporophyte – Represents necessary step toward seeds
Lycophytes • Isoetes – Commonly called quillwort or Merlin’s grass – Typically grow submerged in water for part or all of life cycle – Plant body • Lobed cormlike structure that undergoes secondary growth and produces roots • Tuft of microphylls that resemble grass leaves – Microphylls filled with large air chambers, have prominent ligules
Lycophytes • Isoetes – Heterosporous • Sperm are multiflagellate (most other living lycophytes have biflagellate sperm) – Fossil record suggests Isoetes is living member of ancient lepidodendroid group
Monilophytes • Includes all other seedless tracheophytes except lycophytes • Consists predominantly of plants commonly called ferns • Typically herbaceous today – Previously were tree size – Were important members of Coal Age swamp forests
Monilophytes • Secondary growth occurs in different way than in lycophytes • Produce leaf called a megaphyll – More than one vascular strand – Extensive branching in leaf – Vascular strands cause leaf gap (interruption) in xylem of stem where they branch off to enter leaf – Thought to have resulted from modification of branch system
Monilophytes • Whisk ferns – Psilophytes – No known fossil record – Two living genera • Psilotum • Tmesipteris – Restricted to South Pacific and Australia – Grow in tropical or subtropical regions, often as epiphytes
Monilophytes • Whisk ferns – Psilotum • Lacks roots • Has dichotomously branched rhizome system covered with rhizoids – Cortex cells of rhizome infected with mycorrhizal fungi • Aerial stems that bare enations – – Have pith with fibers, surrounded by cylinder of xylem Endodermis with Casparian strip Cortex Epidermis with thick cuticle and many stomata
Monilophytes • Whisk ferns – Psilotum • Homosporous • Gametophytes lack chlorophyll and associate with endomycorrhizal fungi – Tmesipteris • Epiphyte with dangling branches • Lacks roots but has leaves
Monilophytes • Ophioglossalean ferns – Closest relative of psilophytes – Group of about 75 species • Genera – Botrychium (grape fern) – Ophioglossum (adder’s tongue fern) » Has the greatest number of chromosomes of any plant » 2 n being as high as 1, 260 in some species
Monilophytes • Ophioglossalean ferns – Unusual leaves divided into two segments • Spikelike fertile segment with sporangium embedded in it • Sterile segment expanded for photosynthesis – Leaves not coiled when young – Stems upright rather than horizontal
Monilophytes • Ophioglossalean ferns – Roots run horizontally through soil and produce shoot buds at intervals • Strong mycorrhizal relationships • Lack root hairs
Monilophytes • Horsetails – Sphenophytes – Only one living genus, Equisetum – Worldwide distribution except for Australia and New Zealand – Contains silica in stem epidermis • In pioneer days, stem was used to scrub pots and pans • Commonly called scouring rush
Monilophytes • Horsetails – Some may be toxic to humans and livestock • Contain enzymes that break down thiamine – Medicinal uses • Treat urinary and kidney problems • Reduce bleeding – Originated in Devonian period • Were important members of Coal Age swamp forests
Monilophytes • Horsetails – Sporophytes easily recognized by jointed and ribbed stems, whorled appendages – Stem anatomy • Large central cavity surrounded by ring of vascular bundles and smaller cavities called vallecular canals • Smaller canals called carinal canals in center of each vascular bundle • Stems are hollow except at nodes
Monilophytes • Horsetails – Sporangia are produced in strobili on structures called sporangiophores – Homosporous (produces one kind of spore) • Spores are green, thin-walled, with long, ribbon-like elaters attached to spore wall • Elaters coil and uncoil in response to humidity – Help disperse spores when sporangium splits open at maturity
Monilophytes • Marattialean ferns – Similar in appearance to true ferns • Compound leaves (fronds) that are coiled when young – Have upright stems and distinctive sporangium – Largely tropical – Extensive fossil record • Important element in Coal Age swamp forest flora
Monilophytes • True ferns – Make up majority of living monilophytes – At least 12, 000 species known – Unique feature of true ferns leptosporangium • Originate from single cell in leaf • Strip of thick-walled cells called annulus flicks spores out of sporangium • Grouped in clusters called sori (may be protected by structure called an indusium or by edge of leaf curling over them)
Monilophytes • True ferns – Pteridium aquilinum, most widespread plant on Earth – Fossil record extending back to Devonian period – Important members of coal swamp flora during Carboniferous period
Monilophytes • True ferns – Sporophyte • Typically grow from underground perennial rhizome • Roots and leaves arise from nodes – Young leaves form coiled fiddleheads • Leaf structure – Well-developed epidermis with stomata – Mesophyll may be differentiated into palisade and spongy layers – Secondary and tertiary leaflets (pinnae and pinnules) develop on petiole extension called a rachis
Monilophytes • True ferns – Sexual reproduction • Sporophyte matures in 1 to 10 years • Sporangia develop • Temperate zones – Spores released in fall • Tropics – Released any month of the year • Spores of many species require light for germination
Monilophytes • True ferns – Sexual reproduction • Germinating spore produces (usually) heartshaped thallus • Rhizoids on lower surface anchor thallus • Archegonia and antheridia develop • Archegonia produces attractant that guides sperm toward them • When egg is fertilized, plasma membrane of egg changes so no other sperm can penetrate
Monilophytes • True ferns – Sexual reproduction • Diploid zygote cell develops into embryo • Embryo has foot, shoot, and root regions • Usually one or two zygotes will mature into embryos on one gametophyte • Embryo develops into sporophyte and becomes nutritionally independent of gametophyte
Monilophytes • True ferns – Alternative means of reproduction • Miniature plantlets can form on mature leaves, break off, grow into new plants • Walking ferns form new plants when tip of frond touches soil • Gametophytes can also reproduce vegetatively • Apospory reproduction without spores – Produce diploid gametophytes directly out of sporophyte tissue (usually leaf tissue) • Apogamy reproduction without gametes – Gametophytes produce sporophytes without any fusion of gametes
Monilophytes • Ferns – Ecological and economic importance of ferns • Provide bulk of biomass in some tropical forests • Dominate understories of some temperate conifer forests • Some are weeds smother vegetation, clog waterways, poison livestock – Lygodium (climbing fern) – Pteridium aquilinum (bracken)
Monilophytes • Ferns – Ecological and economic importance of ferns • Generally avoided by animals because of poisons or unpalatable chemicals present • Humans – – – Some consume fiddlehead Leaves used in basket-making Fronds mixed in flower arrangements Popular indoor houseplant and outdoor landscaping plant Gametophytes are excellent subject for research on physiology and plant development
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