Plants Colonized Land

Land plants evolved from green algae Green algae called charophyceans are the closest relatives of land plants

Morphological and Biochemical Evidence Land plants share key traits only with charophyceans: Peroxisome enzymes Structure of flagellated sperm Chlorophyll A

Viridiplantae Streptophyta Plantae Red algae Chlorophytes Charophyceans Embryophytes Ancestral alga

Derived Traits of Plants Five key traits appear in nearly all land plants but are absent in the green algae: Apical meristems Alternation of generations Walled spores produced in sporangia-aexual reproduction Multicellular gametangia-gamete producing structures Multicellular dependent embryos

Apical Meristems Apical Meristem of shoot Developing leaves Root 100 µm 100 µm

Alternation of Generations Haploid multicellular organism (gametophyte) Mitosis Mitosis Spores Gametes MEIOSIS FERTILIZATION Zygote Mitosis Diploid multicellular organism (sporophyte)

The Origin and Diversification of Plants Fossil evidence indicates that plants were on land at least 475 million years ago Fossilized spores and tissues have been extracted from 475-million-year-old rocks

Fossilized spores. Unlike the spores of most living plants, which are single grains, these spores found in Oman are in groups of four (left; one hidden) and two (right). Fossilized sporophyte tissue. The spores were embedded in tissue that appears to be from plants.

Seedless vascular plants Origin of vascular plants Land plants Vascular plants Bryophytes Seedless vascular plants Seed plants Gymno- sperms Angio- sperms Liverworts Hornworts Mosses Lycophytes Pterophytes Charophyceans Origin of seed plants (about 360 mya) Origin of vascular plants (about 420 mya) Origin of land plants (about 475 mya) Ancestral green alga

The life cycles of mosses and other bryophytes are dominated by the gametophyte stage Bryophytes are represented today by three phyla of small herbaceous (nonwoody) plants: Liverworts, phylum Hepatophyta Hornworts, phylum Anthocerophyta Mosses, phylum Bryophyta

Bryophyte Gametophytes In all three bryophyte phyla, gametophytes are larger and longer-living than sporophytes Sporophytes are typically present only part of the time Animation: Moss Life Cycle

Bryophyte gametophytes Produce flagellated sperm in antheridia Produce ova in archegonia Generally form ground-hugging carpets and are at most only a few cells thick Some mosses have conducting tissues in the center of their “stems” and may grow vertically

Bryophyte Sporophytes Grow out of archegonia Are the smallest and simplest of all extant plant groups Consist of a foot, a seta, and a sporangium Hornwort and moss sporophytes have stomata

MOSS SPOROPHYTE

MOSS GAMETOPHYTE

LE 29-9d Polytrichum commune, hairy cap moss Sporophyte Gametophyte

Walled Spores Produced in Sporangia Multicellular Gametangia Dependent Embryos Longitudinal section of Sphagnum sporangium (LM) Archegonium with egg Female gametophyte Spores Embryo Maternal tissue Sporangium 2 µm 10 µm Sporophyte Male gametophyte Antheridium with sperm Gametophyte Wall ingrowths Placental transfer cell Sporophyte and sporangium of Sphagnum (a moss) Archegonia and antheridia of Marchantia (a liverwort)

Raindrop Key Male gametophyte Haploid (n) Sperm Diploid (2n) Spores develop into threadlike protonemata. “Bud” A sperm swims through a film of moisture to an archegonium and fertilizes the egg. Antheridia The haploid protonemata produce “buds” that grow into gametophytes. Most mosses have separate male and female gametophytes, with antheridia and archegonia, respectively. Protonemata “Bud” Egg Spores Gametophore Female gametophyte Archegonia Meiosis occurs and haploid spores develop in the sporangium of the sporophyte. When the sporangium lid pops off, the peristome “teeth” regulate gradual release of the spores. Rhizoid Peristome Sporangium The sporophyte grows a long stalk, or seta, that emerges from the archegonium. FERTILIZATION MEIOSIS (within archegonium) Seta Calyptra Capsule (sporangium) Zygote Mature sporophytes Foot Embryo Archegonium The diploid zygote develops into a sporophyte embryo within the archegonium. Young sporophyte Attached by its foot, the sporophyte remains nutritionally dependent on the gametophyte. Capsule with peristome (SEM) Female gametophytes

LIVERWORT STRUCTURE

GEMMA CUPS

Marchantia polymorpha, a “thalloid” liverwort LE 29-9a Gametophore of female gametophyte 500 µm Foot Seta Sporangium Marchantia polymorpha, a “thalloid” liverwort Marchantia sporophyte (LM)

Ecological and Economic Importance of Mosses Sphagnum, or “peat moss,” forms extensive deposits of partially decayed organic material known as peat Sphagnum plays an important role in the Earth’s carbon cycle

LE 29-10 A peat bog. Gametophyte Sporangium at tip of sporophyte Living photo- synthetic cells Dead water- storing cells 100 µm Closeup of Sphagnum. Note the “leafy” Gametophytes and their offspring, the sporophytes. Sphagnum “leaf” (LM). The combination of living photosynthetic cells and dead water-storing cells gives the moss its spongy quality. “Tolland Man,” a bog mummy dating from 405–100 B.C. The acidic, oxygen-poor conditions produced by Sphagnum can preserve human or animal bodies for thousands of years.

Ferns and other seedless vascular plants formed the first forests Bryophytes and bryophyte-like plants were the prevalent vegetation during the first 100 million years of plant evolution Vascular plants began to diversify during the Carboniferous period Vascular plants dominate most landscapes today

Origins and Traits of Vascular Plants Fossils of the forerunners of vascular plants date back about 420 million years , branching sporophytes They lacked other derived These early tiny plants had independent traits of vascular plants

Life Cycles with Dominant Sporophytes In contrast with bryophytes, sporophytes of seedless vascular plants are the larger generation, as in the familiar leafy fern The gametophytes are tiny plants that grow on or below the soil surface Animation: Fern Life Cycle

LE 29-12 Key Haploid (n) Diploid (2n) Antheridium Spore Young gametophyte Antheridium MEIOSIS Sporangium Sperm Archegonium Egg New sporophyte Sporangium Mature sporophyte Zygote FERTILIZATION Sorus Gametophyte Fiddlehead

Transport in Xylem and Phloem Vascular plants have two types of vascular tissue: xylem and phloem Xylem conducts most of the water and minerals and includes dead cells called tracheids Phloem consists of living cells and distributes sugars, amino acids, and other organic products

Evolution of Roots Roots are organs that anchor vascular plants They enable vascular plants to absorb water and nutrients from the soil Roots may have evolved from subterranean stems

Evolution of Leaves Leaves are organs that increase the surface area of vascular plants, thereby capturing more solar energy that is used for photosynthesis

Leaves are categorized by two types: Microphylls, leaves with a single vein Megaphylls, leaves with a highly branched vascular system According to one model of evolution, microphylls evolved first, as outgrowths of stems

LE 29-13 Vascular tissue Microphylls Megaphylls

Sporophylls and Spore Variations Sporophylls are modified leaves with sporangia Most seedless vascular plants are homosporous, producing one type of spore that develops into a bisexual gametophyte All seed plants and some seedless vascular plants are heterosporous, having two types of spores that give rise to male and female gametophytes

Classification of Seedless Vascular Plants There are two phyla of seedless vascular plants: Lycophyta includes club mosses, spike mosses, and quillworts Pterophyta includes ferns, horsetails, and whisk ferns and their relatives

LE 29-14a Selaginella apoda, a spike moss

LE 29-14b Isoetes gunnii, a quillwort

Diphasiastrum tristachyum, a club moss LE 29-14c Strobili (clusters of sporophyllis) Diphasiastrum tristachyum, a club moss

LE 29-14d Psilotum nudum, a whisk fern

Equisetum arvense, field horsetail Vegetative stem Strobilus on LE 29-14e Equisetum arvense, field horsetail Vegetative stem Strobilus on fertile stem

Athyrium filix-femina, lady fern LE 29-14f Athyrium filix-femina, lady fern

Phylum Pterophyta: Ferns, Horsetails, and Whisk Ferns and Relatives Ferns are the most diverse seedless vascular plants, with more than 12,000 species They are most diverse in the tropics but also thrive in temperate forests Some species are even adapted to arid climates

The Significance of Seedless Vascular Plants The ancestors of modern lycophytes, horsetails, and ferns grew to great heights during the Carboniferous, forming the first forests These forests may have helped produce the global cooling at the end of the Carboniferous period The decaying plants of these Carboniferous forests eventually became coal

FERNS VS GYMNOSPERMS Ferns vs Gymnosperms 1. Two types of spores a. Megaspores-origin of female gametophyte 1. Zygote 2. Embryo-sporophyte b. Microspores-origin of male gametophytes 1. Pollen tube/pollen 2. Separate gametophytes-Separate sexes 3. Gametophyte much more reduced a. No chlorophyll/Not free living 4. No flagella on sperm 5. Young embryo house within seed a. Protects embryo / Embryo self sufficient b. Nutrients from seed to grow

GYMNOSPERMS- conifers, cycads, ginkgoes Name means "naked seed" A. General characteristics 1. Lack separate gametophyte generation 2. Heterosporous 3. Develop seed-no spreading spores a. Contains egg that comes from megaspore b. Contains embryo after fertilization 4. Have pollen a. Microspore turns into pollen b. Develops pollen tube to remove the necessity of water for fertilization-enters thru micropyle of seed

a. Aids in dispersal-wind-water-insects-etc 5. Adaptive importance of pollen and seed a. Aids in dispersal-wind-water-insects-etc b. Protects embryonic plant from drying out c. Protects embryo`s food store from predators or parasites d. Food storage analogous to yolk of egg 6. They have no flowers, they have cones a. Staminate cones-male cones that release pollen b. Ovulate cones-female cones that produce egg-ovules B. Development of secondary growth 1. Cell division occurs in regions around periphery 2. Conducting tissues multiplied into cylindrical zone 3. Enables increase in diameter of plant/tree-like height