Plant Diversity I: How Plants Colonized Land Chapter 29 Notes Plant Diversity I: How Plants Colonized Land

Concept 29.1 More than 280,000 species of plants inhabit the earth today Although some are aquatic, most are terrestrial: deserts, grasslands, forests Land plants evolved from certain green algae called charophyceans

Concept 29.1 There are four main groups of land plants: bryophytes, pteridophytes, gymnosperms, and angiosperms Bryophytes: mosses; distinguished from algae by advances that allow for life on land

Concept 29.1 Pteridophytes: ferns; contain vascular tissue (transport water and food); “seedless plants” Gymnosperms: conifers; “naked seed” (seeds are not enclosed in a special chamber) Seed: consists of a plant embryo packaged with food and a protective coat

Concept 29.1 Angiosperms: flowering plants; “container seed”; most modern-day plants algal ancestors  bryophytes  vascular plants  the origin of seeds  the evolution of flowers

Concept 29.1

Concept 29.1 Charophyceans are the green algae most closely related to land plants Plasma membranes contain rosette cellulose-synthesizing complexes - synthesize the cellulose of cell walls Same enzymes in peroxisomes that help minimize the loss of product due to photorespiration

Concept 29.1

Concept 29.1 Several terrestrial adaptations distinguish land plants from charophycean algae - growth in length is from apical meristems - multicellular, dependent embryos - alteration of generations: gametophyte and sporophyte

Concept 29.1

Concept 29.1

Concept 29.1

Concept 29.2 There are other adaptations that are common in many land plants Adaptations for water conservation: - formation of a cuticle - stomata contain guard cells

Concept 29.2

Concept 29.2 Adaptations for water transport: Except for bryophytes, land plants have true roots, stems, and leaves with vascular tissue - xylem: carry water and minerals up from root - phloem: distribute sugars and amino acids throughout the plant

Concept 29.2

Concept 29.2 Land plants evolved from charophycean algae over 500 mya - chloroplasts: chlorophyll b and beta-carotene - homologous cell walls - peroxisomes

Concept 29.2 Alteration of generations in plants may have adapted by delayed meiosis Charophycean zygote undergoes meiosis to produce haploid spores Plant zygote undergoes mitosis to produce a multicellular sporophyte to produce haploid spores by meiosis

Concept 29.2 Adaptations to shallow water preadapted plants for living on land - natural selection would favor those that could withstand occasional drying

Concept 29.3 Bryophytes are represented by 3 phyla: Hepatophyta (liverwarts), Anthocerophyta (hornworts), and bryophyta (mosses)

Concept 29.3

Concept 29.3 The gametophyte is the dominant generation in the life cycle of bryophytes - sporophytes are typically smaller and present only part of the time - up to 50 million spores can be generated in one spore capsule

Concept 29.3

Concept 29.3

Concept 29.3

Concept 29.3 Mosses are able to exist in very harsh climates - able to loose most of their body water without dying, then rehydrate later Bryophytes were the only plants on earth for 100 million years

Concept 29.4 Modern vascular plants include ferns (pteridophytes), gymnosperms, and flowering plants (angiosperms) Differ from bryophytes - contain phloem and xylem - dominant sporophyte generation

Concept 29.4 2 phyla of seedless vascular plants: phylum Lycophyta and phylum Pterophyta (ferns) Pteridophytes provide clues to the evolution of roots and leaves

Concept 29.4 Most pteridophytes have true roots with lignified vascular tissue Lycophytes have small leaves with only a single unbranched vein; known as microphylls - modern leaves are known as megaphylls

Concept 29.4

Concept 29.4 A sporophyte-dominant life cycle evolved in seedless vascular plants Homosporous plants: produce one type of spore Heterosporus plants: produce megaspores (female) and microspores (male)

Concept 29.4