BackPlant Evolution, Structure, Nutrition, and Reproduction: Study Guide for BIOL 191A (Ch. 26–31)
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Plant Evolution and the Colonization of Land
Evidence for Plant Descent from Green Algae
Plants are believed to have evolved from green algae, specifically charophytes, based on similarities in cell wall composition, chloroplast structure, and the presence of the polymer sporopollenin that prevents desiccation of zygotes. Key derived traits of plants include multicellular, dependent embryos, alternation of generations, walled spores produced in sporangia, multicellular gametangia, and apical meristems.
Embryophytes: All land plants share the trait of multicellular, dependent embryos.
Cuticle: A waxy covering that prevents water loss.
Alternation of Generations: Life cycle with multicellular haploid (gametophyte) and diploid (sporophyte) stages.
Alternation of Generations
Plants alternate between multicellular haploid and diploid generations. The gametophyte produces gametes by mitosis; the sporophyte produces spores by meiosis. Fertilization produces a diploid zygote, which grows into a sporophyte.
Sporophyte (2n): Multicellular diploid form; produces haploid spores by meiosis.
Gametophyte (n): Multicellular haploid form; produces gametes by mitosis.
Spore: Haploid cell that can develop into a gametophyte.

Fungi and the Colonization of Land
Structure and Nutrition of Fungi
Fungi are heterotrophic organisms that absorb nutrients from their environment. Their bodies are composed of networks of hyphae, which collectively form a mycelium. Fungi play a crucial role in the colonization of land by forming mutualistic associations with plants (mycorrhizae), aiding in nutrient uptake.
Hyphae: Filamentous structures that make up the body of a fungus.
Mycelium: Densely branched network of hyphae.
Mycorrhiza: Symbiotic association between fungi and plant roots.
Major Groups of Plants
Nonvascular Plants (Bryophytes)
Nonvascular plants, including mosses, liverworts, and hornworts, lack vascular tissue and are typically small and found in moist environments. They have dominant gametophyte generations and reproduce via spores.
Dominant Generation: Gametophyte
Reproduction: Spores; require water for fertilization
Seedless Vascular Plants
These plants, such as ferns, have vascular tissue (xylem and phloem) but do not produce seeds. The sporophyte is the dominant generation.
Vascular Tissue: Xylem (water transport), Phloem (nutrient transport)
Dominant Generation: Sporophyte
Seed Plants: Gymnosperms and Angiosperms
Gymnosperms: Vascular plants with "naked" seeds not enclosed in an ovary (e.g., conifers).
Angiosperms: Flowering plants with seeds enclosed in fruits (mature ovaries).
Plant Structure and Organization
Root and Shoot Systems
The plant body is organized into two main systems: the root system (anchors the plant and absorbs water/minerals) and the shoot system (stems, leaves, and flowers for photosynthesis and reproduction).
Root System: Taproot, lateral roots, root hairs
Shoot System: Stems (nodes, internodes), leaves (blade, petiole), buds (apical, axillary), flowers

Plant Tissues
Dermal Tissue: Protective outer covering (epidermis, cuticle)
Vascular Tissue: Xylem (water/mineral transport), Phloem (sugar/nutrient transport)
Ground Tissue: Functions in storage, photosynthesis, and support (parenchyma, collenchyma, sclerenchyma cells)
Meristems and Plant Growth
Meristems are regions of undifferentiated cells that allow for indeterminate growth. Apical meristems contribute to primary growth (lengthening), while lateral meristems contribute to secondary growth (thickening).
Apical Meristem: Growth in length
Lateral Meristem: Growth in thickness (vascular cambium, cork cambium)
Plant Nutrition and Resource Acquisition
Essential Elements and Nutrient Uptake
Plants require essential elements (macronutrients and micronutrients) for survival. They absorb minerals from the soil through processes such as cation exchange, where hydrogen ions displace mineral cations from soil particles, making them available for uptake.
Macronutrients: Needed in large amounts (e.g., N, P, K)
Micronutrients: Needed in trace amounts (e.g., Fe, Zn)
Cation Exchange: Process by which roots exchange H+ for mineral cations
Role of Bacteria and Fungi in Plant Nutrition
Mycorrhizae: Fungi that enhance water and mineral absorption
Nitrogen-Fixing Bacteria: Convert atmospheric N2 to ammonia (NH3), which plants can use
Nodules: Structures on legume roots housing nitrogen-fixing bacteria
Plant Reproduction
Angiosperm Reproduction and Flower Structure
Angiosperms reproduce sexually through flowers, which contain both male (stamens) and female (carpels) reproductive organs. The life cycle includes double fertilization, where one sperm fertilizes the egg and another fuses with two nuclei to form endosperm.
Stamen: Male organ (anther, filament)
Carpel (Pistil): Female organ (stigma, style, ovary)
Petals and Sepals: Attract pollinators and protect reproductive organs
Ovule: Contains female gametophyte
Fruit: Mature ovary that aids in seed dispersal

Pollination and Seed Adaptations
Pollination: Transfer of pollen to the stigma; can be abiotic (wind, water) or biotic (animals)
Seed Coat: Protects the embryo
Dormancy: Allows seeds to survive unfavorable conditions
Sexual vs. Asexual Reproduction
Sexual Reproduction: Increases genetic diversity; requires pollination and fertilization
Asexual Reproduction: Offspring genetically identical to parent; rapid colonization but less diversity
Plant Responses to Internal and External Signals
Plant Hormones and Their Functions
Auxin: Cell elongation, root formation, fruit growth
Cytokinins: Stimulate cell division, delay aging
Gibberellins: Stem elongation, seed germination
Abscisic Acid (ABA): Promotes dormancy, closes stomata
Ethylene: Fruit ripening, response to mechanical stress
Plant Sensory Responses
Phototropism: Growth toward light (blue-light receptors)
Photoperiodism: Response to day length (phytochromes)
Circadian Rhythms: Internal biological clock (~24 hours)
Triple Response: Slowing of stem elongation, thickening, and horizontal growth in response to mechanical stress
Senescence, Leaf Abscission, and Fruit Ripening
Senescence: Programmed cell or organ death
Leaf Abscission: Shedding of leaves, often regulated by ethylene
Fruit Ripening: Coordinated by ethylene, making fruit palatable for dispersal
Comparison of Major Plant Groups
Group | Vascular Tissue | Seeds | Flowers | Dominant Generation |
|---|---|---|---|---|
Nonvascular (Bryophytes) | No | No | No | Gametophyte |
Seedless Vascular | Yes | No | No | Sporophyte |
Gymnosperms | Yes | Yes (naked) | No | Sporophyte |
Angiosperms | Yes | Yes (in fruit) | Yes | Sporophyte |