Angiosperms VII

Angiosperms VII Internal Control of Development: The Plant Growth Regulators

The Growth Regulators • Often referred to as “hormones” • adapted from animal physiology • animal hormones are produced in one place (gland) and exert an effect some other location • plant “hormones” don’t always work like that • “growth regulator” better descriptive term

Five Basic Groups • Auxins • Cytokinins • Ethylene • Abscisic Acid • Gibberellins

Early Work on Phototropism • Charles Darwin and his son Francis published early work on the problem: • “Power of Movement in Plants” (1880) • Worked with oat (Avena) Coleoptiles • Demonstrated importance of the “tip” in the plant response

Early Darwin Experiments

Discovery of Auxin • Fritz Went (1928) • Found that he could collect the substance responsible for the bending response • Developed the Avena Coleoptile Curvature Test (first bioassay) • Went called the unknown substance AUXIN

Coleoptile Curvature Test

What is Auxin? • German workers in the 1930’s identified Went’s auxin as indole-acetic acid (IAA) • Lucky discovery based on study of urine (so the story goes) in pregnant women

Formula of IAA

Effects of IAA In Phototropism • Causes local elongation of cells on the shaded side • This unequal elongation causes the bending of the stem (coleoptile) toward the light • Mechanism of action is called the acid growth hypothesis

Acid Growth Hypothesis • IAA triggers H+ ion transport which lowers the pH • This drop in pH loosens cell wall structure probably via proteins (expansins) which “break” bonds holding the cellulose microfibrils • This creates a “loosening” of the cell wall structure so turgor pressure can “expand” the cells • The effect is quite rapid

Cell Wall Expansion

Natural vs. Synthetic Auxins • IAA (indole-acetic acid) is the naturally occurring growth regulator • Synthetic auxins • substances which will cause bending the Avena Coleoptile Curvature Test • examples include: indole-butyric acid (IBA), naphthalene acid acid (NAA), 2,4-D and 2,4,5-T

AUXIN RESPONSES • Apical Dominance • IAA produced in the shoot apex inhibits the development of lateral (axillary) buds • However, it may be that high IAA concentrations stimulate ethylene production which actually inhibits the bud development • Concept used frequently in horticulture (creation of “bushy” shrubs)

Other Auxin Responses (cont.) • Abscission • Actively growing leaves and fruits produce large amounts of auxin (IAA) which is transported to the stem • This inhibits abscission of leaves and fruits • Environmental or age changes stimulate production of ethylene which stimulates production of abscission zone forming enzymes

Other Auxin Responses (cont.) • Differentiation of Vascular Tissue • Auxin + gibberellins and/or various concentrations of sucrose can stimulate development of xylem/phloem (either or both)

Other Auxin Responses (cont.) • Fruit Development • Seeds (result of fertilization) are a source of auxin, which in turn stimulates the formation (not ripening) of the fruit • May form parthenocarpic fruits (tomato and cucumber)

Other Auxin Responses (cont.) • Adventitious Root Formation • Several synthetic auxins (especially IBA) are used commercially to stimulate root development in “cuttings” • Some plants produce enough IAA in the shoot or leaves to stimulate the root formation in a cutting without additional hormone

Other Auxin Responses (cont.) • Weed Killers and Defoliants • 2,4-D and 2,4,5-T effective against dicots • manufacture as part of “Agent Orange” produced toxic trace molecule dioxin (a carcinogen)

Cytokinins • Discovered in the 1940’s in attempting plant tissue culture • Found that coconut milk stimulated cell division • Trail led to “old herring sperm DNA” • Isolated “kinetin” and dubbed the group of growth regulators cytokinins (after cytokinesis in cell division)

Cytokinins (cont.) • Zeatin the first naturally-occurring cytokinin to be isolated • Most cytokinins are produced in roots, but also in seeds, fruits and young leaves • Effects include: • stimulation of cell division • retard senescence in leaf tissues (once used as a bioassay)

Cytokinins (cont.) • with IAA, stimulate formation of either roots or shoot • HIGH IAA, low cytokinin = ROOTS • HIGH CYTOKININ, low IAA = SHOOTS

Cytokinins (cont.) • generally a “juvenile” hormone = keeps things young • used commercially to keep cut foliage “green and fresh”, but NOT for human consumption (a suspected carcinogen because of its nucleotide structure)

Strange Observations? • Burning of “illuminating gas” in Europe in 1800s caused trees near street lights to become defoliated on one side • Oranges can cause rapid ripening of bananas (don’t store them together) • The ancient Chinese burned incense in special huts to ripen fruit • “One bad apple can spoil a whole bushel”

Ethylene • A gas (H2C=CH2), unusual for a growth regulator • Produced in most CLIMATERIC fruits like apples, oranges, tomatoes, bananas • Used widely in the commercial fruit industry (here in Omaha) • The apples you buy in March were probably picked in September

Other Ethylene Responses • Promotes flowering in some plants like mangos and pineapples • Some growers may actually set fires near crops • May induce senescence in some flowers (orchids) • Generally promotes leaf and fruit abscission • Also involved in in monocot sex expression flowers, stem elongation (shaking response inhibits normal elongation), waterlogging effects (epinasty)

Abscisic Acid (ABA) • First extracted from dormant buds and called dormin • Later, found to be chemically identical with another compound called abscisic acid (unfortunate choice since it is not involved in abscission) • Involved in closure of stomata (guard cells) by stimulating loss of K+ ions (followed by water loss and closure)

Gibberellins • Discovered by E. Kurosawa studying “foolish seedling” disease of rice • Fungus, Gibberella fujikuroi, found to be disease agent • Could induce symptoms (stem elongation) from fungus extract • Later, found same substances in plants themselves

Effects of Gibberellins • Growth of Intact Plants • elongation AND cell division throughout the plant (unlike auxin) • overcomes genetic dwarfing

Gibberellins and Mendel • One of the 7 pairs of traits that Mendel studied in peas as he worked out the basic rules of inheritance was dwarf-tall. • The recessive gene - today called le - turns out to encode an enzyme that is defective in enabling the plant to synthesize GA. • The dominant gene, Le, encodes a functioning enzyme permitting normal GA synthesis and making the "tall" phenotype.

Effects ofGibberellins(cont.) • Seed Germination (grasses) • produced by the embryo and stimulates the aleurone layer to synthesize amylases

Starch Digestion in Seeds Treated with 1 ppm GA Treated with 1 ppb Treated with water

Effects of Gibberellins (cont.) • Used in production of sugarcane (increases biomass) • Mechanism of action not involved in cell wall acidification • May overcome light or cold requirements for seed germination • used in brewing industry to help germinate barley and produce the “malt”

Effects of Gibberellins (cont.) • Flowering/Bolting of Biennials • can substitute for “winter” cold period for bolting (flowering) in rosette biennials

Effects of Gibberellins (cont.) • Fruit Formation • used to produce larger fruits in open clusters in Thompson seedless grapes

Angiosperms VII

Angiosperms VII

Presentation Transcript

Kingdom Plantae: Angiosperms

Angiosperms

The angiosperms

The angiosperms

ANGIOSPERMS

Angiosperms

Absolute Angiosperms

Angiosperms

Angiosperms

Seed Plants: Angiosperms

Angiosperms II

Angiosperms VI

Angiosperms III

Angiosperms

ANGIOSPERMS (MONOCOTS)

Angiosperms

ANGIOSPERMS

Angiosperms

Plants: Angiosperms

Angiosperms

ANGIOSPERMS

Angiosperms