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Transport In Plants
Water Potential
• The physical property predicting the direction in which water will flow – ____________________ – Pressure
• water moves from high water potential to low water potential
Water Potential (a)
• Left Side – Pure Water = 0
Water Potential • Right Side
– Negative Water Potential • 0 pressure • - solute (has solutes)
• Water moves to the right
Water Potential (b) • Left Side
– Pure Water = 0 Water Potential
• Right Side – 0 Water Potential
• + pressure equal to solute conc.
• - solute (has solutes)
• Water is at equilibrium
Water Potential (c) • Left Side
– Pure Water = 0 Water Potential
• Right Side – Positive Water
Potential • + pressure more
than solute conc. • - solute (has
solutes)
• Water moves to the left
Water Potential (d)
• Left Side – Pure Water and
Negative Tension • Right Side
– Negative Water Potential • 0 pressure • - solute (has
solutes)
• Water moves to the left
Transport of Xylem Sap
• Pushing Xylem – Root Pressure
• caused by active pumping of minerals into xylem
• _____________: accumulation of water
Transport of Xylem Sap
• ______________ – Transpiration
• evaporative loss of H2O from a plant through the stomata
Transport of Xylem Sap
The Control of Transpiration
• ______________ – turgid - open – flaccid - closed
• Potassium Ions – active transport of H+ out of
cell causes K+ to move in
Stomata
• Open during the day / Closed at night – first light (blue light receptor) – depletion of Carbon Dioxide – internal clock (circadian rhythms)
Reducing Transpiration
• Small, thick leaves
• Thick cuticle • Stomata are
recessed • Lose their leaves • C4 or CAM plants
Translocation of Phloem Sap
Translocation of Phloem
• Phloem Sap – 30% sucrose, minerals, amino acids,
hormones – Transported in sieve-tube members
• ____________– leaves, tuber or bulbs • Sugar sink – growing roots, shoots,
fruits
Pressure Flow and
Translocation A) Pressure is high
B) Pressure is low
C) Xylem recycles water
D) Allows Phloem sap to flow from source to sink
A
B
C
Plant Nutrition
Uptake of Nutrients
_______________ cultures used to determine which chemical elements are essential.
17 essential elements needed by all plants
Soil • Develops from weathered
rocks – Anchors plants – Provides water – Provides dissolved minerals
Soil Texture • Pertains to sizes of soil
particles – includes the following:
• sands (0.02 - 2 mm) • silt (0.002 - 0.02 mm) • clay (less than 0.002 mm)
Soil Composition • Made up of sand, silt,
clay, rocks, humus, microorganisms (bacteria, fungi, algae, protists, insects, worms, roots)
• Soil contains a mixture of different sized particles – _______ – roughly equal
amounts of sand, silt, and clay – most fertile
The availability of soil water and minerals
The availability of soil water and minerals
• Plant takes up water not tied to hydrophilic soil particles
• Positively charged ions attach to soil • H+ help displace minerals attached to
soil • Roots add H+ to the soil directly and
through the release of ____
• (reacts with water to form carbonic acid)
The availability of soil water and minerals
Soil Conservation • Fertilizers
– (Nitrogen, Phosphorus, Potassium)
The Nation that Destroys Its Soil Destroys Itself – Franklin D. Roosevelt 1937
Loss of Topsoil • 1930’s “_____________” • Due to inappropriate farming in
late 1800’s and early 1900’s • Wheat and cattle farming • Droughts • Steinbeck’s Grapes of Wrath • 30% of world’s farmlands have
reduced production due to poor soil conditions.
Nitrogen Fixation
Nitrogen Fixation • Plants absorb nitrogen in the
form of nitrate • _____________ and
ammonifying bacteria produce ammonium
• Ammonium is shifted to nitrate by nitrifying bacteria
• Plants shift nitrate back to ammonium for use
Nitrogen Fixation
Unusual Nutritional Adaptations in Plants - Epiphytes
Unusual Nutritional Adaptations in Plants - Mistletoe
Unusual Nutritional Adaptations in Plants – Venus Fly Traps
Unusual Nutritional Adaptations in Plants – Pitcher Plants
Unusual Nutritional Adaptations in Plants - Sundews
Control Systems in Plants
Plant Hormones
• Coordinates growth • Coordinates development • Coordinates responses to
environmental stimuli
Plant Hormones
• Auxin (IAA) • Cytokinins • Gibberllins • Abscisic Acid • Ethylene • Oligogaccharins • Brassinosteroids
Auxins • Stimulates stem elongation • Stimulates root growth • Stimulates differentiation and
branching • Stimulates development of
fruit • Stimulates apical dominance • Stimulates phototropism and
gravitropism
Auxin Control • Auxin stimulates
growth • Auxin block on
right causes cells to elongate and the plant bends left
• Auxin block on left causes cells to elongate the the plant bends right
• Proton pump stimulated by auxin lower pH of wall • H+ activates Enzyme • Enzyme breaks hydrogen bonds in cellulose • Wall takes up water and elongates
Acid Growth
Auxin Others • Promotes secondary
growth by stimulating vascular cambium and secondary xylem
• Promotes adventitious root at the base of a cut stem
• Promotes fruit growth without pollination (seedless tomatoes)
Cytokinins • Stimulates root growth • Stimulates cell division and
differentiation (with auxins) – more cytokinin - shoot buds
develop – more auxin - roots develop
• Stimulates germination • Delays Senescence
Gibberellins • Promotes seed and bud
germination • Promotes stem elongation • Promotes leaf growth • Stimulates flowering and
fruits – (with auxin)
Abscisic Acid • Slows growth • Closes stomata under water
stress • Permits seed dormancy
Ethylene • Promotes fruit ripening • Controls Abscission (causes
leaf loss)
Plant Movements
• Phototropism • Gravitropism • ____________
Plant Movement • Rapid Leaf
Movement (39.27) – drop in turgor
pressure within pulvini
– sent by action potentials
Plant Movement • Sleep Movements (39.21)
– cells on opposite sides of pulvinus control the movement
Daily and Seasonal Responses
• Circadian Rhythm • Photoperiodism
– controls flowering (short-day vs. long-day)
– critical night length
Photoperiodic Control
Flowering Hormones • Experiment
indicates the presence of some type of flowering hormone
Phytochromes • Function as photoreceptors / red (660nm) to
far red (730nm) • Activates kinases (regulatory proteins)
Red vs. Far Red Response
Plant Responses to Environmental Stress
• Water Deficit • Oxygen Deprivation • Salt Stress • Heat Stress • Cold Stress • Herbivores
Responses to Herbivores • Produce
_________ (an amino acid similar to arginine)
• Recruitment of predatory animals
Why plants are important? • Food!
• Humans have domesticated plants for 13,000 years.
• ____ of all the calories consumed by humans come from six crops: Wheat, Rice, Maize, Potatoes, Cassava, and Sweet Potatoes.
• Also, we use plants to feed cattle, 5-7kg to produce 1 kg of beef.
Pyramid of Net Productivity
Plants remove CO2
• _____ of all US Prescription Drugs contain one or more active ingredients from plants.
• ____ earth’s species will become extinct within the next 100 years (larger than the Permian or Cretaceous)
• Only 5,000 of 290,000 species have been studied.
• 3-4 species per hour,
27,000 per year!
Cinchona tree
• Bark contains __________ • Grows in the
Andes in peru • Used since the
early 1600’s to treat malaria
Aspirin • Acetylsalicylic acid or ASA • Dates back to 3000 B.C. • Greek Physician Hippocrates
prescribed it. • From _____________ and
other Salicylate-rich plants (leaves and bark)
• Scientists at Bayer began investigating acetylsalicylic acid as a less-irritating replacement for standard common salicylate medicines. By 1899, Bayer named it this Aspirin
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