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Transport in Plants

Transport in Plants. Chapter 36. Cellular Transport. A. passive transport Driven by the principles of diffusion Much of the diffusion is facilitated Selective channels are usually gated and regulated. Cellular Transport. B. Active Transport Often uses proton pump

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Transport in Plants

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  1. Transport in Plants Chapter 36

  2. Cellular Transport • A. passive transport • Driven by the principles of diffusion • Much of the diffusion is facilitated • Selective channels are usually gated and regulated

  3. Cellular Transport • B. Active Transport • Often uses proton pump • Generates membrane potential • may be used to drive active transport of other molecules (cotransport)

  4. Cellular Transport • Water Transport • By osmosis water moves from hypotonic to hypertonic solution in cells • BUT in plant cell, cell wall provides a pressure component, therefore water potential must be used

  5. Water potential review: • What is ψ of a container of distilled water that is open? • If ψ inside a cell is -0.7 MPa, and outside of the cell is -0.1 MPa, which direction will water move? • If ψS=-0.5MPa and ψP=0.1MPa, will water move into or out of this cell if it is placed in an environment where ψ=-0.2 MPa?

  6. Aquaporins • 1990’s Peter Agre (John’s Hopkins) discovers water pores in membranes that facilitate diffusion of water • 2003 Nobel Prize in Chemistry along with Roderick MacKinnon • Water is small and can diffuse through bilayer to some extent despite polarity • Aquaporins speed up this diffusion • May be gated to regulate water diffusion

  7. 3 Cellular Compartments • Apoplast: continuum of cell walls and extracellular spaces • Symplast: continuum of cytosol linked by plasmodesmata • Vacuole: bound by membrane called tonoplast

  8. Lateral Transport • Short distance horizontal movement • Mechanisms • Transmembrane (through membranes from one cell to the next) – slow • Symplastic (through one membrane into cell, then through plasmodesmata) • Apoplastic (through cell walls)

  9. Absorption by Roots • Root hairs increase surface area • Mycorrhizae (fungal partners) enhance absorption • Endodermis functions as selective region • Symplastic continues through plasmodesmata • Apoplastic must cross plasma membrane into cytosol due to Casparian strip • Casparian strip is waxy and hydrophobic, traps water and minerals in the vascular tissue

  10. Long Distance Transport in the Xylem • Root Pressure: Pushing • Transpiration: Pulling

  11. Root Pressure • Used by some plants, at night • At night, plants still expend energy pumping minerals into xylem • Accumulation of nutrients decreases ψ , causing water to flow in by osmosis • This upward push is root pressure • Guttation: exudation of water droplets seen in the morning

  12. Transpiration • Major mechanism of movement • Water is adhesive and cohesive • As one water droplet moves, the next also moves (water in continuous column in xylem) • As water evaporates out of the stomata, water below moves upward

  13. Guard Cells • Guard cells regulate water loss. • What conditions will promote the closing of guard cells? • Buckle outward when turgid • Regulate opening and closing by managing K+

  14. Stomata

  15. Guard Cells • Pump H+ out, K+ enters due to electric charge, water follows due to osmosis • Close when K+ leaves (water follows) • Aquaporins may vary permeability to regulate

  16. Some leaf molds, which are fungi that parasitize plants, secrete a chemical that causes guard cells to accumulate potassium ions. How does this adaptation enable the leaf mold to infect the plant?

  17. Guard Cell Cues • Light stimulates a blue light receptor in guard cells, activates H+ pumps • CO2 depletion when Calvin cycle starts • Can trick guard cells by placing in environment without CO2 • Internal Clock • Open and close even in 24 hour dark • Circadian rhythm

  18. What adaptations are seen for arid climates? • thick leaves (low SA/vol) • Thick cuticle • Stomata on lower leaf surface • Stomata in pores to shield wind • Shed leaves in hot dry season • Cacti have no leaves (adapt to spines) • CAM photosynthesis

  19. Phloem Transport • Translocation • Sugar source to sugar sink • Sugar loaded into sieve tube members by active transport • Water follows by osmosis (increases pressure) • At sink, sugar leaves sieve tube members (by diffusion or active transport) • Water follows (decreases pressure) • Water is recycled by xylem

  20. Oleander: stomata in “cypts”

  21. Old Man cactus

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