Movement of water and solutes in plants Chapter 4 and 30 4 and 30 . Movement of water ... Movement...
Transcript of Movement of water and solutes in plants Chapter 4 and 30 4 and 30 . Movement of water ... Movement...
Movement of water and solutes
in plants Chapter 4 and 30
Movement of water
Movement of water depends in: Volume of water (solvent) Amount of solutes Gravity Membranes Capillarity
Diffusion Concentration gradient Rates of diffusion are affected by
• Temperature • Density
In the leaves, water diffuses out via the stomata into the atmosphere.
Molecular Movement
Movement of water
Fluid statics = hydrostatics Hydrostatic pressure is the pressure required to stop the movement of water. Water potential quantifies the tendency of water to move from one area to another due to osmosis, gravity, mechanical pressure, or surface tension.
Osmosis
Osmotic potential: minimum pressure required to prevent fluid from moving as a result of osmosis. The pressure potential: pressure that develops against the cell walls as a result of water entering the cell’s vacuole. (Ψ) Water potential of a plant cell = The osmotic potential + pressure potential
The pores of the stomata are closed when turgor pressure (pressure potential) in the guard cells is low, and they are open when turgor pressure is high. • light intensity • carbon dioxide concentration • water concentration • Intake of K+
• Osmosis
Regulation of Transpiration. Turgor pressure.
Plasmolysis
Plasmolysis is the loss of water via osmosis and accompanying shrinkage of the protoplasm away from the cell wall. When this occurs, the cell is said to be plasmolyzed.
Imbibition
Imbibition is the swelling of tissues, alive or dead, to increases several times their original volume. This is a result of the electrical charges on materials in suspension attracting highly polar water molecules which then move into the cell.
Photographer: Michael Clayton
Active Transport Active transport is the movement of substances against an electrical gradient.
1. Hydrogen pumps
• H+ out into the soil water.
2. H+ combine with anions or membrane carriers allow the uptake of the ion against the electrochemical gradient (3). 4. H+ displace cations from the clay particles
Direct method of active mineral absorption
Cations that are free and in solution in the soil water can be taken up actively by active transport membrane pumps. Experiments that metabolically poison the root causes all mineral absorption to stop.
Water and its movement through the Plant
Roughly 95% of the water that enters a plant is lost via transpiration.
Water is necessary for:
1. Turgor and pressure 2. Photosynthesis 3. Regulation of internal temperature
The Cohesion-
Tension Theory
The difference between the water potentials of the soil and the air around the stomata are capable of producing enough force to transport water through the plant—from bottom to top and thus goes the cycle.
Translocation / The Pressure-Flow Hypothesis
Food substances from a source are taken up by osmosis destination or a sink organic solutes are moved along concentration gradients existing between sources and sinks.
• roots • food storage tissues (root cortex or rhizomes) • food producing tissues (mesophyll in leaves)
The Pressure-Flow Hypothesis
Apoplast and symplast pathways Ernst Münch, separated the plant into two principal compartments, the "dead" apoplast and the living symplast. Apoplast Spaces between the cells Cells walls It essentially maintains homeostasis in a plant. Symplast The cytoplasm of root cells Plasma membrane Plasmodesmata
Apoplast and symplast
Apoplastic and symplastic pathways
The root hair cell provides both an increase in the cell wall (apoplastic pathway) and the cytoplasmic route (symplastic pathway) for the movement of water.
Guttation
Appearance of drops of xylem sap on the tips or edges of leaves The water will accumulate in the plant, creating a slight root pressure. The root pressure forces some water to exude through hydathodes, forming drops.
Hydathodes
The hydathodes, that can often be found at the end of vascular bundles are derivatives of stoma complexes. They have guard cells, but they cannot be closed any more
Phloem Contents
its "honeydew' secretion.
Sucrose Glutamate or Glutamine and Aspartate or Asparagine Plant Hormones. Long-distance auxin transport, also occurs in the xylem. Basic pH Potassium, Magnesium, Phospahate and Chloride Nitrate, Calcium, Sulfur and Iron may be excluded
Attendance
Men4on the different kinds of transporta4on in The Cohesion-‐Tension Theory and the The Pressure-‐Flow Hypothesis Define apoplast and symplast What is an hydathode?