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14.10 Homeostasis in Plants

Definition:

  • Homeostasis in plants involves maintaining a stable internal environment to support essential processes like water balance, gas exchange, and photosynthesis.

1. Importance of Stomata in Plant Homeostasis

  • Stomata: Small pores mainly found on the underside of leaves.
    • Function: Regulate gas exchange (CO₂ in, O₂ out) and control water vapor loss (transpiration).
  • Guard Cells: Specialized cells that surround each stoma and control its opening and closing based on environmental conditions.

2. Structure of Guard Cells

  • Kidney Shape: Allows guard cells to bend outward when they swell, opening the stoma.
  • Cell Wall Adaptations:
    • Thicker Inner Walls: Help guard cells expand in a way that opens the pore.
    • Thinner Outer Walls: Enable bending and movement.
  • Cellulose Microfibrils: Arranged in bands, directing expansion lengthwise to control stomatal opening.


3. Mechanism of Stomatal Opening and Closing

Stomatal Opening (in light conditions)

  1. Proton Pump Activation:
    • Light activates proton (H⁺) pumps in the guard cell membrane, moving H⁺ ions out of the cell.
    • This creates a negative charge inside the cell.
  2. Potassium Ion (K⁺) Influx:
    • The negative charge inside opens K⁺ channels, allowing K⁺ ions to flow into guard cells, lowering water potential.
  3. Water Movement by Osmosis:
    • Water enters guard cells by osmosis due to the lower water potential, increasing turgor pressure.
  4. Cell Expansion:
    • Guard cells swell outward (due to their structural adaptations), opening the stoma for gas exchange.

Stomatal Closing (in darkness or water stress)

  1. Ion Movement Reversal:
    • Proton pumps stop, K⁺ ions exit guard cells, raising water potential.
  2. Water Loss:
    • Water exits guard cells by osmosis, decreasing turgor pressure.
  3. Cell Flaccidity:
    • Guard cells become flaccid, closing the stoma to conserve water.

Diurnal Rhythm

  • Day: Stomata typically open to allow CO₂ for photosynthesis.
  • Night: Stomata close to conserve water, as photosynthesis cannot occur in the dark.

4. Role of Abscisic Acid (ABA) in Stomatal Regulation

ABA: A plant hormone produced in response to stress, especially during drought or high temperatures.

  • Function: Signals guard cells to close stomata to reduce water loss.
  • Mechanism:
    • ABA Binding: ABA binds to receptors on guard cells.
    • Calcium Ion (Ca²⁺) Influx: Acts as a second messenger, prompting K⁺ and Cl⁻ ions to exit the cell.
    • Increased Water Potential: Water exits guard cells by osmosis, causing flaccidity and stomatal closure.


5. Key Concepts in Stomatal Regulation

  • Proton Pump: Moves H⁺ ions out of guard cells to initiate stomatal opening.
  • Electrochemical Gradient: Negative charge inside the cell attracts K⁺ ions.
  • Water Potential: Lowered by ion influx, allowing water to enter by osmosis.
  • Turgor Pressure: Increased by water intake, causing guard cells to expand and open the stoma.

6. Environmental Adaptations of Stomatal Behaviour

  • Light and CO₂: Stomata open when light is present and CO₂ is low, optimizing photosynthesis.
  • Water Stress: Stomata close in response to high temperatures or drought to conserve water.
  • Diurnal Patterns: Daytime opening for CO₂ intake; nighttime closure to reduce water loss.

7. Key Terms

  • Guard Cell: Surrounds each stoma and controls its opening and closing.
  • Electrochemical Gradient: Created by proton pumps, aiding K⁺ entry into guard cells.
  • Abscisic Acid (ABA): Hormone that promotes stomatal closure during water stress.

Questions for Review

Answer: Ion influx lowers water potential, causing water to enter by osmosis, which increases turgor pressure and opens the stoma.

Explain how stomata adapt to environmental changes.

Answer: Stomata open in response to light and low CO₂ to support photosynthesis. They close under water stress or at night to conserve moisture.

Describe how ABA functions during water stress.

Answer: ABA binds to guard cell receptors, inhibits H⁺ pumps, triggers ion exit, raises water potential, and causes water loss, leading to stomatal closure.

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