IEB GRADE 11 LIFE SCIENCES
Comprehensive Examination Preparation Notes
1. Plant Tissues & Systems
Vascular plants have evolved highly structured tissue systems optimized for mechanical support, growth, and
long-distance transport of water, inorganic nutrients, and manufactured assimilates.
Anatomy of Roots, Stems, and Leaves in Dicots
The Dicot Root: Organized primarily for absorption and structural anchorage.
• Epidermis: A single outer layer of cells lacking a waxy cuticle to ensure unimpeded water absorption.
Specialized cells extend outward to form root hairs, which vastly increase the total absorptive surface area.
• Cortex: A wide region of loosely arranged parenchyma cells with abundant intercellular spaces,
specialized for the storage of starch and facilitating the radial movement of water toward the vascular
cylinder.
• Endodermis: The innermost layer of the cortex. It forms a selective barrier characterized by the
Casparian strip—a waterproof, suberized band around the radial cell walls. This forces water to pass
transcellularly through the living plasma membrane, acting as a biological filter.
• Stele (Vascular Cylinder): Contains a central X-shaped or star-shaped core of primary xylem, with
patches of primary phloem situated between the xylem arms.
The Dicot Stem: Organized to offer architectural support and facilitate multidirectional internal transport.
• Epidermis: Coated by a protective waxy cuticle to drastically curtail desiccation. It contains stomata or
lenticels for regulated gaseous exchange.
• Cortex: Composed of an outer band of collenchyma (providing flexible mechanical support) and an inner
core of parenchyma cells.
• Vascular Bundles: Distinctly arranged in a discrete, peripheral ring structure. The xylem always faces
internal pith, while the phloem faces outward. Between them lies the fascicular vascular cambium, a
lateral meristem responsible for secondary growth (thickening).
The Leaf: Optimized directly to maximize photosynthetically active radiation (PAR) capture and gas exchange.
• Cuticle & Epidermis: The upper epidermis is covered by a dense waxy cuticle to prevent non-stomatal
water loss. The lower epidermis typically possesses a higher density of stomata, each bound by a pair of
chlorophyllous guard cells.
Page 1 of 5
, IEB Grade 11 Life Sciences
• Mesophyll Layer: Divided into the upper palisade mesophyll (columnar, tightly packed cells rich in
chloroplasts to optimize light capture) and the lower spongy mesophyll (loosely organized cells with
substantial air spaces to maximize CO₂ diffusion).
Transport Dynamics: Xylem vs. Phloem
Feature Xylem Tissue Phloem Tissue
Primary Transports water and dissolved mineral ions Transports organic nutrients (predominantly
Function unidirectionally from roots up to aerial sucrose) bi-directionally from source to sink
tissues. tissues.
Cellular Composed entirely of dead, hollowed cells Composed of living cells lacking nuclei at
Viability at maturity (Vessels and Tracheids). maturity (Sieve Tube Elements) assisted by
Companion Cells.
Structural Cell walls heavily reinforced with Cellulose walls with sieve plates
Modification hydrophobic lignin laid down in annular, possessing specialized cytoplasmic pores
spiral, or pitted patterns. for mass flow.
The Transpiration Stream
Water movement across the plant axis operates under a continuous negative pressure gradient driven
collectively by three forces:
1. Root Pressure: Active accumulation of inorganic ions into the root stele drops the internal osmotic
potential. Water moves down a water potential gradient into the root xylem, producing a positive hydrostatic
pushing force.
2. Capillarity: Upward physical migration within narrow xylem lumens determined by adhesion (affinity
between water molecules and hydrophilic cell wall components) and cohesion (intermolecular hydrogen
bonding holding the fluid column together).
3. Transpiration Pull: The primary driving force. Evaporation of water vapor through stomata creates a
severe localized reduction in water potential within mesophyll walls. Due to strong cohesive properties, this
localized tension pulls the entire unbroken column of water upward from the roots.
Page 2 of 5