Biology HL · Chapter 8: Physiology

8.2 Plant Transport

Explain root uptake, xylem cohesion-tension, transpiration control and phloem translocation from source to sink.

Estimated time: 110 minutes

IB syllabus: B3.2 · SL and HL

Roots Build the Entry Gradient

Root hairs are extensions of epidermal cells that greatly increase contact with soil water. Mineral ions may enter through channels or active transporters, lowering water potential in root cells so water follows by osmosis. Water can travel through cell walls and intercellular spaces by the apoplast route or cross membranes and cytoplasm by symplast and transmembrane routes. At the endodermis, the hydrophobic Casparian strip blocks the wall route and forces selective membrane crossing before xylem entry.

HL extensionB3.2

Active ion loading into xylem can lower its water potential and generate positive root pressure, especially when transpiration is low. Root pressure can contribute to guttation and may help refill small vessels, but it is not sufficient to lift water through tall plants. Long-distance ascent is explained principally by cohesion-tension: evaporation at leaves creates tension that is transmitted through a continuous water column.

Xylem Couples Evaporation to Upward Flow

Xylem vessels are chains of dead cells whose end walls are absent or perforated. Their lignified walls resist collapse under tension, and pits allow lateral movement around blockages. Water molecules cohere through hydrogen bonding and adhere to hydrophilic vessel walls. When water evaporates from mesophyll cell walls and diffuses through stomata, curved air-water interfaces pull on the remaining water, reducing leaf water potential and drawing replacement water from xylem.

Transpiration is an unavoidable consequence of opening stomata for carbon dioxide. Warmth increases evaporation and diffusion, wind removes the humid boundary layer, and low atmospheric humidity steepens the water-vapor gradient. Light commonly opens stomata to support photosynthesis. Soil water shortage eventually causes guard cells to lose turgor or respond to abscisic acid, closing the pore. Closure conserves water but also restricts carbon dioxide and can lower photosynthesis.

A transverse section helps relate transport to support. In a young dicot stem, vascular bundles commonly form a ring, with xylem toward the center and phloem toward the outside. In a root, xylem is central and often star-shaped, with phloem between its arms. This arrangement supports the organ and shortens movement from absorbing tissues to xylem. A drawing should show relative tissue positions clearly rather than imitate every observed cell.

HL extensionB3.2 AHL

Phloem Moves Assimilates from Source to Sink

Phloem transports sucrose, amino acids and signaling molecules through living sieve-tube elements. Perforated sieve plates connect elements; little cytoplasm and no nucleus reduce obstruction. Companion cells retain organelles and provide metabolic support through plasmodesmata. At a source such as a mature leaf, proton pumps and cotransport can load sucrose into the sieve tube, lowering water potential so water enters from xylem and raises hydrostatic pressure.

At a sink, sucrose is removed for respiration, storage or growth, water potential rises and water can return to xylem. The source-to-sink pressure difference drives mass flow. Different tubes may carry sap in opposite directions because sources and sinks change with season and development. This is not bidirectional flow within one unobstructed tube at the same instant; it is a network containing different pressure gradients.

Xylem and phloem must be distinguished by energy and direction. Xylem transport of water is largely passive once gradients exist and usually moves from roots toward leaves through dead conduits under tension. Phloem loading and unloading often require active transport; sap moves through living tissue under positive pressure from whichever organ is a source to whichever is a sink. A growing fruit, root tip or storage organ can be a sink, while a storage organ becomes a source when reserves are mobilized.

Whole-Plant Transport Laboratory

Coordinate stomatal opening, soil water and phloem sink activity to see how xylem tension and source-to-sink pressure flow interact.

Structure · gradient · exchange · feedback

Physiology systems laboratory

Cohesion-tension and pressure-flowsource → sinkroot hairsxylemphloemwater vapour

Test Yourself

A ring of bark including phloem is removed while xylem remains intact. Which early outcome is most likely on a sunny day?

Exam questions on this topic

Practice focused questions or see how IB combines this topic with ideas from elsewhere in the course.