Mass transport in plants

Created by

Lish

Cards (18)

Describe the function of xylem tissue
Transports water (and mineral ions) through the stem, up the plant to leaves of plants
Suggest how xylem tissue is adapted for its function
Cells joined with no end walls forming a long continuous tube → water flows as a continuous column
Cells contain no cytoplasm / nucleus → easier water flow / no obstructions
Thick cell walls with lignin → provides support / withstand tension / prevents water loss
Pits in side walls → allow lateral water movements
Explain the cohesion-tension theory of water transport in the xylem
Water lost from leaf by transpiration - water evaporates from mesophyll cells into air spaces and water vapour diffuses through (open) stomata
Reducing water potential of mesophyll cells
So water drawn out of xylem down a water potential gradient
Creating tension (‘negative pressure’ or ‘pull’) in xylem
Hydrogen bonds result in cohesion between water molecules (stick together) so water is pulled up as a continuous column
Water also adheres (sticks to) to walls of xylem
Water enters roots via osmosis
Describe how to set up a potometer
Cut a shoot underwater at a slant → prevent air entering xylem
Assemble potometer with capillary tube end submerged in a beaker of water
Insert shoot underwater
Ensure apparatus is watertight / airtight
Dry leaves and allow time for shoot to acclimatise
Shut tap to reservoir
Form an air bubble - quickly remove end of capillary tube from water
Describe how a potometer can be used to measure the rate of transpiration
Potometer estimates transpiration rate by measuring water uptake:
Record position of air bubble
Record distance moved in a certain amount of time (eg. 1 minute)
Calculate volume of water uptake in a given time:
Use radius of capillary tube to calculate cross-sectional area of water (πr2)
Multiply this by distance moved by bubble
Calculate rate of water uptake - divide volume by time taken
Describe how a potometer can be used to investigate the effect of a named environmental variable on the rate of transpiration
Carry out the above, change one variable at a time (wind, humidity, light or temperature)
○ Eg. set up a fan OR spray water in a plastic bag and wrap around the plant OR change distance of a light source OR change temperature of room
Keep all other variables constant
Suggest limitations in using a potometer to measure rate of transpiration
Rate of water uptake might not be same as rate of transpiration
○ Water used for support / turgidity
○ Water used in photosynthesis and produced during respiration
Rate of movement through shoot in potometer may not be same as rate of movement through shoot of whole plant
○ Shoot in potometer has no roots whereas a plant does
○ Xylem cells very narrow
Suggest how Light Intensity affect transpiration rate
Light intensity:
Increases rate of transpiration
Stomata open in light to let in CO2 for photosynthesis
Allowing more water to evaporate faster
Stomata close when it’s dark so there is a low transpiration rate
Suggest how Temperature affect transpiration rate
Temperature:
Increases rate of transpiration
Water molecules gain kinetic energy as temperature increases
So water evaporates faster
Suggest how Wind Intensity affect transpiration rate
Wind intensity:
Increases rate of transpiration
Wind blows away water molecules from around stomata
Decreasing water potential of air around stomata
Increasing water potential gradient so water evaporates faster
Suggest how Humidity affect transpiration rate
Humidity:
Decreases rate of transpiration
More water in air so it has a higher water potential
Decreasing water potential gradient from leaf to air
Water evaporates slower
Describe the function of phloem tissue
Transports organic substances eg. sucrose in plants
Suggest how phloem tissue is adapted for its function
Sieve tube elements -No nucleus / few organelles → maximise space for / easier flow of organic substances -End walls between cells perforated (sieve plate)
Companion cells -Many mitochondria → high rate of respiration to make ATP for active transport of solutes
What is translocation?
Movement of assimilates / solutes such as sucrose
From source cells (where made, eg. leaves) to sink cells (where used / stored, eg. roots) by mass flow
Explain the mass flow hypothesis for translocation in plants
At source, sucrose is actively transported into phloem sieve tubes /cells
By companion cells
This lowers water potential in sieve tubes so water enters (from xylem) by osmosis
This increases hydrostatic pressure in sieve tubes (at source)/ creates a hydrostatic pressure gradient
So mass flow occurs - movement from source to sink
At sink, sucrose is removed by active transport to be used by respiring cells or stored in storage organs
Describe the use of tracer experiments to investigate transport in plants
Leaf supplied with a radioactive tracer eg. CO2containing radioactive isotope14C
Radioactive carbon incorporated into organic substances during photosynthesis
These move around plant by translocation
Movement tracked using autoradiography or a Geiger counter
Describe the use of ringing experiments to investigate transport in plants
Remove / kill phloem eg. remove a ring of bark
Bulge forms on source side of ring
Fluid from bulge has higher conc. of sugars than below - shows sugar is transported in phloem
Tissues below ring die as cannot get organic substances
Suggest some points to consider when interpreting evidence from tracer & ringing experiments and evaluating evidence for / against the mass flow hypothesis
Is there evidence to suggest the phloem (as opposed to the xylem) is involved ?
Is there evidence to suggest respiration / active transport is involved?
Is there evidence to show movement is from source to sink? What are these in the experiment?
Is there evidence to suggest movement is from high to low hydrostatic pressure?
Could movement be due to another factor eg. gravity?