Plant transport

TWO transport systems in plants:
 XYLEM
 transports water and mineral salts
 no need for energy as ATP
 made of dead cells

 PHLOEM
 transports food e.g. sucrose, amino acids
using ATP
 made of living cells

Vascular tissue
is composed of:
 Xylem
 Phloem

Note how the xylem & phloem
branch to enter the leaves

Where are the xylem and pholem?
In the Leaf

mid-rib
vein

xylem
phloem

What causes
the upward
flow within
the xylem?

Mostly,
evaporation
of water by
the sun.

Translocation
 is the long-distance transport of food
materials within a plant
To growing regions to be
Glucose produced by used as energy for growth.
photosynthesis in leaf is
converted to sugars
(mainly sucrose) and
translocated to different
parts of the plant.

To storage organ (fruit)
to be stored mainly as
sugars. To storage organ
(tubers in roots)
To be stored
mainly as starch.

Section through
a stem.

Section through
a root.

Let’s discover the reason for the
different positioning of the xylem
& phloem in the stem & root

STEM: at the side

ROOT: at the centre

Shoot sways in the wind. What prevents it
from snapping?

Stem must be flexible to bend
without snapping

Sways in
the wind

Anchors
the shoot.

Give a reason for the arrangement of
the vascular bundles in the stem.
phloem
xylem

The xylem and phloem are arranged in bundles
near the edge of the stem to resist compression
and bending forces.

Stem resists:

Bending forces

Give a reason for the arrangement of
the vascular tissue in the root.

phloem
xylem

The xylem and phloem in the centre of the root
to withstand stretching forces.

To show the site of sugar movement
in a plant

A complete ring of bark
(containing phloem tissue) was
removed from a woody stem.

Result:
 the removal of the phloem prevents
transport in the plant

Conclusion:
 phloem tissue is the site of sugar transport

To show the site of water movement
in a plant

To show the site of water movement
in a plant
 plant is left in
eosin (red dye) for
about one hour

 cross sections of
the stem and root
are cut out and
examined

Celery stalk
in eosin. After 24 h Note red
lines.

Celery stem under microscope

Xylem stains
red

Celery leaf
veins stain
red

Predict what would happen.
1 2

3
4

Which parts become stained red with
eosin?

What is the
function of root
hairs?

Absorb water and
mineral ions.

How are root
hairs adapted
for
absorption?
1. are long and
provide a large
surface area
2. have a thin cell
wall

Question: [SEP, 2005]

Plants need mineral ions which they obtain from
soil. Explain how the uptake of mineral ions by
plants, may be inhibited in waterlogged soils. (3)
Ions are taken up by active transport.
Active transport needs energy from
respiration.
There is not enough oxygen for roots to
respire in waterlogged soils.

Uptake and transport of
water

A root hair cell has an extension

Learn to draw a root hair cell

nucleus
cytoplasm
cell membrane
cell wall

How does water from the soil end up
in the xylem?
The Uptake of Water

Up xylem
vessels to
plant

into xylem
across
Water from soil absorbed into across cortex vessels
phloem
root hair cell cells

Water moves by osmosis across the
root causing root pressure

H2O H2O

Transpiration:
is the loss of water vapour from the
surface of a plant

Water vapour is lost via open stomata

Transpiration stream:
the flow of water from root to leaves

Transport Of Water And Mineral Salts
Transport in the Xylem
There are three forces that move
the water upwards in the xylem:

a) Root pressure - a force that
pushes water up the xylem
(produced by the continuous
movement of water through the root
cells.
b) Capillary action - a force that
pushes water up the narrow xylem
vessels.
c) Transpirational pull - a force that
pulls water up the xylem (produced
by evaporation of water from the
leaves).

QUESTION: SEP, 2011
Describe the path taken by a
water molecule from the root
hair to the stomata in a leaf. (3)

Root hair absorbs water by osmosis.
Water moves across the root cortex by osmosis.
Water enters xylem and moves up towards
leaves, mostly due to evaporation.
Water evaporates into
air spaces between
spongy mesophyll cells
and diffuses out via
stomata.

Let’s study
transpiration in detail.

How can you show that water is actually
lost by transpiration & not another
chemical?
Leave for 1 hour. Test condensation by
a piece of blue cobalt
chloride paper.

Blue cobalt chloride paper becomes
pink

Apparatus to measure the rate of
transpiration: Potometer
Weight Water
potometer potometer

balance

Weight potometer
 A potted plant is well
watered.

 A plastic bag is
wrapped around the
pot to prevent water
loss from the soil.

 The apparatus is
weighed at intervals
and changes in weight
indicate water loss.

Suggest a control for this experiment.

CONTROL

To study the effect of wind speed on
the rate of transpiration
Which graph is for
highest fan speed?

C

A water potometer measures the rate
of water ABSORBED by the plant
 it is assumed that:
amount of water absorbed = water lost

A water potometer

Capillary tubing.
Ordinary glass
tubing.

Why is capillary tubing
used rather than
ordinary glass tubing?

Four factors affecting transpiration

1. Light
2. Temperature
3. Humidity
4. Wind currents

1. Light
 stomata open in the light and so
more water is lost

2. Temperature
 as temperature increases, evaporation
increases

Water molecules move
faster.

3. Humidity
 in dry air, the plant loses more water vapour
than in humid air

High humidity in air : less transpiration.
WHY?
A lot of water
vapour in air. Not
A lot of water much difference
vapour inside leaf in concentration

4. Wind currents
 moving air removes water vapour from
the leaf surfaces

QUESTION: SEP, 2011
Stomata allow transpiration to occur.
Explain why if a plant is enclosed in a
transparent bag, the rate of transpiration
decreases. (4)
Air around shoot becomes
humid.
Difference in concentration
of water vapour inside the
leaf and in the air around
leaf decreases.

Functions of transpiration
1. The plant cools as water evaporates.
2. Water is transported up the plant as water is
lost from the shoot – keeps cells turgid.
3. Dissolved salts move up too.

What is the picture showing?
The plant lost No loss in weight
weight as water as the water
evaporates in to which
the air. evaporated, retur
ned to flask.
2
1

QUESTION: MAY, 2012
Comment on the biological significance of the
following statement:

Transpiration may have some useful effects in
plants. (4)

Plant adaptations
to reduce water loss

1. Reduced leaf area – e.g. in cacti and pine

2. Hairs on leaves to trap moisture

3. Thick waxy cuticle – reduces transpiration by:
i) acting as a barrier to evaporation
ii) the shiny surface reflects heat and so lowers
temperature

Holly

4. Stomata on lower surface of leaves
– as more water would be lost if stomata
were on the upper epidermis as the sun
acts directly on this surface.

5. Sunken stomata trap still, moist air above
the stomata, so reducing transpiration.

Adaptations of plants which live in
dry habitats

1. Succulent leaves or stems (most cacti)
to store water.

2. Shallow, but extensive root systems

What is the advantage of having both
shallow and deep roots?

QUESTION: MAY, 2006
Olive trees (Olea europaea) are native to the
Mediterranean region and other hot, arid regions.
Give TWO adaptations which plants living in this
region show to reduce the rate of transpiration. (2)

1. Thick waxy cuticle.
2. Dense cover of short hairs on underside of
leaves.
3. Relatively small leaves.
4. Sunken stomata.

Plant transport

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Plant transport