Transport in Xylem and Phloem (Chapter 7)

Question 1

What are the two possible pathways that water can move down the water potential gradient from cell to cell?

Answer 1

1) symplastic pathway

2) apoplastic pathway

Question 2

Describe briefly the symplastic pathway

Answer 2

Water moves from cell to cell via the plasmodesmata

Question 3

Describe briefly the apoplastic pathway

Answer 3

Water moves through the cell walls

Question 4

What are 3 unusual characteristics of xylem tissue?

Answer 4

1) made from cells joined end to end to form tubes
2) the cells are dead
3) walls of the cells are thickened with lignin

Question 5

What are the two functions of xylem?

Answer 5

Support and transport

Question 6

What are the three types of cell in xylem tissue in flowering plants?

Answer 6

1) vessel elements and tracheids (cells involved with transport of water)
2) sclerenchyma fibres (dead, elongated cells with lignified walls that help support the plant)
3) parenchyma cells

Question 7

What are xylem vessels made up of?

Answer 7

Many vessel elements (elongated cells) arranged end to end

Question 8

How does a vessel element form?

Answer 8

1) each vessel element starts as a normal plant cell in whose wall lignin is laid down
2) as lignin builds up around the cell, the contents of the cell die, leaving a completely empty space (lumen) inside

Question 9

What is lignin?

Answer 9

• A very hard, strong substance which is impermeable to water

Question 10

What are pits, how are they formed, and describe their characteristics?

Answer 10

• Pits are non-lignified areas formed where no lignin is laid down in the original cell walls where groups of plasmodesmata are found
• They are seen as gaps in the thick walls of the xylem vessels
• They are not open pores bc they are crossed by permeable, unthickened cellulose cell wall
• The pits in one cell link with the those in the neighbouring cells, so water can pass freely from one cell to the next

Question 11

How is a xylem vessel formed?

Answer 11

When the end walls of neighbouring vessel elements break down completely, to form a continuous tube running through the plant

Question 12

What is hydrostatic pressure?

Answer 12

The pressure exerted by a liquid

Question 13

How do changes in hydrostatic pressure cause water to move up the xylem vessels?

Answer 13

1) the removal of water from xylem vessels in the leaf reduces the hydrostatic pressure at the top of the xylem vessels
2) ∴ the hydrostatic pressure at the top of the xylem vessel becomes lower than the pressure at the bottom
3) this pressure difference causes water to move up the xylem vessels in continuous columns, as the higher pressure at the bottom pushes water up the vessel
4) the lower the hydrostatic pressure, the lower the water potential ∴ hydrostatic pressure gradient is also a water potential gradient

Question 14

Why do xylem vessels have strong, lignified walls?

Answer 14

To stop them from collapsing as a result of pressure differences as the water in the xylem vessels is under tension

Question 15

By what process does water move up xylem vessels?

Answer 15

By mass flow (i.e. all water molecules and any dissolved solutes move together as a body of fluid)

Question 16

How do cohesion and adhesion allow mass flow of water?

Answer 16

1) Water molecules are attracted to each other (cohesion) and to the cellulose and lignin in the walls of the xylem vessels (adhesion)
2) Cohesion and adhesion ∴ help to keep the water in a xylem vessel moving as a continuous column

Question 17

What is the benefit of xylem vessel elements being dead cells?

Answer 17

There is no protoplasm to get in the way of transport

Question 18

Why do xylem vessels have a small diameter?

Answer 18

To help prevent breaks in the column of water (air locks) forming due to air bubbles

Question 19

What is the benefit of having pits in xylem vessels?

Answer 19

• They allow water to move out into neighbouring vessels and ∴ bypass such an airlock
• Air bubbles cannot pass through pits
• Pits allow water to move out of xylem vessels to surrounding living cells

Question 20

What is the effect of an airlock?

Answer 20

It prevents water from moving up the vessel as the column of water breaks and the difference in pressure between the water at the top and the water at the bottom cannot be transmitted through the vessel

Question 21

How does the arrangement of xylem tissue in a series of roads around the centre of the stem help the plant?

Answer 21

It helps to support the stem

Question 22

How else can plants increase the hydrostatic pressure difference between the top and the bottom of the xylem vessel?

Answer 22

By increasing the pressure at the base of the vessels (roots)

Question 23

How is hydrostatic pressure raised at the bottom of the vessels?

Answer 23

1) the cells surrounding the vessels actively pump solutes across their membranes, into the water inside the xylem vessels in the root by active transport
2) the presence of the solutes lowers the water potential of the solution in the xylem ∴ drawing in water from the surrounding root cells
3) this influx of water increases the water pressure at the base of the xylem vessel

Question 24

Why is water transport a largely passive process?

Answer 24

The water simply moves down a continuous water potential gradient from the soil to the air, driven by transpiration in the leaves

Question 25

Where are xylem vessels in roots?

Answer 25

In the centre

Question 26

How is water move across the root into the xylem?

Answer 26

1) water taken up by root hairs crosses the cortex of the root and enters the xylem in the centre of the root bc the water potential inside the xylem vessels is lower than the water potential in the root hairs
2) ∴ water moves down this water potential gradient across the root

Question 27

Describe the apoplastic pathway in roots

Answer 27

Water soaks into the cell walls of the cells of the cortex and seeps across the root from cell wall to cell wall without ever entering the cytoplasm of the cortical cells

Question 28

Outline the 3 steps of the apoplastic pathway?

Answer 28

1) water enters the cell in the cell wall
2) water moves through the cell wall
3) water moves from cell wall to cell wall through intracellular spaces directly

Question 29

Describe the symplastic pathway in roots

Answer 29

Water moves into the cytoplasm/vacuole of a cortical cell by osmosis and then into adjacent cells through the interconnecting plasmodesmata, adjacent CSM or cells walls

Question 30

When does more water travel via the symplastic pathway?

Answer 30

Most of the time (when transpiration rates are low/normal)

Question 31

When does more water travel via the apoplastic pathway?

Answer 31

When transpiration rates are especially high

Question 32

What happens when water reaches the endodermis in roots?

Answer 32

The apoplastic pathway is abruptly blocked

1) the cells in the endodermis have a thick, waterproof, waxy band of suberin in their cell walls called the Casparian strip
2) this forms an impenetrable barrier to water in the walls of the endodermis cells ∴ the only way for water to cross the endodermis is through the cytoplasm (i.e. via symplastic pathway)
3) water can continue to pass freely through passage cells, where suberin deposits have not become more extensive like endodermal cells
4) water then continues to move down the water potential gradient across the pericycle and then into xylem vessels through pits in their walls

Question 33

What does the Casparian strip allow plants to do?

Answer 33

• This arrangement gives plants control over what miner ions pass into xylem vessels as everything has to cross CSMs
• It may also help with the generation of root pressure

Question 34

Describe the structure of the tip of a root

Answer 34

• The tip is covered by a tough, protective root cap and is not permeable to water
• Behind the tip, some of the cells in the epidermis (outer layer) are drawn out into long, thin extensions called root hairs - these reach into spaces between the soil particles, from where they absorb water

Question 35

How does water move into the root hairs from the soil?

Answer 35

By osmosis down a water potential gradient

1) soil has a relatively high water potential bc even though it contains some inorganic ions in solution, it is a relatively dilute solution
2) cytoplasm and cell sap inside the root hairs have a relatively low water potentials because they have considerable quantities of inorganic ions and organic substances e.g. proteins and sugars, dissolved in them
3) ∴ water diffuses down this water potential gradient through the partially permeable CSM and into the cytoplasm and vacuole of root hair cells

Question 36

Why are root hairs important?

Answer 36

1) the large no. of very fine root hairs provides a large SA in contact with the soil surrounding the root ∴ increasing the rate at which water can be absorbed
2) important in the absorption of mineral ions e.g. Mg2+
3) they are regularly replaced (every few days) as the root grows

Question 37

Describe the path of mineral ions in solution similar to that of water

Answer 37

Mineral ions in solution are absorbed along with water by the roots (roots hairs), cross the root by apoplastic and symplastic pathways before moving in the mass flow of xylem sap up the xylem to the rest of the plant

Question 38

How else can mineral ions move in the plant?

Answer 38

1) diffusion

2) active transport and facilitated diffusion - allow cells to control what ions enter/leave cells

Question 39

What is translocation?

Answer 39

Moving from one place to another

Question 40

What is translocation used to describe?

Answer 40

The transport of soluble organic substances (assimilates) within a plant

Question 41

What are assimilates?

Answer 41

Substances that the plant has made itself e.g. sucrose and amino acids

Question 42

Where are assimilates transported

Answer 42

In sieve elements

Question 43

What is found in phloem tissue?

Answer 43

Sieve tubes (made up of sieve elements), fibres, parenchyma and companion cells

Question 44

What is a sieve tube?

Answer 44

A unique tube-like structure made up of many elongated sieve (tube) elements, joined end to end vertically to form a continuous tube

Question 45

What is a sieve element

Answer 45

A living cell (but special)

• Contains: cellulose cell wall, CSM, cytoplasm, ER and mitochondria
• Does not contain: nucleus, ribosomes

Question 46

What is different about the cytoplasm in a sieve element?

Answer 46

It is very cell and only forms a thin layer lining the inside of the inside wall of the cell

Question 47

What happens where the end walls of 2 sieve elements meet?

Answer 47

A sieve plate is formed

Question 48

What is a sieve plate made up of?

Answer 48

The walls of both sieve elements, perforated by large pores

Question 49

Describe the pores in sieve plates in living phloem

Answer 49

They are open, presenting little barrier to the free flow of liquids through them

Question 50

What does each sieve element have?

Answer 50

• At least one companion cell lying close beside it

- A companion cell and sieve element are very closely associated and regarded as a single functional unit

Question 51

Describe the characteristics of companion cells

Answer 51

• They have the structure of a normal plant cell BUT the number of mitochondria and ribosomes is large than normal and the cells are very metabolically active
• Numerous plasmodesmata pass through their cell walls, making direct contact between the cytoplasm of the companion cell and that of the sieve element
• They have many mitochondria to produce ATP required for active transport
• They carry out the metabolic processes needed by sieve tube elements

Question 52

What is phloem sap?

Answer 52

The liquid inside phloem sieve tubes

Question 53

What are the contents of sieve tube under?

Answer 53

Very high turgor pressure because of its high solute content

Question 54

What happens when a sieve tube is cut?

Answer 54

1) the release of pressure inside the tube causes a surge of its contents towards the cut
2) when the contents come up against the sieve plate, the plate may block the contents, helping to prevent escape of the contents of the sieve tube
3) within minutes, clotting occurs - the sieve plate is properly sealed with a carbohydrate called callose, preventing leakage and loss of valuable substances e.g. sucrose, which the plants cannot afford to lose in large quantities - these would leak out rapidly if the holes in the sieve plate were not quickly sealed due to high turgor pressure
4) this clotting also helps to prevent the entry of microorganisms which might feed on nutritious sap or cause disease

Question 55

How does phloem sap move?

Answer 55

Mass flow (much faster than diffusion)

Question 56

What does the plant need to do to create the pressure differences needed for mass flow created in the phloem?

Answer 56

The plant has to use energy ∴ phloem transport is an active process (vs passive in xylem)

Question 57

What is the pressure difference produced by in phloem?

Answer 57

Active loading of sucrose into sieve elements at the place from which sucrose is to be transported

Question 58

What is a source?

Answer 58

Any area of a plant in which assimilates are loaded into the phloem e.g. leaf/storage organ

Question 59

What is a sink?

Answer 59

Any area where assimilates are taken out of the phloem e.g. buds, flowers, fruits, roots and storage organs (normally growing or storage points)

Question 60

How is a pressure difference created in the phloem?

Answer 60

1) loading a high conc of sucrose into a sieve element greatly decreases the water potential of the sap inside of it ∴ water enters the sieve element by osmosis, down the water potential gradient
2) this causes a correspondingly high build up of hydrostatic/turgor pressure in the sieve element
3) ∴ a pressure difference is created between the source and sink, causing mass flow of water and dissolved solutes trough the sieve tubes from the high pressure area to the low pressure area (source to sink)

Question 61

What happens at the sink?

Answer 61

Sucrose may be removed and used, causing the water to follow by osmosis ∴ maintaining the pressure gradient

Question 62

Where can sinks be in the plant and what does this mean for direction of flow of phloem sap?

Answer 62

• Anywhere in the plant, both above and below photosynthesising leaves
• ∴ phloem sap flows both upwards and downwards in the phloem (unlike xylem which is always upwards)
• Within any vascular bundle, phloem sap may be flowing upwards in some sieve tubes and downwards in others, but it can only flow one way in any particular sieve tube at any one time

Question 63

By what pathways is sucrose loaded into phloem tissue?

Answer 63

Sucrose produced in photosynthesis in leaf mesophyll cells moves across the leaf in solution to the phloem tissue by both the symplastic and apoplastic pathways

Question 64

Why what transport method is sucrose loaded into a companion cell/sieve element from a leaf?

Answer 64

Active transport

Question 65

Explain how sucrose is loaded into the phloem

Answer 65

1) H+ are pumped out of the companion cell into its cell wall, using ATP as an energy source
2) this creates a large excess of H+ in the apoplastic pathway outside the companion cell
3) the H+ can move back into the cell down their conc gradient, through a co-transporter protein
4) the sucrose molecules are carried through the co-transporter molecule into the companion cell, against the conc gradient for sucrose
5) the sucrose molecules can then move from the companion cell into the sieve tube, through the plasmodesmata which connect them (symplastic pathway)

Question 66

What is a co-transporter protein?

Answer 66

A protein which acts as a carrier for both H+ and sucrose at the same time

Question 67

Where does unloading of sucrose from phloem occur?

Answer 67

Into any tissue which requires sucrose

Question 68

What happens when sucrose is unloaded from the phloem?

Answer 68

• Phloem unloading requires energy and similar methods as loading are used
• Once in the tissue, the sucrose is converted into something else by enzymes ∴ decreasing its conc and maintaining a conc gradient e.g. invertase hydrolyses sucrose to glucose and fructose

Question 69

How do assimilates move between sources and sinks?

Answer 69

In phloem sieve tubes

Question 70

What is the similarity between sieve tubes and xylem vessels?

Answer 70

Liquid moves by mass flow down a pressure gradient, through tubes formed by cells stacked end to end

Question 71

What is the difference between transport in phloem and xylem?

Answer 71

• Unlike water transport through xylem, which occurs through dead xylem vessels, translocation through phloem sieve tubes involves active loading of sucrose at sources and unloading at sinks ∴ requiring living cells
• Sucrose would leak out of xylem vessels, bc they have no membranes which control entry/loss of solutes

Question 72

What is the difference between xylem vessel elements and sieve elements?

Answer 72

• Vessel elements have lignified cell walls - advantage bc cells can be dead and ∴ entirely empty so water can flow unimpeded and dead xylem vessels with strong walls help to support the plant
• Sieve tubes do not have lignified cell walls but reduce resistance to flow by having only a thin layer of cytoplasm and no nuclei

Question 73

What is the difference between the ends of xylem vessel elements and the ends of sieve plates?

Answer 73

• The end walls of phloem sieve elements form sieve plates - advantage bc without the resistance of these sieve plates along the pathway, the steep positive pressure gradient inside the sieve tubes would quickly be lost with the different pressures at source and sink quickly equilibrating
• The end walls of xylem elements disappear completely ∴ xylem has to withstand high negative pressure (tension) inside its tubes and buckling is prevented by its lignified walls

Question 74

What is the function of lignin?

Answer 74

1) to provide strength and support
2) to withstand cohesion tension from water
3) to prevent inwards collapse
4) to allow unimpeded flow of water without friction

Question 75

What is the mechanism of pulling water up the stem called?

Answer 75

Cohesion-tension mechanism

Question 76

What is the driving force for the movement of water up the xylem?

Answer 76

Transpiration in the leaves

Question 77

What two features of xylem vessels adapt them for water transport?

Answer 77

1) low resistance

2) hollow - no living material

Question 78

What is mass flow?

Answer 78

The movement of fluids containing dissolved/suspended substances e.g. glucose over a long distance in living organisms, caused by a pressure gradient