9.2 Transport in the phloem of plants

Question 1

What type of tissue is found throughout plants?

Answer 1

Phloem tissue

Question 2

Where can phloem tissue be found specifically? (3)

Answer 2

• stems
• roots
• leaves

Question 3

What is the phloem composed of?

Answer 3

Sieve tubes

Question 4

What are sieve tubes composed of?

Answer 4

columns of specialized cells called sieve tube cells

Question 5

What are individual sieve tube cells separated by?

Answer 5

Perforated walls called sieve plates

Question 6

What are sieve tube cells closely associated with and how?

Answer 6

Companion cells

due to the fact that the sieve tube cell and its companion cell share the same parent cell

Question 7

What function do the companion cells perform? (2)

Answer 7

• many of the genetic and metabolic functions of the sieve tube cell
• maintain the viability of the sieve tube cell

Question 8

What is the structures and functions of companion cells? (3)

Answer 8

• Abundant mitochondria - support active transport of sucrose (figure 6)
• infolding of the plasma membrane - increases the phloem loading capacity using the apoplastic route
• Plasmodesmata - connect the cytoplasm of the companion cells with the sieve tube cells, have a larger diameter than plasmodesmata found in other parts of the plant to accomodate the movement of oligosaccharides and genetic elements between the two cells

Question 9

What are the structures and functions of sieve tube cells? (3)

Answer 9

• presence of active transport proteins or enzyme activity - produce the oligosaccharides from the accumulation of sucrose in the sieve tube element-companion cell pair
• rigid cell walls of the sieve tube cells - allow for the establishment of the pressure necessary to achieve the flow of phloem in the sieve tube cell
• sieve plates - seperates individual sieve tube cells with remnants of cell walls that separated the cells. The perforated walls in combination with the reduced cytoplasm means that the resistance to the flow of phloem sap will be lower

Question 10

What does the phloem transport?

Answer 10

organic compounds throughout the plant
* products of photosynthesis (mainly sucrose sugar), in solution, from leaves to parts of the plant that do not photosynthesise, such as roots, flowers and growing shoots

Question 11

What is translocation?

Answer 11

the transport of organic solutes (assimilates) in a plant
* Phloem sap flows through the pores in the sieve plate

Assimilates are substances made by the plant, using substances absorbed from the environment. They include sugars (mainly transported as sucrose) and amino acids

Question 12

Why is glucose transported as surcrose?

Answer 12

Glucose is a reducing sugar so is reactive and would be used up in chemical reactions

Question 13

What parts of the plant does the phloem link together?

Answer 13

Links parts of the plant that need a supply of sugars and other solutes such as amino acids to other parts that have a surplus

Question 14

What is a source in a plant?

Answer 14

areas where sugars and amino acids are loaded into the phloem

A part of the plant that load sassimilates into the phloem sieve tubes

Question 15

What is a sink in a plant?

Answer 15

where the sugars and amoino acids are unloaded and used

A part of the plant that removes assimilates from the phloem sieve tubes

Question 16

What are the sources of plants? (4)

Answer 16

Sources
Photosynthetic tissues:
* Mature green leaves
* green stems
Storage organs that are unloading their stores:
* storage tissues in germinating seeds
* tap roots or tubers at the start of the growth season

Question 17

What are the sinks of plants? (4)

Answer 17

Sink
Roots that are growing or absorbing mineral ions using energy from cell respiration (parts of the plant that are growing or developing food stores):
* Developing fruits
* developing seeds
* growing leaves
* developing tap roots or tubers

Question 18

What is the ringing experiment?

Answer 18

• two rings of bark were removed from an apple tree
• the bark contains the phloem tissue
• the effects on apple growth are clearly visible

Question 19

What can sinks and sources sometimes do?

Answer 19

Sinks can become sources
Sources can become sinks

Question 20

Since sinks can turn into sources, or vice versa, what must the tubes in phloem must be able to do?

Answer 20

must be able to transport biochemicals in either direction

Question 21

How is the phloem and the blood system of animals different?

Answer 21

there are no valves or central pump in phloem

Question 22

What are the similarities between transport in phloem and blood vessels?

Answer 22

In both systems
* a fluid flows inside the tubes because of pressure gradients
* Energy is needed to generate the pressures
* So the flow of blood and the movement of phloem sap are both active processes

Question 23

What is the movement through xylem and phloem by?

Answer 23

mass transport
* all particles move together in the same direction, such as in the transpiration stream up a xylem

Question 24

What is diffusion?

Answer 24

Diffusion is the result of the random motion of particles - particles move down their ceoncentration gradient and different particles may move in different directions

Question 25

Why is the movement through xylem and phloem by mass transport rather than diffusion?

Answer 25

Mass flow is faster than diffusion and can move large amounts of fluid long distances, quickly

Question 26

What are the features of sieve tube elements?

Answer 26

• no nucleus
• very little cytoplasm
• very thin cell walls

Question 27

How do sieve tube elements of phloem compare to the vascular elements of xylem?

Answer 27

• sieve tube elements are living unlike vascular elements of xylem
• but sieve tube elements have reduced quantities of cytoplasm and no nucleus

Question 28

Why do sieve cells need to be living?

Answer 28

they depend on the membrane to help maintain the sucrose and organic molecule concentration that has been established by active transport

Question 29

What are sieve tube elments?

Answer 29

the cells that make up phloem vessels

Question 30

What do sieve plates do?

Answer 30

• keep the sieve tubes open
• block movement of sap through phloem if plant is infected

Question 31

What is sap?

Answer 31

dissolved sucrose and amino acid in water

Question 32

What is the most prevalent solute in phloem sap?

Answer 32

Sucrose

Question 33

How is sucrose a good transport form of carbohydrate?

Answer 33

• it is not as readily available for plant tissues to metabolize directly in respiration
• it will not be metabolized during transport

Question 34

What are the features of companion cells?

Answer 34

• Large nucleus
• many mitochondria to provide ATP for active transport
• Plasmodesmata connect the cytoplasm of sive tube elements and companion cells

Question 35

Why does phloem not have walls impregnated with lignin?

Answer 35

• Lignin would kill the phloem
• However the sieve tube elements need to be alive in order to have a partially permeable membrane that allow active loading of assimulates (sucrose and amino acid) into the phloem

Question 36

What are the differences of xylem and phloem (6)

Answer 36

Question 37

What is phloem loading?

Answer 37

the mechanism by which the plants bring sugars into the phloem

Question 38

Does phloem loading differ for plants?

Answer 38

Yes

Question 39

What are the two types of route for phloem loading?

Answer 39

• apoplast route
• symplast route

Question 40

What is the apoplast route in phloem loading?

Answer 40

• significant amount of sugar travels through cell walls from mesophyll cells to the cell walls of companion cells
• sometimes sieve cells, where a sucrose transport protein then actively transports the sugar in

Question 41

How is an concentration gradient of sucrose established?

Answer 41

by active transport

Question 42

What is the process of the movement of sucrose across a sieve tube membrane

Answer 42

• H+ ions are actively trnasported out of the companion cell from surrounding tissues using ATP as an energy source
• this results in the movement of sucrose molecules by facilitated diffusion and diffusion
• the build-up of H+ then flows down its concentration gradient into the companion cells through a co-transport protein (only allow movement of the H+ ions into the cell if they are accompanied by sucrose molecules)
• the energy released is used to carry sucrose into the companion cell-sieve tube complex
• sucrose diffuses into sieve tube element through the plasmodesmata

Question 43

What happens as the concentration of sucrose in the companion cell sincreases?

Answer 43

surcrose can diffuse through the plasmodesmata into the sieve tube element

Question 44

What is the symplast route of phloem loading?

Answer 44

• much of the sucrose travels between cells thorugh connections between cells called plasmodesmata
• once the sucrose reaches the companion cell it is converted to an oligosaccharide to maintain the sucrose concentration gradient

Question 45

What is surcrose converted to maintain the sucrose concentration gradient?

Answer 45

Once it reaches the companion cells, it is converted to an oligosaccharide

Question 46

What is mass flow caused by?

Answer 46

A difference in hydrostatic pressure between the two ends of the phloem, which creates a pressure gradient

Question 47

What does sucrose entering the phloem at the source do to the water potential in the phloem?

Answer 47

It lowers the water potential

Question 48

As a result of sucrose entering the phloem at the source and lowering the water potential, where do the water molecules move?

Answer 48

water molecules move into the sieve tube element by osmosis from the surrounding tissues

this increases the hydryostatic pressure in the sieve tube at the source

Question 49

Where does the sap moves along the phloem?

Answer 49

from higher hydrostatic pressure at the source to a lower hydrostatic pressure at the sink

Question 50

What does the removal of sucrose from the sap increase, and so what?

Answer 50

increases the water potential so that water moves out of the sieve tube into the surrounding cells by osmosis

this lowers the hydrostatic pressure in the phloem at the sink

Question 51

Describe the process of mass flow in the phloem

Answer 51

1. sucrose enter the phloem at the source
2. lowers the water potential in the phloem
3. water molecules move into the sieve tube element by osmosis from surrounding tissues
4. this increases the hydrostatic pressure in the sieve tube at the source
5. sap moves along the phloem from higher hydrostatic pressure at the source to a lower hydrostatic pressure at the sink
6. the removal of sucrose from the sap increases the water potential
7. so that water moves out of the sieve tube into the surrounding cells by osmosis
8. this lowers the hydrostatic pressure in the phloem at the sink

Question 52

How is water drawn into the companion cell through osmosis?

Answer 52

the build-up of sucrose and other carbohydrates

Question 53

What 2 things contribute to a build-up of pressure in companion cells?

Answer 53

rigid cell walls combined with the incompressibility of water result in a build-up of pressure

Question 54

Where do water flow in terms of pressure?

Answer 54

form area of high pressure to an area of low pressure

Question 55

What happens to sucrose and water at the sink end?

Answer 55

sucrose is withdrawn from the phloem and the loss of solute causes a reduction in osmotic pressure and the water that carried the solute to the sink is then drawn back in to the transpiration stream in the xylem

Question 56

What is the sucrose withdrawn from the phloem used as?

Answer 56

either as an energy source (i.e. growth) or converted to starch

Question 57

What are the 3 functions of phloem?

Answer 57

• loading of carbohydrates
• transport of the carbohydrates (sometimes over long distances)
• unloading of the carbohydrates at sinks

Question 58

What are two ways in which we can measure phloem transport rates?

Answer 58

• aphid stylets
• radioactively-labelled carbon dioxide

Question 59

What animals consume phloem sap as part of their diet?

Answer 59

insects from a group called the Hemiptera which includes aphids, whitefly, mealybugs and psyllids

Question 60

How do Aphids consume phloem sap?

Answer 60

Aphids penetrate plant tissues to reach the phloem using mouth parts called stylets

Question 61

How can phloem transport rates be measured using aphids?

Answer 61

• if the aphid is anaesthetized and the stylet severed while they are feeding
• the phloem will continue to flow out of the stylet
• both the rate of flow and the composition of the sap can be analysed
• the closer the stylet is to the sink, the slower the rate at which the phloem sap will come out.

Question 62

What is an radioactive isotope of carbon?

Answer 62

Carbon-14

Question 63

How can radioactively-labelled carbon dioxide we used to measure phloem transport rates?

Answer 63

1. Radioactively-labelled carbon within carbon dioxide can be fixed by plants during photosynthesis
2. it will release radiation that can be detected either using film or radiation detectors
3. as the carbon is metabolized, it will be found in different molecules within the plant
4. both the formation and movement of radioactive molecules can be traced
5. A Geiger counter device can be used to measure the radiation levels in a crop of sunflowers

Question 63

How can radioactively-labelled carbon dioxide we used to measure phloem transport rates?

Answer 63

1. Radioactively-labelled carbon within carbon dioxide can be fixed by plants during photosynthesis
2. it will release radiation that can be detected either using film or radiation detectors
3. as the carbon is metabolized, it will be found in different molecules within the plant
4. both the formation and movement of radioactive molecules can be traced
5. A Geiger counter device can be used to measure the radiation levels in a crop of sunflowers

Question 64

What are 2 things to look out for when comparing xylem and phloem in light micrographs?

Answer 64

• xylem cells are generally larger than phloem cells
• wihitin one vascular bundle, phloem cells tend to be closer to the outside of the plant in stems and roots