9 - Transport in Plants Flashcards

Question 1

Q

What is a cotyledon?

Answer

A

An organ which acts as a food store for the developing embryo plant, and which forms the first leaves when the seed germinates

Question 2

Q

What is the difference between a monocot and a dicot?

Answer

A

Monocots have 1 cotyledon, dicots have 2

Question 3

Q

What is an arborescent plant?

Answer

A

A woody one like a tree with lots of tough tissue, which can survive for hundreds of years

Question 4

Q

What is a herbaceous plant?

Answer

A

One with lots of soft tissues and a relatively short lifespan

Question 5

Q

What is the pressure in the phloem of a plant?

Answer

A

Around 2000 kPa

Question 6

Q

What are the three main reasons that multicellular plants need transport systems?

Answer

A

Metabolic Demands 2. Size 3. Surface Area to Volume ratio

Question 7

Q

Why do plants need transport systems because of metabolic demands?

Answer

A

Many internal or underground parts of a plant cannot make their own glucose for energy via photosynthesis, so need glucose and oxygen transported to them. Hormones and mineral ions also need to be moved.

Question 8

Q

Why do mineral ions need to be moved around a plant?

Answer

A

So they can be moved to all cells for protein production

Question 9

Q

Why is the surface area to volume ratio not simple in plants?

Answer

A

The leaves are adapted to have a large surface area to volume ratio, but when taking into account the stems, trunks and roots the overall SA:V ratio may be quite small

Question 10

Q

Where are vascular bundles in the stem of a dicot and why?

Answer

A

Around the edges to give strength and support

Question 11

Q

Where are the vascular bundles in the root of a dicot and why?

Answer

A

In the middle to help the plant withstand the tugging strains that result as the stems and leaves are blown in the wind

Question 12

Q

Where is the main vein carrying the vascular bundle of a dicot’s leaf found and why?

Answer

A

The midrib of the leaf in order to help support the structure of the leaf

Question 13

Q

What other vascular tissues are found in a dicot leaf apart from the main vein?

Answer

A

Many small, branching veins which spread throughout the leaf and function in both transport and support

Question 14

Q

How is the main vascular bundle structured in the leaf of a dicot?

Answer

A

Xylem above phloem, vascular bundle roughly circular cross-section

Question 15

Q

How is the vascular bundle structured in the stem of a dicot?

Answer

A

Phloem on the outside, xylem on the inside, separated by a strip called the procambium (or just cambium)

Question 16

Q

What is the bit in the middle of a dicot stem called?

Answer

A

Pith, composed of soft spongy parenchyma cells

Question 17

Q

What is the area between vascular bundles in a dicot stem called?

Answer

A

Interfasicular parenchyma

Question 18

Q

What is the outermost layer of a plant stem called?

Answer

A

Epidermis

Question 19

Q

How is the vascular bundle of a dicot root arranged?

Answer

A

A ‘X’ shaped xylem with phloem vessels in the gaps of the X, with a ring called the endodermis enclosing all this

Question 20

Q

What is the tissue immediately surrounding a vascular bundle in a dicot root called?

Answer

A

Endodermis

Question 21

Q

What is the outermost layer of a dicot root called?

Answer

A

Exodermis

Question 22

Q

What layer is found immediately below the exodermis of a plant root?

Answer

A

Epidermis

Question 23

Q

What is the area between the vascular bundles and epidermis in a dicot root and stem called?

Question 24

Q

What are the two main functions of xylem in a plant?

Answer

A

Support 2. Transport of water and mineral ions

Question 25

Q

What is a feature of most cells found in the xylem?

Answer

A

Most are dead when functioning in the plant

Question 26

Q

What determines the rigidity of the xylem?

Answer

A

The shape of the lignin- some shapes give more support than others

Question 27

Q

What is the main part of xylem and what is its structure?

Answer

A

Xylem vessels, which are made up of long tubes of dead cells with no cytoplasm or end cell walls, thick, lignified walls and lots of unlignified ‘bordered pits’ in the walls for the movement of water

Question 28

Q

What are the two main tissues associated with xylem vessels in dicots?

Answer

A

Xylem parenchyma 2. Xylem fibers

Question 29

Q

If lignin is the 2nd most common natural polysaccharide, then what is the first?

Answer

A

Cellulose

Question 30

Q

What is tannin and what is its purpose?

Answer

A

A bitter, astringent-tasting chemical which protects plant tissue from attack by herbivores

Question 31

Q

What is xylem parenchyma and where is it found?

Answer

A

Thick-walled cells packed around the xylem vessels which store food and tannin deposits

Question 32

Q

What are xylem fibres?

Answer

A

Long cells with lignified secondary walls which provide additional strength, but do not carry water

Question 33

Q

How is lignin laid down in xylem vessels’ walls?

Answer

A

Can be a number of ways- rings, spirals or even relatively solid tubes with lots of small unlignified areas called bordered pits

Question 34

Q

What is special about sieve tube elements?

Answer

A

They have no nucleus, and the tonoplast and many organelles break down, leaving them full of phloem sap with only a thin layer of cytoplasm

Question 35

Q

What are sieve plates?

Answer

A

Holes in the end cell walls of sieve tube elements which let the phloem’s contents through

Question 36

Q

What do companion cells do?

Answer

A

Add support to sieve tube elements and also carry out living functions, such as producing ATP, for them

Question 37

Q

What is a sclereid?

Answer

A

A tissue associated with phloem which has cells with very thick cell walls

Question 38

Q

What tissues are associated with phloem tissues?

Answer

A

Fibres and sclereids

Question 39

Q

What links sieve tube elements and companion cells?

Answer

A

Many plasmodesmata (microscopic holes in the cell wall)

Question 40

Q

What is the turgor pressure in a typical leaf cell?

Answer

A

Around 1.5 MPa

Question 41

Q

What are some reasons that water is so important for plants?

Answer

A

Its evaporation helps keep them cool 2. Raw material for photosynthesis 3. Mineral ions and products of photosynthesis are transported in aqueous solution 4. Turgor drives cell expansion 5. Turgor (a.k.a. hydrostatic) pressure in plants helps provide a hydrostatic ‘skeleton’ to keep the plant rigid

Question 42

Q

Why are mineral ions actively moved into the cytoplasm of root hair cells?

Answer

A

To keep the concentration of them higher than in the soil so that water moves in down a concentration gradient

Question 43

Q

What are the two pathways that water can move along the root in?

Answer

A

Apoplastic and symplastic

Question 44

Q

Where does water move along in the symplastic pathway?

Answer

A

Along the interconnected (via plasmodesmata) cytoplasm of root cells (passing around the vacuole)

Question 45

Q

How does water move along the symplastic pathway?

Answer

A

The cells on the very edge and end of the root have high water potentials due to the absorption of water from the soil. This water potential is higher than the water potential of the next cell along, so water moves along the root by osmosis this way.

Question 46

Q

Where does water move along in the apoplastic pathway?

Answer

A

Along the cell walls and intercellular spaces

Question 47

Q

How does water move along the apoplastic pathway?

Answer

A

It fills the open spaces between fibres in the cellulose cell wall. As water moves into the xylem, the cohesive forces between it and water further back in the cell walls creates tension that causes water molecules to be pulled along, unencumbered by the loose network of cellulose fibres in the cell walls.

Question 48

Q

What is the Casparian Strip made of?

Answer

A

A waxy material called suberin

Question 49

Q

Why is water forced from the apoplastic to the symplastic pathway?

Answer

A

Because water travelling along the apoplastic can carry unwanted contaminants from the soil with it, and forcing it into the symplastic pathway allows the cell surface membrane to remove these contaminants

Question 50

Q

What is the Casparian strip and what is its purpose?

Answer

A

A waxy, impermeable layer in the cell wall of the endodermis, whose purpose is to force water from the apoplastic pathway to the symplastic pathway

Question 51

Q

What is the endodermis?

Answer

A

The layer of cells surrounding the vascular tissue of the roots

Question 52

Q

How is water moved from the endodermis to the xylem?

Answer

A

Mineral ions are actively pumped into the xylem, which creates a concentration gradient which causes water to move into the xylem via osmosis

Question 53

Q

What causes root pressure?

Answer

A

The active pumping of mineral ions into the xylem

Question 54

Q

What does root pressure do?

Answer

A

Gives water a ‘push’ up the xylem, although this is not usually the major factor in moving water up to the leaves

Question 55

Q

What are 4 pieces of evidence for the role of active transport in creating root pressure?

Answer

A

Xylem sap can exude from cut ends of sap at certain times- links to guttation 2. If levels of oxygen or respiratory substrates fall, root pressure falls 3. Cyanide prevents ATP production. If it is applied to root cells, root pressure disappears 4. Root pressure increases with a rise in temperature and falls with a drop, suggesting that chemical reactions occur

Question 56

Q

What is guttation?

Answer

A

Where xylem sap is forced out of pores at the end of the leaves in some conditions, such as at night when transpiration is low.

Question 57

Q

Where is water lost from leaf cells to?

Answer

A

The air spaces in the spongy mesophyll

Question 58

Q

What is transpiration?

Answer

A

The loss of water vapour from the stems and leaves of plants via stomata

Question 59

Q

Why do some stomata need to be open at night?

Answer

A

To allow oxygen in for cellular reactions such as aerobic respiration, as none is being produced by photosynthesis

Question 60

Q

What is the transpiration stream?

Answer

A

The movement of water from the moment it is absorbed in the roots of the leaf until it leaves as water vapour from stomata in the leaves

Question 61

Q

What is the cohesion-tension theory?

Answer

A

The model of water moving as a continuous stream from the roots all the way up to and across the leaves

Question 62

Q

According to the cohesion-tension theory, how does water move inside the leaf?

Answer

A

Water evaporates from cells in the leaves, causing their water potential to fall. This causes water to move in from an adjacent cell. This repeats all the way back to the xylem, where water moves into the first leaf cell by osmosis

Question 63

Q

According to the cohesion-tension theory, how does water move up the xylem?

Answer

A

Water molecules form hydrogen bonds with the carbohydrates in the walls of the xylem (known as adhesion), as well as with each other (known as cohesion), the combined effects of which cause water to move up the xylem via capillary action

Question 64

Q

What is capillary action?

Answer

A

Where water can be drawn up a narrow tube against gravity

Answer 64

A

Where water is drawn up the xylem in a continuous stream to replace that lost in the leaves via evaporation

Answer 65

A

The transpiration pull results in a tension in the xylem, helping move move water across the roots.

Answer 66

A

When a xylem vessel is broken, in most cases air is drawn in rather than water leaking out 2. In the case above, water can no longer be drawn up the xylem vessel, as the continuous stream of water molecules is broken 3. Changes in the diameter of trees; when transpiration is at its highest in the day, the tension in the xylem is the highest, so the diameter of the tree shrinks. The opposite occurs at night when transpiration is at its lowest.

Answer 67

A

A potometer, which measures water uptake instead

Answer 68

A

When turgor is low due to low water content, the asymmetrically thick inner cell walls of the guard cells close the stomatal aperture

Answer 69

A

Hormonal signals from the plant can trigger turgor loss from the guard cells, which closes the stomatal pore

Answer 70

A

They pump in solutes by active transport, which increases their turgor. Because of cellulose hoops the cells cannot expand in width so they do so in length- because the inner wall of the cells are thicker and less flexible, the cells change shape asymmetrically and open the pore

Answer 71

A

Temperature 2. Humidity 3. Wind speed 4. Availability of water in the soil 5. Light intensity

Answer 72

A

By increasing the kinetic energy of molecules, speeding up osmosis, diffusion and evaporation 2. It increases the concentration of water vapour that external air can hold before it becomes saturated

Answer 73

A

More humid air has a higher concentration of water molecules, so there is a lower concentration gradient and the air accepts less molecules through evaporation before becoming saturated

Answer 74

A

Increasing wind speed blows more water vapour away from the stomata, so there is a higher concentration gradient and more water will leave the leaf

Answer 75

A

If there is not enough water then the plant will be under water stress and will lose less water through transpiration- the opposite is true if it is very wet

Answer 76

A

In higher light intensities more photosynthesis will take place, so more gaseous exchange needs to take place through the stomata and more water will be lost through them

Answer 77

A

The products of photosynthesis moving around the plant

Answer 78

A

40 to 60 times higher

Answer 79

A

The movement of assimilates dissolved in water via the phloem from sources to sinks

Answer 80

A

Places where assimilates are made

Answer 81

A

Storage organs such as tubers or tap roots when they are unloading their assimilates 2. Green leaves and stems 3. Food stores in seeds when they germinate

Answer 82

A

The parts of a plant which require assimilates, and have assimilates delivered to them

Answer 83

A

Actively dividing meristems 2. Roots which are growing and/or actively absorbing mineral ions 3. Any parts of the plant laying down food stores such as seeds, storage organs or fruits

Answer 84

A

Storage organs such as tubers

Answer 85

A

Where a molecule such as glucose must be transported across a carrier/channel protein with an ion, such as Na⁺, in order for the protein to allow the molecule across

Answer 86

A

Assimilates are actively loaded into the sieve tubes of the phloem. This lowers water potential, so water enter the phloem from the xylem via companion cells.

Answer 87

A

Assimilates usually leave via diffusion to be used up here (in the sink). Removal of solutes causes water potential to rise, and water leaves by osmosis to lower it.

Answer 88

A

H⁺ ions are actively pumped out of companion cells into mesophyll cells 2. A high concentration of H⁺ builds up in mesophyll cells, causing the ions to move back into companion cells, taking sucrose with it via a co-transporter protein 3. This causes a high concentration of sucrose in companion cells, so sucrose moves by diffusion into sieve tube elements, lowering water potential 4. Water moves by osmosis into the sieve tube elements from surrounding cells such as the xylem, increasing turgor pressure in the elements and causing movement of water and assimilates by mass flow to the sinks

Answer 89

A

Many mitochondria to provide the necessary ATP for the active transport of hydrogen

Answer 90

A

Water and assimilates arrive in sieve tube elements in the sink 2. Sucrose diffuses into surrounding cells, which convert them into other substances such as starch 3. This lowers sucrose concentration, so more sucrose diffuses out of the sieve tube 4. The reduced sucrose in the sieve tube leads to an increase in water potential, so water moves out into surrounding cells by osmosis. 5. This reduces turgor pressure in the sieve tubes, and maintains mass flow in the phloem

Answer 91

A

If the mitochondria in companion cells are poisoned, active loading stops 2. Advances in microscopy mean we can see it happen, and see adaptations of companion cells to help it 3. Rate of movement of sucrose is 10,000 times quicker than by diffusion

Answer 92

A

Girdling- if you cut a ring of bark from a tree, thereby cutting off all phloem, which are found in the bark, the tree will bulge out above the cut as a new sink is formed 2. Aphids put their stylets into the bark of a tree where the phloem are and, if the fluids inside them are analysed, they can be found to contain many sugars

Answer 93

A

Unsure of the role of sieve plates in translocation 2. Sucrose seems to move through the phloem at the same rate regardless of concentration at the sink

Answer 94

A

Organisms adapted to survive in very dry conditions

Answer 95

A

Organisms adapted to survive in very wet conditions

Answer 96

A

Thick waxy cuticle, sunken stomata, large, deep root network or many roots near the surface, less stomata, leaves reduced to spines, less leaves, hairy leaves, curled leaves, specialised water storage parenchyma tissue in succulents, loss of leaves in dry season, dormancy in dry periods

Answer 97

A

It has a curled, ‘C’ shaped leaf, which creates a windless, humid environment for stomata to lose water into, as well as hairs near the stomata to collect water, after which it dribbles down to the roots for collection. Also has a very deep root network and an extensive system of shallow roots near the surface

Answer 98

A

Very thin/no waxy cuticle, many permanently open stomata on upper surfaces, reduced plant structure as plenty of water to support, wide, flat leaves to spread across surface of water, small roots, large SA of underwater stems and roots, air sacs to allow leaves and flowers to float (aerenchyma)

Answer 99

A

A specialised aerial root found in hydrophytes to ensure that they get enough air, which have many lenticels which allow the movement of air into woody tissue

Answer 100

A

Aerenchyma found in rice may provide a low-resistance pathway for methane produced by the rice plant to move into the atmosphere

Answer 101

A

Specialised parenchyma tissue formed in the stems, leaves and roots, which have many large air spaces (which seem to be formed by apoptosis in normal parenchyma), which makes stems and leaves more buoyant and forms a low-resistance pathway for the movement of substances such as oxygen to underwater tissues

Answer 102

A

Anoxic (low oxygen) conditions, such as is mud

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9 - Transport in Plants Flashcards

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