Raven Test Bank Transport In Plants Chapter 36 - Biology 12e Complete Test Bank by Peter Raven. DOCX document preview.

Raven Test Bank Transport In Plants Chapter 36

Biology, 12e (Raven)

Chapter 36 Transport in Plants

1) The process by which water is "pulled" up through the xylem columns of plants as it evaporates out of the leaves is called

A) respiration.

B) transpiration.

C) osmosis.

D) anhydration.

E) stomatization.

2) The most important ion in controlling the movement of water into and out of the guard cells is

A) sodium.

B) hydrogen.

C) carbon.

D) nitrogen.

E) potassium.

3) Water is able to cross plant plasma membranes by a combination of

A) osmosis and aquaporins.

B) evaporation and diffusion.

C) root pressure and turgidity.

D) diffusion and phloem.

E) transpiration and Casparian strips.

4) On a short-term basis, water loss in plants may be controlled by the

A) bending of the petioles on the leaves.

B) closing of the stele in the roots.

C) closing of the stomata in the leaves to limit transpiration.

D) opening of the stomata in the leaves to allow more carbon dioxide to enter.

E) opening the Casparian strips in the roots.

5) Mangrove plants live in areas regularly flooded with salt water. Which of these is not a possible mechanism for controlling their salt balance?

A) The roots block salt uptake.

B) The succulent leaves contain large quantities of water that dilute salt that is absorbed.

C) Absorbed salt is secreted from special salt glands.

D) Modified roots emerge above the water level and help oxygen diffuse into the roots.

E) Excess salt is stored in special tissues.

6) Some plants are able to endure frequent flooding events because they contain a tissue with loose parenchyma cells and large air spaces called

A) xylem.

B) spongy mesophyll.

C) pneumatophores.

D) aerenchyma.

E) epidermal tissue.

7) Even in the absence of transpiration, some water can move into the roots and partially up the xylem columns. This phenomenon is due to

A) flooding.

B) stomatal opening.

C) root pressure.

D) proton pumps.

E) phloem translocation.

8) Which of the following statements does not apply to aquaporins?

A) They are water transport channels.

B) They are unique to plant cells.

C) They occur in the plasma membrane.

D) They speed up osmosis.

E) They do not alter the direction of water movement.

9) Which of the following statements about transport through phloem is true?

A) Transport only occurs from the roots to the shoot.

B) It is aided by root pressure.

C) The direction of flow can change at different times if the sources and sinks change.

D) No energy is required.

E) Mostly dissolved starch is transported.

10) Which of the following is not transported within the plant by the xylem and/or the phloem?

A) dissolved minerals

B) sucrose

C) growth-regulating hormones

D) water

E) starch

11) Turgor is most directly related to the plant cells'

A) total water potential.

B) pressure potential.

C) solute potential.

D) osmosis.

E) gravity potential.

12) Water moves through a plant by each of the following methods except

A) from cell to cell through plasmodesmata.

B) through the Casparian strip.

C) through the spaces between cells.

D) through vessel members.

E) from cell to cell across plasma membranes.

13) The movement of oxygen through the aquatic plant may depend on

A) osmotic absorption by the roots.

B) aquaporins.

C) negative pressures created by transpiration.

D) differences in the water potential of different tissues.

E) aerenchyma tissue.

14) Most of the water that evaporates from leaves passes out through the

A) cuticle.

B) ends of xylem vessels.

C) epidermis.

D) spaces between epidermal cells.

E) stomata.

15) Most of the water absorbed by the plant enters through the

A) root apical meristem.

B) root cap.

C) root hairs.

D) stomata.

E) lenticels.

16) Stomatal opening requires each of the following conditions, except

A) expenditure of energy.

B) a reduction of turgor in the guard cells.

C) water entering the guard cells by osmosis.

D) a lower water potential in the guard cells.

E) pumping of potassium ions into the guard cells.

17) The plasma membranes of root hair cells contain a variety of protein transport channels through which specific ions are transported, even against large concentration gradients, by

A) electron pumps.

B) carbohydrate pumps.

C) water pumps.

D) proton pumps.

E) root pumps.

18) A plant will usually wilt when which component of water potential reaches 0 MPa?

A) solute potential

B) turgor pressure

C) total water potential

D) gravity potential

19) Cavitation can occur when what happens?

A) Root pressure pushes water up the xylem.

B) Starch grains block the sieve tubes.

C) Gas bubbles expand inside a tracheid or vessel member.

D) Stomata get stuck closed.

E) Clouds block sunlight shining on the leaves.

20) Which of the following actions occurs in many plants when CO2 concentrations are high?

A) Guard cells lose turgor, and the stomata close.

B) Water evaporates at a higher rate than usual.

C) CAM photosynthesis fixes CO2 at night.

D) Oxygen is used by plants for photosynthesis.

E) Calcium ions are transported faster through the phloem.

21) The Calvin Cycle can only produce sugar if ________ can enter through the pores of the leaves.

A) O2

B) CO2

C) water

D) potassium

E) N2

22) Plants living in standing water often face which of the following problems?

A) increased CO2 levels

B) chilling of the roots

C) oxygen deprivation

D) loss of stomata

E) harmful root pressure

23) A plant is exposed to a toxin that blocks ABA receptor sites in the plasma membrane. What is the likely consequence of this exposure?

A) Oxygen deprivation will trigger the release of ethylene, which will in turn suppress root growth.

B) Gibberellin production will increase, allowing the plant to access more nutrients in the soil.

C) ABA will enter the cells by an alternative route and normal function will be restored.

D) The plant will lose excess water through transpiration and suffer dehydration.

E) The guard cells will become flaccid and gas exchange will cease.

24) Which of the following must occur in order to maintain a high pressure potential within guard cells?

A) Potassium ions must be actively transported out.

B) Energy must be constantly expended.

C) Water must exit guard cells by osmosis.

D) Stomata must take up more oxygen and less carbon dioxide.

E) The rate of transpiration must increase.

25) Mechanisms that evolved in plants to regulate the rate of water loss do not include

A) becoming dormant during dry times of the year.

B) losing leaves.

C) producing leaves that are thick and hard.

D) containing stomata in crypts or pits.

E) increasing the number of water vacuoles in the cells.

26) The uneven distribution of an impermeable solute on either side of a membrane will result in

A) an increase in oxygen deprivation.

B) proton pumping.

C) root pressure.

D) osmosis.

E) stomatal closing.

27) Most carbohydrates manufactured in leaves and other photosynthetic parts are transported through the phloem to the rest of the plant by the process of

A) transpiration.

B) translocation.

C) osmosis.

D) receptor-mediated transport.

E) turgor pressure.

28) Which of the following does not require expenditure of energy?

A) accumulation of ions inside a cell

B) transport against a concentration gradient

C) flow of sucrose and other carbohydrates once inside the sieve tubes

D) the loading and unloading of carbohydrates from the sieve tubes

E) opening or closing stomata

29) Which of the following hormones increases when plants are flooded?

A) gibberellin

B) auxin

C) ethylene

D) cytokinin

E) abscisic acid

30) Some plants can tolerate flooding conditions by

A) formation of aerenchyma.

B) opening their lenticels.

C) forming additional adventitious roots.

D) shedding their bark.

E) pumping water out of their roots.

31) The process of moving water through a plant by transpiration works because water molecules stick to each other with

A) turgor pressure.

B) osmosis.

C) ionic bonds.

D) adhesion.

E) hydrogen bonds.

32) Which of the following equations represents the total water potential of a plant?

A) s2 + p2 = w2

B) ψs = ψp + ψw

C) ψp = ψw + ψs

D) ψw = ψp + ψs

E) ψw = ψp _ ψs

33) Pure water without applied pressure has a water potential that is equal to

A) infinity.

B) 0.0 MPa.

C) 1.6 MPa.

D) -2.0 MPa.

E) atmospheric pressure.

34) Water molecules can "stick" to certain surfaces by

A) adhesion.

B) cohesion.

C) root pressure.

D) water pressure.

E) pneumatophores.

35) Water may be lost in the form of liquid from the surface of leaves through a process known as

A) guttation.

B) cohesion.

C) phloem loading.

D) mesophyll adhesion.

E) aeration.

36) The pressure-flow hypothesis describes

A) how hormones move through the phloem.

B) how carbohydrates enter the sieve tubes.

C) how carbohydrates in solution move through the phloem.

D) how water and minerals move through the xylem.

E) how carbohydrates and minerals move through the xylem.

Consider the following plant cells floating in an open beaker containing 0.2M sucrose. By definition, an open beaker has a pressure potential 0 MPa. Assume that the cells have come to equilibrium with the solution in the beaker.

Component

Beaker

Cell 1

Cell 2

Cell 3

Solute potential

Ψs

-0.5 MPa

-1.0 MPa

-0.75 MPa

-0.5 MPa

Pressure potential

Ψp

0.0 MPa

?

?

?

Total water potential

Ψw

-0.5 MPa

?

?

?

 

37) In Cell 1,

A) ψp = 0.0 MPa and ψw = 0.0 MPa.

B) ψp = 0.0 MPa and ψw = -1.0 MPa.

C) ψp = +0.5 MPa and ψw = -0.5 MPa.

D) ψp = -0.5 MPa and ψw = -0.5 MPa.

E) ψp = 0.0 MPa and ψw = +0.5 MPa.

38) In Cell 2,

A) ψp = 0.75 MPa and ψw = 0.0 MPa.

B) ψp = 0.0 MPa and ψw = -0.75 MPa.

C) ψp = -0.25 MPa and ψw = -0.5 MPa.

D) ψp = +0.25 MPa and ψw = -0.5 MPa.

E) ψp = +0.25 MPa and ψw = +0.25 MPa.

39) In Cell 3,

A) ψp = 0.0 MPa and ψw = -0.5 MPa.

B) ψp = 0.0 MPa and ψw = 0.0 MPa.

C) ψp = +0.5 MPa and ψw = -0.5 MPa.

D) ψp = -0.5 MPa and ψw = -0.5 MPa.

E) ψp = 0.0 MPa and ψw = +0.5 MPa.

40) Most often, the largest gradient in water potential is between

A) roots and soil water.

B) root xylem and shoot xylem.

C) xylem and phloem.

D) leaf cells and the intracellular spaces inside the leaves.

E) the relative humidity inside the leaf and the relative humidity outside the plant.

41) Mycorrhizal fungi interact with plants at the

A) stomata.

B) seed coat.

C) roots.

D) edge of ponds.

E) cuticle.

42) A large watermelon fruit is very heavy and contains nearly 90% water. Since the skin of a watermelon is thick and lacks stomata, transpiration does not "pull" water into the watermelon. So, how does all that water get into the fruit?

A) Root pressure pushes water into the watermelon.

B) Water enters by osmosis from the soil.

C) Water is pumped in by active transport.

D) Water is transported in the phloem along with the sugars while they are being translocated into the fruit.

E) Watermelons, like other fruit, contain an abundance of xylem.

43) Which of these structures is not likely to contain significant amounts of aerenchyma tissue?

A) mangrove pneumatophores

B) rice roots

C) water lily leaves

D) cypress "knees"

E) coconut tree roots

44) Halophytes are plants that live in saline soils. The high osmotic potential of the salt solution in the soil creates a very negative water potential. What can halophytes do so that water will flow into the roots?

A) They can close their stomata so that less water is lost through transpiration.

B) They can open all their stomata so that transpiration "pulls" more water into the roots.

C) They can increase the solute concentration in their roots creating a water potential that is more negative than the soil.

D) They can pump ions out of the plant creating a water potential in the roots that is more positive than the soil.

E) They can remove the mycorrhizal fungi from their roots decreasing the competition for water.

45) Which of these situations regarding phloem sources and sinks is not correct?

A) The root of a carrot plant is a source.

B) Young leaves are sinks.

C) A growing pumpkin is a sink.

D) In a seedling, the cotyledons would be sources.

E) During autumn, deciduous tree roots would be a sink.

Choose the letter of the best match from the following:

A. abscisic acid

B. trichomes

C. aquaporin

D. endodermis

E. stoma

46) Pore in plasma membrane that allows water movement.

47) Triggers K+ to pass rapidly out of guard cells.

48) Pore in leaves that regulates gas exchange.

49) Regulates movement of mineral ions into root xylem.

50) Reflects sunlight at leaf surface.

51) Closing the stomata for an extended period of time would lead to an increase in G3P in the mesophyll cells.

52) If the soil around a plant is treated with a fungicide, the plant may experience a decline in DNA synthesis.

53) You a given a plant tissue in lab and asked to determine if the tissue is a source or a sink. Microscopic analysis reveals an abundance of colorless parenchyma cells with plastids. Only one biochemical test reacts positively with your sample. In the presence of iodine, the plastids turn a dark purplish color. Based on this information you determine your sample is

A) a source because your sample is rich in carbohydrates.

B) a source because your sample contains plastids.

C) a sink because your sample is rich in carbohydrates.

D) both a source and sink because it contains both plastids and carbohydrates.

54) Cavitation would have no effect on translocation.

55) An application of too much fertilizer will negatively affect the movement of materials in the phloem.

56) A decrease in the availability of ATP in a root cell could decrease the water potential of the cell.

57) If a mutation decreased the radius of a xylem vessel threefold, there would be an 81-fold increase in the volume of liquid moving through the vessel.

58) An increase in root pressure will result in the rapid release of abscisic acid (ABA) and the subsequent opening of the stomata.

59) If the proton pumps of guard cell were damaged, transpiration would decrease.

Document Information

Document Type:
DOCX
Chapter Number:
36
Created Date:
Aug 21, 2025
Chapter Name:
Chapter 36 Transport In Plants
Author:
Peter Raven

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