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Transport in Plants

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Title: Transport in Plants


1
Chapter 36 Transport in Plants
2
Question ?
  • How do plants move materials from one organ to
    the other ?

3
Levels of Plant Transport
  • 1. Cellular
  • 2. Short Distance
  • 3. Long Distance

4
Cellular Transport
  • The transport of solutes and water across cell
    membranes.
  • Types of transport
  • 1. Passive Transport
  • 2. Active Transport
  • 3. Water Transport

5
1. Passive Transport
  • Diffusion and Osmosis.
  • Requires no cellular energy.
  • Materials diffuse down concentration gradients.

6
Problems
  • Usually very slow.
  • How can diffusion be assisted?
  • Transport Proteins
  • Ex. K channel

7
Potassium Channel
  • Found in most plant cell membranes.
  • Allow K but not Na to pass.
  • Often gated to respond to environmental stimuli
    (see cell signaling)

8
2. Active Transport
  • Requires cell energy.
  • Moves solutes against a concentration gradient.
  • Ex Proton Pumps

9
Proton Pump
  • Uses ATP to move H out of cells.
  • H creates a membrane potential.
  • H allows cotransport.

10
Membrane Potentials
  • Allow cations to moved into the cell.
  • Ex Ca2, Mg2
  • Allow anions to move by co-transport.
  • Ex NO3

11
Summary
12
3. Water Transport
  • Osmosis - water moves from high concentration to
    low concentration.

13
Water Potential
  • The potential energy of water to move from one
    location to another.
  • Abbreviated as y

14
Problem
  • Cell wall creates a pressure in the cells.
  • Water potential must account for this pressure.
  • Pressure counteracts the tendency for water to
    move into plant cells.

15
Water Potential
  • Has two components
  • Pressure potential yr
  • Solute potential yp
  • y yr yp

16
Comment
  • See the Ts lab handout for more on water
    potential.

17
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18
Bulk Flow
  • The movement of water between two locations due
    to pressure or tension.

19
Bulk Flow
  • Much faster than osmosis.
  • Tension (negative pressure) pulls water from
    place to place.
  • May cause bulk flow against the diffusion
    gradient.

20
Plant Vacuoles
  • Create Turgor Pressure against the cell wall.
  • Affect water potential by controlling water
    concentrations inside cells.

21
Tonoplast
  • Name for the vacuole membrane.
  • Has proton pumps.
  • Comment genetic modification of these pumps
    gives plants salt tolerance.

22
Proton Pumps
  • Drives solutes inside the vacuole.
  • Lowers water potential (yp ) inside the vacuole.

23
Result
  • Water moves into the vacuole.
  • Vacuole swells.
  • Turgor pressure increases.

24
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25
Turgor Pressure
  • Important for non-woody plant support.
  • Wilting
  • Loss of turgor pressure.
  • Loss of water from cells.

26
Flaccid
Turgid
27
Aquaporins
  • Water specific facilitated diffusion transport
    channels.
  • Help water move more rapidly through lipid
    bilayers.

28
Aquaporins with GFP
29
Short Distance Transport
  • 1. Transmembrane route
  • 2. Symplast route
  • 3. Apoplast route

30
1. Transmembrane
  • Materials cross from cell to cell by crossing
    each cell's membranes and cell walls.

31
2. Symplast
  • The continuum of cytoplasm by plasmodesmata
    bridges between cells.

32
3. Apoplast
  • Extracellular pathway around and between cell
    walls.

33
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34
Long Distance Transport
  • Problem diffusion is too slow for long
    distances.
  • Answer tension and bulk flow methods.

35
Root Hairs
  • Main site of absorption of water and minerals.
  • Comment - older roots have cork and are not very
    permeable to water.

36
Root Cortex
  • Very spongy.
  • Apoplast route very common.

37
Problem
  • Can't control uptake of materials if the apoplast
    route is used.

38
Solution
  • Endodermis with its Casparian Strip.

39
Casparian Strip
  • Waxy layer of suberin.
  • Creates a barrier between the cortex and the
    stele.
  • Forces materials from apoplast into endodermis
    symplast.

40
Casparian Strip
Endodermis
41
Result
  • Plant can now control movement of materials into
    the stele.

42
Mycorrhizae
  • Symbiotic association of fungi with roots of
    plants.
  • Help with water and mineral absorption (replaces
    root hairs in some plants).
  • May also prevent toxins from entering the plant.

43
Mycorrhizae
44
Xylem Sap
  • Solution of water and minerals loaded into the
    xylem by the endodermis.
  • Endodermis - also prevents back flow of water and
    minerals out of the stele.

45
Xylem Sap Transport Methods
  • 1. Root Pressure
  • 2. Transpiration (Ts)

46
Root Pressure
  • Root cells load minerals into xylem.
  • Water potential (yp) is lowered.
  • Water flows into xylem.

47
Result
  • Volume of water in xylem increases
  • Xylem sap is pushed up the xylem tissues creating
    root pressure.

48
Comments
  • Root Pressure limited way to move xylem sap.
  • Most apparent at night.
  • Excess water may leave plant through Guttation.

49
Transpiration (Ts)
  • Evaporation of water from aerial plant parts.
  • Major force to pull xylem sap up tall trees.

50
TCTM Theory
  • Transpiration
  • Cohesion
  • Tension
  • Mechanism

51
How does TCTM work?
  • Water evaporates from leaves, especially from the
    cell walls of the spongy mesophyll.
  • Reason water potential of the air is usually
    much less than that of the cells.

52
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53
As water evaporates
  • Cohesion water molecules sticking together by H
    bonds.
  • Adhesion water molecules sticking to other
    materials (cell walls etc.).

54
Result
  • The loss of water from the leaves creates
    tension or negative pressure between the air
    and the water in the plant.

55
Tension causes
  • Xylem sap to move to replace the water lost from
    the mesophyll cells.

56
Xylem Sap
  • Is pulled by the resulting tension all the way
    down the plant to the roots and soil.

57
Ts Summary
  • Xylem sap moves along a continual chain of water
    potential from
    air? leaf? stem? roots? soil

58
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59
Comments
  • Tension is a negative pressure which causes a
    decreased in the size of xylem cells.
  • Xylem cells would collapse without secondary cell
    walls.

60
Factors that Affect Transpiration Rate
  • 1. Environmental
  • 2. Plant Structures

Multiple Layer Epidermis
Stomatal Crypt
61
Homework
  • Read Chapter 36, 39
  • Chapter 36 Mon. 4/16
  • Test 2 next week Chapters 29, 30, 35, 36. A
    few questions may come from 37, 38 and possible
    39.

62
Environmental Factors
  • 1. Humidity
  • 2. Temperature
  • 3. Light
  • 4. Soil Water Content
  • 5. Wind

63
Plant Structure Factors
  • 1. Cuticle
  • 2. Stomate Number
  • 3. Hairs

64
Stomates
  • Openings in the epidermis that allow water and
    gas exchange.
  • Controlled by Guard Cells.
  • Control rate of Ts and Ps.

65
Guard Cells
  • Turgid Swell - open stomata.
  • Flaccid Shrink - close stomata.
  • Size of the cells is a result of turgor pressure
    changes.

66
Turgid - Open
Flaccid - Closed
67
Turgor Pressure of Guard cells
  • Controlled by K concentrations.

68
To Open Stomata
  • 1. K enters the guard cells.
  • 2. Water potential lowered.
  • 3. Water enters guard cells.
  • 4. Turgor pressure increases.
  • 5. Guard cells swell and Stomata opens.

69
To Close Stomata
  • 1. K leaves guard cells.
  • 2. Water leaves guard cells.
  • 3. Turgor pressure decreases.
  • 4. Guard cells shrink and Stomata close.

70
K Movement
  • Regulated by proton pumps and K channels.
  • Controlled by
  • Light (Blue)
  • CO2 concentrations
  • Abscisic Acid (water stress)

71
Comment
  • Plant must balance loss of water by transpiration
    with CO2 uptake for Ps.

72
Adaptations for Balance
  • C4 Ps
  • CAM Ps

73
Phloem Transport
  • Moves sugars (food).
  • Transported in live cells.
  • Ex Sieve Companion Cells

74
Source - Sink Transport
  • Model for movement of phloem sap from a Source to
    a Sink.

75
Source
  • Sugar production site
  • Ex Ps Starch breakdown in a
    storage area.

76
Sink
  • Sugar uptake site.
  • Ex Growing areas Storage areas
    Fruits and seeds

77
Comment
  • The same organ can serve as a source or a sink
    depending on the season.

78
Result
  • Phloem transport can go in two directions even in
    the same vascular bundle.

79
Xylem Transport In Contrast to Phloem
  • Usually unidirectional.
  • Endodermis prevents back flow.
  • Dead cells.

80
Phloem Loading at the Source
  • 1. Diffusion
  • 2. Transfer Cells
  • 3. Active Transport

81
Phloem Loading
82
Transfer Cells
  • Modified cell with ingrowths of cell wall to
    provide more surface area for sugar diffusion.

83
Result
  • Sugar loaded into phloem.
  • Water potential (yp) decreases.
  • Bulk flow is created.

84
Bulk Flow
  • Movement of water into phloem.
  • Pressure forces phloem sap to move toward the
    sink.

85
At the Sink
  • Sugar is removed.
  • Water potential is raised.
  • Water moves out of phloem over to xylem.

86
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87
Phloem summary
  • Source - builds pressure.
  • Sink - reduces pressure.
  • Pressure caused by
  • Sugar content changes
  • Water potential changes

88
Comment
  • Plants move materials without "moving" parts,
    unlike animals.

89
Summary
  • Know various ways plants use to move materials.
  • Know how Ts works and the factors that affect Ts.
  • Know how phloem transport works.
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