1. Plant Responses to Internal and External Signals
Chapter 39
Plant Responses to Internal and External Signals

2. AP Biology Frameworks
2.E.1 Timing and coordination of specific events are necessary for the normal development of an organism, and these events are regulated by a variety of mechanisms.
2.E.2 Timing and coordination of physiological events are regulated by multiple mechanisms.
2.E.3 Timing and coordination of behavior are regulated by various mechanisms and are important in natural selection.

3. Plants
Physiological events involve interactions between environmental stimuli and internal molecular signals.

4. Signal Transduction Pathway
???

5. Plant Hormones
Coordinate growth, development and response to stimuli.
Auxin
Cytokinins
Gibberellins
Brassinosteroids
Abscisic acid
Ethylene

6. Light is a major environmental stimulus for plants.
Light cues many key events in plant growth and development
Phototropism – response to the presence of light

7. Environmental Stimulus and Hormones Working Together!
In 1880, Charles Darwin and his son Francis designed an experiment to determine what part of the coleoptile senses light. In 1913, Peter Boysen-Jensen conducted an experiment to determine how the signal for phototropism is transmitted.
EXPERIMENT
In the Darwins’ experiment, a phototropic response occurred only when light could reach the tip of coleoptile. Therefore, they concluded that only the tip senses light. Boysen-Jensen observed that a phototropic response occurred if the tip was separated by a permeable barrier (gelatin) but not if separated by an impermeable solid barrier (a mineral called mica). These results suggested that the signal is a light-activated mobile chemical.
CONCLUSION
RESULTS
Control
Darwin and Darwin (1880)
Boysen-Jensen (1913)
Light
Shaded
side of
coleoptile
Illuminated
Tip
removed
Tip covered
by opaque
cap
covered
by trans- parent cap
Base covered
by opaque shield
Tip separated
by gelatin block
by mica
Figure 39.5

8. Relate phototropism in plants to natural selection.

9. Biological Clocks and Circadian Rhythms
Internal and external signals regulate a variety of physiological responses that synchronize with environmental cycles and cues.
Ex. Many plant processes oscillate during the day.
Many legumes lower their leaves in the evening and raise them in the morning
Noon
Midnight

10. Cyclical responses to environmental stimuli are called circadian rhythms
Circadian Rhythms - The physiological cycle that is present in all eukaryotes and persists even in the absence of external cues.
are approximately 24 hours long
can be entrained to exactly 24 hours by the day/night cycle (environmental cues)

11. Responses to seasons (night length)
Photoperiodism – responses to changes in length of night
Flowering in short-day plants vs. long-day plants.

12. Critical Night Length
In the 1940s, researchers discovered that flowering and other responses to photoperiod are actually controlled by night length, not day length
EXPERIMENT
During the 1940s, researchers conducted experiments in which periods of darkness were interrupted with brief exposure to light to test how the light and dark portions of a photoperiod affected flowering in “short-day” and “long-day” plants.
RESULTS
Darkness
Flash of light
24 hours
Critical dark period
Light
(a) “Short-day” plants flowered only if a period of continuous darkness was longer than a critical dark period for that particular species (13 hours in this example). A period of darkness can be ended by a brief exposure to light.
(b) “Long-day” plants flowered only if a period of continuous darkness was shorter than a critical dark period for that particular species (13 hours in this example).
CONCLUSION
The experiments indicated that flowering of each species was determined by a critical period of darkness (“critical night length”) for that species, not by a specific period of light. Therefore, “short-day” plants are more properly called “long-night” plants, and “long-day” plants are really “short-night” plants.
Figure 39.22

13. Besides light, what other environmental stimuli can affect plant growth/development?
Gravity
Mechanical stimuli
Drought
Flooding
Salt stress
Heat stress
Cold stress
Defense against herbivores
Defense against pathogens

14. Choose 1 plant hormone and create a visual that depicts the effect of the hormone on the plant.
Choose one stimulus, besides light, that a plant might respond to and create a visual depiction of this response.

15. 39.5 Plants respond to attacks by herbivores and pathogens.
2.D.4 Plants and animals have a variety of chemical defenses against infections that affect dynamic homeostasis.

16. Most of a plant’s interactions with other organisms are not beneficial to the plant.
Herbivores
Infection by viruses, bacteria, fungi…

17. Plant defenses against herbivores:
Physical defenses  thorns
Chemical defenses  distasteful or toxic compounds
Recruit predatory animals

18. Some plants even “recruit” predatory animals
That help defend the plant against specific herbivores
Recruitment of parasitoid wasps that lay their eggs within caterpillars 4 3
Synthesis and release of volatile attractants 1
Chemical in saliva
Wounding 2
Signal transduction pathway
Figure 39.29

19. Plant defenses against pathogens:
Physical barrier (epidermis)
Disease resistance genes
Hypersensitive response
Systemic acquired resistance

20. Plant Responses to Pathogen Invasions
A hypersensitive response against an avirulent pathogen
Seals off the infection and kills both pathogen and host cells in the region of the infection
4 Before they die, infected cells release a chemical signal, probably salicylic acid.
3 In a hypersensitive response (HR), plant cells produce anti- microbial molecules, seal off infected areas by modifying their walls, and then destroy themselves. This localized response produces lesions and protects other parts of an infected leaf.
Signal
5 The signal is
distributed to the
rest of the plant. 4 5
Hypersensitive response
Signal transduction pathway 6 3
6 In cells remote from the infection site, the chemical initiates a signal transduction pathway.
Signal transduction pathway 2
Acquired resistance 7
2 This identification
step triggers a
signal transduction
pathway. 1
7 Systemic acquired
resistance is activated: the production of molecules that help protect the cell against a diversity of pathogens for several days.
Avirulent pathogen
1 Specific resistance is
based on the
binding of ligands
from the pathogen
to receptors in
plant cells.
R-Avr recognition and
hypersensitive response
Systemic acquired
resistance
Figure 39.31

21. Systemic Acquired Resistance
Systemic acquired resistance (SAR)
Is a set of generalized defense responses in organs distant from the original site of infection
Is triggered by the signal molecule salicylic acid

23. Defenses Against herbivores: Thorns (physical)
Production of distasteful/toxic compounds (chemical)
“Recruiting” predatory animals to help defend the plant

24. Some plants even “recruit” predatory animals
That help defend the plant against specific herbivores
Recruitment of parasitoid wasps that lay their eggs within caterpillars 4 3
Synthesis and release of volatile attractants 1
Chemical in saliva
Wounding 2
Signal transduction pathway
Figure 39.29

25. Defenses against pathogens
Epidermis
Disease resistance genes (R) which can lead to:
Hypersensitive response
Systemic acquired resistance

26. Plant Responses to Pathogen Invasions
A hypersensitive response against an avirulent pathogen
Seals off the infection and kills both pathogen and host cells in the region of the infection
4 Before they die, infected cells release a chemical signal, probably salicylic acid.
3 In a hypersensitive response (HR), plant cells produce anti- microbial molecules, seal off infected areas by modifying their walls, and then destroy themselves. This localized response produces lesions and protects other parts of an infected leaf.
Signal
5 The signal is
distributed to the
rest of the plant. 4 5
Hypersensitive response
Signal transduction pathway 6 3
6 In cells remote from the infection site, the chemical initiates a signal transduction pathway.
Signal transduction pathway 2
Acquired resistance 7
2 This identification
step triggers a
signal transduction
pathway. 1
7 Systemic acquired
resistance is activated: the production of molecules that help protect the cell against a diversity of pathogens for several days.
Avirulent pathogen
1 Specific resistance is
based on the
binding of ligands
from the pathogen
to receptors in
plant cells.
R-Avr recognition and
hypersensitive response
Systemic acquired
resistance
Figure 39.31

27. Systemic Acquired Resistance
Systemic acquired resistance (SAR)
Is a set of generalized defense responses in organs distant from the original site of infection
Is triggered by the signal molecule salicylic acid

28. Overview: Stimuli and a Stationary Life
Plants, being rooted to the ground
Must respond to whatever environmental change comes their way

29. For example, the bending of a grass seedling toward light
Begins with the plant sensing the direction, quantity, and color of the light
Figure 39.1

30. Plants have cellular receptors
Concept 39.1: Signal transduction pathways link signal reception to response
Plants have cellular receptors
That they use to detect important changes in their environment
For a stimulus to elicit a response
Certain cells must have an appropriate receptor

31. A potato left growing in darkness
Will produce shoots that do not appear healthy, and will lack elongated roots
These are morphological adaptations for growing in darkness
Collectively referred to as etiolation
(a) Before exposure to light. A dark-grown potato has tall, spindly stems and nonexpanded leaves—morphological adaptations that enable the shoots to penetrate the soil. The roots are short, but there is little need for water absorption because little water is lost by the shoots.
Figure 39.2a

32. After the potato is exposed to light
The plant undergoes profound changes called de-etiolation, in which shoots and roots grow normally
Figure 39.2b
(b) After a week’s exposure to natural daylight. The potato plant begins to resemble a typical plant with broad green leaves, short sturdy stems, and long roots. This transformation begins with the reception of light by a specific pigment, phytochrome.

33. The potato’s response to light
Is an example of cell-signal processing
Figure 39.3
CELL
WALL
CYTOPLASM
  1 Reception
2 Transduction
3 Response
Receptor
Relay molecules
Activation
of cellular
responses
Hormone or
environmental
stimulus
Plasma membrane

34. Internal and external signals are detected by receptors
Reception
Internal and external signals are detected by receptors
Proteins that change in response to specific stimuli

35. Transduction Second messengers
Transfer and amplify signals from receptors to proteins that cause specific responses

36. An example of signal transduction in plants
1 Reception
  2 Transduction
3 Response
CYTOPLASM
Plasma
membrane
Phytochrome
activated
by light
Cell
wall
Light
cGMP
Second messenger
produced
Specific
protein
kinase 1
Transcription
factor 1
NUCLEUS P
Translation
De-etiolation
(greening)
response
proteins
Ca2+
Ca2+ channel
opened
kinase 2
factor 2
2 One pathway uses cGMP as a second messenger that activates a specific protein kinase.The other pathway involves an increase in cytoplasmic Ca2+ that activates another specific protein kinase.
3 Both pathways lead to expression
of genes for proteins that function in the de-etiolation (greening) response.
1 The light signal is detected by the phytochrome receptor, which then activates at least two signal transduction pathways.
Figure 39.4

37. Ultimately, a signal transduction pathway
Response
Ultimately, a signal transduction pathway
Leads to a regulation of one or more cellular activities
In most cases
These responses to stimulation involve the increased activity of certain enzymes

38. Transcriptional Regulation
Transcription factors bind directly to specific regions of DNA
And control the transcription of specific genes

39. Post-Translational Modification of Proteins
Involves the activation of existing proteins involved in the signal response

40. De-Etioloation (“Greening”) Proteins
Many enzymes that function in certain signal responses are involved in photosynthesis directly
While others are involved in supplying the chemical precursors necessary for chlorophyll production

41. Concept 39.2: Plant hormones help coordinate growth, development, and responses to stimuli
Are chemical signals that coordinate the different parts of an organism

42. The Discovery of Plant Hormones
Any growth response
That results in curvatures of whole plant organs toward or away from a stimulus is called a tropism
Is often caused by hormones

43. Charles Darwin and his son Francis
Conducted some of the earliest experiments on phototropism, a plant’s response to light, in the late 19th century

44. EXPERIMENT CONCLUSION Figure 39.5
In 1880, Charles Darwin and his son Francis designed an experiment to determine what part of the coleoptile senses light. In 1913, Peter Boysen-Jensen conducted an experiment to determine how the signal for phototropism is transmitted.
EXPERIMENT
In the Darwins’ experiment, a phototropic response occurred only when light could reach the tip of coleoptile. Therefore, they concluded that only the tip senses light. Boysen-Jensen observed that a phototropic response occurred if the tip was separated by a permeable barrier (gelatin) but not if separated by an impermeable solid barrier (a mineral called mica). These results suggested that the signal is a light-activated mobile chemical.
CONCLUSION
RESULTS
Control
Darwin and Darwin (1880)
Boysen-Jensen (1913)
Light
Shaded
side of
coleoptile
Illuminated
Tip
removed
Tip covered
by opaque
cap
covered
by trans- parent cap
Base covered
by opaque shield
Tip separated
by gelatin block
by mica
Figure 39.5

45. In 1926, Frits Went
Went concluded that a coleoptile curved toward light because its dark side had a higher concentration of the growth-promoting chemical, which he named auxin.
The coleoptile grew straight if the chemical was distributed evenly. If the chemical was distributed unevenly, the coleoptile curved away from the side with the block, as if growing toward light, even though it was grown in the dark.
Excised tip placed
on agar block
Growth-promoting chemical diffuses into agar block
Agar block with chemical stimulates growth
Control (agar block lacking chemical) has no effect
Control
Offset blocks cause curvature
RESULTS
CONCLUSION
In 1926, Frits Went’s experiment identified how a growth-promoting chemical causes a coleoptile to grow toward light. He placed coleoptiles in the dark and removed their tips, putting some tips on agar blocks that he predicted would absorb the chemical. On a control coleoptile, he placed a block that lacked the chemical. On others, he placed blocks containing the chemical, either centered on top of the coleoptile to distribute the chemical evenly or offset to increase the concentration on one side.
EXPERIMENT
Extracted the chemical messenger for phototropism, auxin, by modifying earlier experiments
Figure 39.6

46. A Survey of Plant Hormones

47. In general, hormones control plant growth and development
By affecting the division, elongation, and differentiation of cells
Plant hormones are produced in very low concentrations
But a minute amount can have a profound effect on the growth and development of a plant organ

48. Auxin
The term auxin
Is used for any chemical substance that promotes cell elongation in different target tissues

49. Auxin transporters
Move the hormone out of the basal end of one cell, and into the apical end of neighboring cells
Cell 1
Cell 2
100 m
Epidermis
Cortex
Phloem
Xylem
Pith
Basal end of cell
25 m
To investigate how auxin is transported unidirectionally, researchers designed an experiment to identify the location of the auxin transport protein. They used a greenish-yellow fluorescent molecule to label antibodies that bind to the auxin transport protein. They applied the antibodies to longitudinally sectioned Arabidopsis stems.
RESULTS
The left micrograph shows that the auxin transport protein is not found in all tissues of the stem, but only in the xylem parenchyma. In the right micrograph, a higher magnification reveals that the auxin transport protein is primarily localized to the basal end of the cells.
CONCLUSION
The results support the hypothesis that concentration of the auxin transport protein at the basal ends of cells is responsible for polar transport of auxin.
EXPERIMENT
Figure 39.7

50. The Role of Auxin in Cell Elongation
According to a model called the acid growth hypothesis
Proton pumps play a major role in the growth response of cells to auxin

51. Cell elongation in response to auxin
3 Wedge-shaped expansins, activated
by low pH, separate cellulose microfibrils from
cross-linking polysaccharides. The exposed cross-linking
polysaccharides are now more accessible to cell wall enzymes.
Expansin
CELL WALL
Cell wall enzymes
Cross-linking cell wall polysaccharides
Microfibril H+
ATP
Plasma membrane
Plasma
membrane
Cell
wall
Nucleus
Vacuole
Cytoplasm
H2O
4 The enzymatic cleaving of the cross-linking
polysaccharides allows the microfibrils to slide. The extensibility of the cell wall is increased. Turgor causes the cell to expand.
2 The cell wall becomes more acidic.
1 Auxin increases the activity of proton pumps.
5 With the cellulose loosened,
the cell can elongate.
Figure 39.8

52. Lateral and Adventitious Root Formation
Auxin
Is involved in the formation and branching of roots

53. Auxins as Herbicides
An overdose of auxins
Can kill eudicots

54. Auxin affects secondary growth
Other Effects of Auxin
Auxin affects secondary growth
By inducing cell division in the vascular cambium and influencing differentiation of secondary xylem

55. Cytokinins
Cytokinins
Stimulate cell division

56. Control of Cell Division and Differentiation
Cytokinins
Are produced in actively growing tissues such as roots, embryos, and fruits
Work together with auxin

57. Control of Apical Dominance
Cytokinins, auxin, and other factors interact in the control of apical dominance
The ability of a terminal bud to suppress development of axillary buds
Axillary buds
Figure 39.9a

58. If the terminal bud is removed
Plants become bushier
“Stump” after removal of apical bud
Lateral branches
Figure 39.9b

59. Cytokinins retard the aging of some plant organs
Anti-Aging Effects
Cytokinins retard the aging of some plant organs
By inhibiting protein breakdown, stimulating RNA and protein synthesis, and mobilizing nutrients from surrounding tissues

60. Gibberellins have a variety of effects
Such as stem elongation, fruit growth, and seed germination

61. Gibberellins stimulate growth of both leaves and stems In stems
Stem Elongation
Gibberellins stimulate growth of both leaves and stems
In stems
Gibberellins stimulate cell elongation and cell division

62. Fruit Growth In many plants
Both auxin and gibberellins must be present for fruit to set

63. Gibberellins are used commercially
In the spraying of Thompson seedless grapes
Figure 39.10

64. Germination
After water is imbibed, the release of gibberellins from the embryo
Signals the seeds to break dormancy and germinate
2 The aleurone responds by synthesizing and secreting digestive enzymes that hydrolyze stored nutrients in the endosperm. One example is -amylase, which hydrolyzes
starch. (A similar enzyme in our saliva helps in digesting bread and other starchy foods.)
Aleurone
Endosperm
Water
Scutellum
(cotyledon) GA
-amylase
Radicle
Sugar
1 After a seed imbibes water, the embryo releases gibberellin (GA)
as a signal to the aleurone, the thin outer layer of the endosperm.
3 Sugars and other nutrients absorbed from the endosperm by the scutellum (cotyledon) are consumed during growth of the embryo into a seedling. 2
Figure 39.11

65. 2 The aleurone responds by synthesizing and secreting digestive enzymes that hydrolyze stored nutrients in the endosperm. One example is -amylase, which hydrolyzes
starch. (A similar enzyme in our saliva helps in digesting bread and other starchy foods.)
Aleurone
Endosperm
Water
Scutellum
(cotyledon) GA
-amylase
Radicle
Sugar 2
1 After a seed imbibes water, the embryo releases gibberellin (GA)
as a signal to the aleurone, the thin outer layer of the endosperm.
3 Sugars and other nutrients absorbed from the endosperm by the scutellum (cotyledon) are consumed during growth of the embryo into a seedling.

66. Brassinosteroids Brassinosteroids
Are similar to the sex hormones of animals
Induce cell elongation and division

67. Two of the many effects of abscisic acid (ABA) are
Seed dormancy
Drought tolerance

68. Seed dormancy has great survival value
Because it ensures that the seed will germinate only when there are optimal conditions

69. Precocious germination is observed in maize mutants
That lack a functional transcription factor required for ABA to induce expression of certain genes
Figure 39.12
Coleoptile

70. ABA is the primary internal signal
Drought Tolerance
ABA is the primary internal signal
That enables plants to withstand drought

71. Plants produce ethylene
In response to stresses such as drought, flooding, mechanical pressure, injury, and infection

72. The Triple Response to Mechanical Stress
Ethylene induces the triple response
Which allows a growing shoot to avoid obstacles
Ethylene induces the triple response in pea seedlings, with increased ethylene concentration causing increased response.
CONCLUSION
Germinating pea seedlings were placed in the
dark and exposed to varying ethylene concentrations. Their growth was compared with a control seedling not treated with ethylene.
EXPERIMENT
All the treated seedlings exhibited the triple response. Response was greater with increased concentration.
RESULTS
0.00
0.10
0.20
0.40
0.80
Ethylene concentration (parts per million)
Figure 39.13

73. Ethylene-insensitive mutants
Fail to undergo the triple response after exposure to ethylene
Figure 39.14a
ein mutant

74. Other types of mutants
Undergo the triple response in air but do not respond to inhibitors of ethylene synthesis
ctr mutant
Figure 39.14b

75. A summary of ethylene signal transduction mutants
Control
Ethylene added
Ethylene synthesis
inhibitor
Wild-type
Ethylene insensitive
(ein)
Ethylene
overproducing (eto)
Constitutive triple
response (ctr)
Figure 39.15

76. Apoptosis: Programmed Cell Death
A burst of ethylene
Is associated with the programmed destruction of cells, organs, or whole plants

77. A change in the balance of auxin and ethylene controls leaf abscission
The process that occurs in autumn when a leaf falls
0.5 mm
Protective layer
Abscission layer
Stem
Petiole
Figure 39.16

78. A burst of ethylene production in the fruit
Fruit Ripening
A burst of ethylene production in the fruit
Triggers the ripening process

79. Systems Biology and Hormone Interactions
Interactions between hormones and their signal transduction pathways
Make it difficult to predict what effect a genetic manipulation will have on a plant
Systems biology seeks a comprehensive understanding of plants
That will permit successful modeling of plant functions

80. Concept 39.3: Responses to light are critical for plant success
Light cues many key events in plant growth and development
Effects of light on plant morphology
Are what plant biologists call photomorphogenesis

81. Plants not only detect the presence of light
But also its direction, intensity, and wavelength (color)
A graph called an action spectrum
Depicts the relative response of a process to different wavelengths of light

82. Phototropic effectiveness relative to 436 nm
Action spectra
Are useful in the study of any process that depends on light
Researchers exposed maize (Zea mays) coleoptiles to violet, blue, green, yellow, orange, and red light to test which wavelengths stimulate the phototropic bending toward light.
EXPERIMENT
RESULTS
The graph below shows phototropic effectiveness (curvature per photon) relative to effectiveness of light with a wavelength of 436 nm. The photo collages show coleoptiles before and after 90-minute exposure to side lighting of the indicated colors. Pronounced curvature occurred only with wavelengths below 500 nm and was greatest with blue light.
Wavelength (nm)
1.0
0.8
0.6
0.2
450
500
550
600
650
700
Light
Time = 0 min.
Time = 90 min.
0.4
400
Phototropic effectiveness relative to 436 nm
The phototropic bending toward light is caused by a photoreceptor that is sensitive to blue and violet light, particularly blue light.
Figure 39.17
CONCLUSION

83. Research on action spectra and absorption spectra of pigments
Led to the identification of two major classes of light receptors: blue-light photoreceptors and phytochromes

84. Blue-Light Photoreceptors
Various blue-light photoreceptors
Control hypocotyl elongation, stomatal opening, and phototropism

85. Phytochromes as Photoreceptors
Regulate many of a plant’s responses to light throughout its life

86. Phytochromes and Seed Germination
Studies of seed germination
Led to the discovery of phytochromes

87. In the 1930s, scientists at the U.S. Department of Agriculture
Determined the action spectrum for light-induced germination of lettuce seeds
Dark (control)
Dark
Dark

88. EXPERIMENT
During the 1930s, USDA scientists briefly exposed batches of lettuce seeds to red light or far-red light to test the effects on germination. After the light exposure, the seeds were placed in the dark, and the results were compared with control seeds that were not exposed to light.
The bar below each photo indicates the sequence of red-light exposure, far-red light exposure, and darkness. The germination rate increased greatly in groups of seeds that were last exposed to red light (left). Germination was inhibited in groups of seeds that were last exposed to far-red light (right).
RESULTS
Dark (control)
Dark
Red
Far-red
CONCLUSION
Red light stimulated germination, and far-red light inhibited germination. The final exposure was the determining factor. The effects of red and far-red light were reversible.
Figure 39.18

89. A phytochrome
Is the photoreceptor responsible for the opposing effects of red and far-red light
A phytochrome consists of two identical proteins joined to form
one functional molecule. Each of these proteins has two domains.
Chromophore
Photoreceptor activity. One domain,
which functions as the photoreceptor,
is covalently bonded to a nonprotein
pigment, or chromophore.
Kinase activity. The other domain
has protein kinase activity. The
photoreceptor domains interact with the kinase domains to link light reception to cellular responses triggered by the kinase.
Figure 39.19

90. Phytochromes exist in two photoreversible states
With conversion of Pr to Pfr triggering many developmental responses
Synthesis
Far-red
light
Red light
Slow conversion
in darkness
(some plants)
Responses:
seed germination,
control of
flowering, etc.
Enzymatic
destruction
Pfr Pr
Figure 39.20

91. Phytochromes and Shade Avoidance
The phytochrome system
Also provides the plant with information about the quality of light
In the “shade avoidance” response of a tree
The phytochrome ratio shifts in favor of Pr when a tree is shaded

92. Biological Clocks and Circadian Rhythms
Many plant processes
Oscillate during the day

93. Many legumes
Lower their leaves in the evening and raise them in the morning
Noon
Midnight
Figure 39.21

94. Cyclical responses to environmental stimuli are called circadian rhythms
And are approximately 24 hours long
Can be entrained to exactly 24 hours by the day/night cycle

95. The Effect of Light on the Biological Clock
Phytochrome conversion marks sunrise and sunset
Providing the biological clock with environmental cues

96. Photoperiodism and Responses to Seasons
Photoperiod, the relative lengths of night and day
Is the environmental stimulus plants use most often to detect the time of year
Photoperiodism
Is a physiological response to photoperiod

97. Photoperiodism and Control of Flowering
Some developmental processes, including flowering in many species
Requires a certain photoperiod

98. Critical Night Length
In the 1940s, researchers discovered that flowering and other responses to photoperiod
Are actually controlled by night length, not day length
EXPERIMENT
During the 1940s, researchers conducted experiments in which periods of darkness were interrupted with brief exposure to light to test how the light and dark portions of a photoperiod affected flowering in “short-day” and “long-day” plants.
RESULTS
Darkness
Flash of light
24 hours
Critical dark period
Light
(a) “Short-day” plants flowered only if a period of continuous darkness was longer than a critical dark period for that particular species (13 hours in this example). A period of darkness can be ended by a brief exposure to light.
(b) “Long-day” plants flowered only if a period of continuous darkness was shorter than a critical dark period for that particular species (13 hours in this example).
CONCLUSION
The experiments indicated that flowering of each species was determined by a critical period of darkness (“critical night length”) for that species, not by a specific period of light. Therefore, “short-day” plants are more properly called “long-night” plants, and “long-day” plants are really “short-night” plants.
Figure 39.22

99. Action spectra and photoreversibility experiments
Show that phytochrome is the pigment that receives red light, which can interrupt the nighttime portion of the photoperiod
Figure 39.23
A unique characteristic of phytochrome is reversibility in response to red and far-red light. To test whether phytochrome is the pigment measuring interruption of dark periods, researchers observed how flashes of red light and far-red light affected flowering in “short-day” and “long-day” plants.
EXPERIMENT
RESULTS
CONCLUSION
A flash of red light shortened the dark period. A subsequent flash of far-red light canceled the red light’s effect. If a red flash followed a far-red flash, the effect of the far-red light was canceled. This reversibility indicated that it is phytochrome that measures the interruption of dark periods. 24 20 16 12 8 4
Hours
Short-day (long-night) plant
Long-day (short-night) plant R FR
Critical dark period

100. The flowering signal, not yet chemically identified
A Flowering Hormone?
The flowering signal, not yet chemically identified
Is called florigen, and it may be a hormone or a change in relative concentrations of multiple hormones

101. Figure 39.24
To test whether there is a flowering hormone, researchers conducted an experiment in which a plant that had been induced to flower by photoperiod was grafted to a plant that had not been induced.
EXPERIMENT
RESULTS
CONCLUSION
Both plants flowered, indicating the transmission of a flower-inducing substance. In some cases, the transmission worked even if one was a short-day plant and the other was a long-day plant.
Plant subjected to photoperiod
that induces flowering
that does not induce flowering
Graft
Time (several weeks)

102. Meristem Transition and Flowering
Whatever combination of environmental cues and internal signals is necessary for flowering to occur
The outcome is the transition of a bud’s meristem from a vegetative to a flowering state

103. Because of their immobility
Concept 39.4: Plants respond to a wide variety of stimuli other than light
Because of their immobility
Plants must adjust to a wide range of environmental circumstances through developmental and physiological mechanisms

104. Roots show positive gravitropism Stems show negative gravitropism
Gravity
Response to gravity
Is known as gravitropism
Roots show positive gravitropism
Stems show negative gravitropism

105. Plants may detect gravity by the settling of statoliths
Specialized plastids containing dense starch grains
Statoliths
20 m
(a)
(b)
Figure 39.25a, b

106. The term thigmomorphogenesis
Mechanical Stimuli
The term thigmomorphogenesis
Refers to the changes in form that result from mechanical perturbation

107. Rubbing the stems of young plants a couple of times daily
Results in plants that are shorter than controls
Figure 39.26

108. Growth in response to touch
Is called thigmotropism
Occurs in vines and other climbing plants

109. Rapid leaf movements in response to mechanical stimulation
Are examples of transmission of electrical impulses called action potentials
(a) Unstimulated
(b) Stimulated
Side of pulvinus with
flaccid cells
turgid cells
Vein
0.5 m
(c) Motor organs
Leaflets after stimulation
Pulvinus (motor organ)
Figure 39.27a–c

110. Environmental Stresses
Have a potentially adverse effect on a plant’s survival, growth, and reproduction
Can have a devastating impact on crop yields in agriculture

111. Drought During drought
Plants respond to water deficit by reducing transpiration
Deeper roots continue to grow

112. Enzymatic destruction of cells
Flooding
Enzymatic destruction of cells
Creates air tubes that help plants survive oxygen deprivation during flooding
Vascular cylinder
Air tubes
Epidermis
100 m
(a) Control root (aerated)
(b) Experimental root (nonaerated)
Figure 39.28a, b

113. Salt Stress
Plants respond to salt stress by producing solutes tolerated at high concentrations
Keeping the water potential of cells more negative than that of the soil solution

114. Heat Stress
Heat-shock proteins
Help plants survive heat stress

115. Altering lipid composition of membranes
Cold Stress
Altering lipid composition of membranes
Is a response to cold stress

116. 39.5 Plants respond to attacks by herbivores and pathogens.
2.D.4 Plants and animals have a variety of chemical defenses against infections that affect dynamic homeostasis.

117. Plants counter external threats
With defense systems that deter herbivory and prevent infection or combat pathogens

118. Defenses Against Herbivores
Herbivory, animals eating plants
Is a stress that plants face in any ecosystem
Plants counter excessive herbivory
With physical defenses such as thorns
With chemical defenses such as distasteful or toxic compounds

119. Some plants even “recruit” predatory animals
That help defend the plant against specific herbivores
Recruitment of parasitoid wasps that lay their eggs within caterpillars 4 3
Synthesis and release of volatile attractants 1
Chemical in saliva
Wounding 2
Signal transduction pathway
Figure 39.29

120. Defenses Against Pathogens
A plant’s first line of defense against infection
Is the physical barrier of the plant’s “skin,” the epidermis and the periderm
Once a pathogen invades a plant
The plant mounts a chemical attack as a second line of defense that kills the pathogen and prevents its spread

121. The second defense system
Is enhanced by the plant’s inherited ability to recognize certain pathogens

122. Gene-for-Gene Recognition
A virulent pathogen
Is one that a plant has little specific defense against
An avirulent pathogen
Is one that may harm but not kill the host plant

123. Gene-for-gene recognition is a widespread form of plant disease resistance
That involves recognition of pathogen-derived molecules by the protein products of specific plant disease resistance (R) genes

124. Plant cell is resistant
A pathogen is avirulent
If it has a specific Avr gene corresponding to a particular R allele in the host plant
Figure 39.30a
Receptor coded by R allele
(a) If an Avr allele in the pathogen corresponds to an R allele in the host plant, the host plant will have resistance, making the pathogen avirulent. R alleles probably code for receptors in the plasma membranes of host plant cells. Avr alleles produce compounds that can act as ligands, binding to receptors in host plant cells.
Signal molecule (ligand)
from Avr gene product R
Avr allele
Avirulent pathogen
Plant cell is resistant

125. If the plant host lacks the R gene that counteracts the pathogen’s Avr gene
Then the pathogen can invade and kill the plant
Figure 39.30b
No Avr allele;
virulent pathogen
Plant cell becomes diseased
Avr allele
No R allele;
plant cell becomes diseased
Virulent pathogen
(b) If there is no gene-for-gene recognition because of one of the above three conditions, the pathogen will be virulent, causing disease to develop. R

126. Plant Responses to Pathogen Invasions
A hypersensitive response against an avirulent pathogen
Seals off the infection and kills both pathogen and host cells in the region of the infection
4 Before they die, infected cells release a chemical signal, probably salicylic acid.
3 In a hypersensitive response (HR), plant cells produce anti- microbial molecules, seal off infected areas by modifying their walls, and then destroy themselves. This localized response produces lesions and protects other parts of an infected leaf.
Signal
5 The signal is
distributed to the
rest of the plant. 4 5
Hypersensitive response
Signal transduction pathway 6 3
6 In cells remote from the infection site, the chemical initiates a signal transduction pathway.
Signal transduction pathway 2
Acquired resistance 7
2 This identification
step triggers a
signal transduction
pathway. 1
7 Systemic acquired
resistance is activated: the production of molecules that help protect the cell against a diversity of pathogens for several days.
Avirulent pathogen
1 Specific resistance is
based on the
binding of ligands
from the pathogen
to receptors in
plant cells.
R-Avr recognition and
hypersensitive response
Systemic acquired
resistance
Figure 39.31

127. Systemic Acquired Resistance
Systemic acquired resistance (SAR)
Is a set of generalized defense responses in organs distant from the original site of infection
Is triggered by the signal molecule salicylic acid