1. Help needed for the Art & Science Day at the Chester Street Elementary school 110 Chester St, Kingston
12- 3:30 on Tuesday, March 22.

2. Plant Growth & Development
3 stages
Embryogenesis
Fertilization to seed
Plant Growth & Development
3 stages
Embryogenesis
Fertilization to seed
2. Vegetative growth
Juvenile stage
Germination to adult
"phase change" marks transition
3. Reproductive development
Make flowers, can
reproduce sexually

3. Senescence
Shoot apical meristem now starts making new organ: flowers, with many new structures & cell types
Eventually petals, etc senesce = genetically programmed cell death: controlled by specific genes

4. Senescence
Eventually petals, etc senesce = genetically programmed cell death: controlled by specific genes
Also seen in many other cases: deciduous leaves in fall, annual plants, older trees

5. Senescence
Induce specific senescence-associated genes ; eg DNAses, proteases, lipases
Also seen during xylem formation: when cell wall is complete cell kills itself

6. Senescence
Also seen during xylem formation: when cell wall is complete cell kills itself
Also seen as wound response: hypersensitive response
Cells surrounding the wound kill themselves

7. Senescence
Also seen during xylem formation: when cell wall is complete cell kills itself
Also seen as wound response: hypersensitive response
Cells surrounding the wound kill themselves
Some mutants do this w/o wound -> is controlled by genes!

8. Light regulation of Plant Development
Plants use light as food and information
Use information to control development

9. Light regulation of Plant Development
Plants use light as food and information
Use information to control development
germination

10. Light regulation of Plant Development
Plants use light as food and information
Use information to control development
Germination
Photomorphogenesis vs skotomorphogenesis

11. Light regulation of Plant Development
Plants use light as food and information
Use information to control development
Germination
Photomorphogenesis vs skotomorphogenesis
Sun/shade & shade avoidance

12. Light regulation of Plant Development
Germination
Morphogenesis
Sun/shade & shade avoidance
Flowering

13. Light regulation of Plant Development
Germination
Morphogenesis
Sun/shade & shade avoidance
Flowering
Senescence

14. Light regulation of growth
Plants sense
Light quantity

15. Light regulation of growth
Plants sense
Light quantity
Light quality (colors)

16. Light regulation of growth
Plants sense
Light quantity
Light quality (colors)
Light duration

17. Light regulation of growth
Plants sense
Light quantity
Light quality (colors)
Light duration
Direction it comes from

18. Light regulation of growth
Plants sense
Light quantity
Light quality (colors)
Light duration
Direction it comes from
Have photoreceptors
that sense specific
wavelengths

19. Light regulation of growth
Early work:
Darwins showed
blue light controls
phototropism

20. Light regulation of Plant Development
Early work:
Darwins : blue light controls phototropism
Duration = photoperiodism (Garner and Allard,1920)
Maryland Mammoth tobacco flowers in the S but not in N

21. Light regulation of Plant Development
Early work:
Darwins : blue light controls phototropism
Duration = photoperiodism (Garner and Allard,1920)
Maryland Mammoth tobacco flowers in the S but not in N
= short-day plant (SDP)

22. Light regulation of Plant Development
Duration = photoperiodism (Garner and Allard,1920) Maryland Mammoth tobacco flowers in the S but not in N
= short-day plant (SDP)
Measures night! 30" flashes during night stop flowers

23. Light regulation of growth
Duration = photoperiodism (Garner and Allard,1920) Maryland Mammoth tobacco flowers in the S but not in N
= short-day plant (SDP)
Measures night! 30" flashes during night stop flowers
LDP plants such as Arabidopsis need long days to flower

24. Light regulation of growth
Duration = photoperiodism (Garner and Allard,1920) Maryland Mammoth tobacco flowers in the S but not in N
= short-day plant (SDP)
Measures night! 30" flashes during night stop flowers
LDP plants such as Arabidopsis need long days to flower
SDP flower in fall, LDP flower in spring, neutral flower when ready

25. Light regulation of growth
Measures night! 30" flashes during night stop flowers
LDP plants such as Arabidopsis need long days to flower
SDP flower in fall, LDP flower in spring, neutral flower when ready
Next : color matters! Red light works best for flowering

26. Light regulation of growth
Next : color matters! Red light (666 nm) works best for flowering & for germination of many seeds!

27. Light regulation of growth
Next : color matters! Red light (666 nm) works best for flowering & for germination of many seeds!
But, Darwins showed blue works best for phototropism!

28. Light regulation of growth
Next : color matters! Red light (666 nm)works best for flowering & for germination of many seeds!
But, Darwin showed blue works best for phototropism!
Different photoreceptor!

29. Light regulation of growth
But, Darwin showed blue works best for phototropism!
Different photoreceptor!
Red light (666 nm) promotes germination
Far red light (>700 nm) blocks germination

30. Light regulation of growth
But, Darwin showed blue works best for phototropism!
Different photoreceptor!
Red light (666 nm) promotes germination
Far red light (>700 nm) blocks germination

31. Light regulation of growth
Red light (666 nm) promotes germination
Far red light (>700 nm) blocks germination
After alternate R/FR flashes last flash decides outcome

32. Light regulation of growth
Red light (666 nm) promotes germination
Far red light (>700 nm) blocks germination
After alternate R/FR flashes last flash decides outcome
Seeds don't want to germinate in the shade!

33. Light regulation of growth
Red light (666 nm) promotes germination
Far red light (>700 nm) blocks germination
After alternate R/FR color of final flash decides outcome
Seeds don't want to germinate in the shade!
Pigment is photoreversible

34. Light regulation of growth
Red light (666 nm) promotes germination
Far red light (730 nm) blocks germination
After alternate R/FR color of final flash decides outcome
Pigment is photoreversible! -> helped purify it!
Looked for pigment that absorbs first at 666 nm, then 730

35. Phytochrome
Red light (666 nm) promotes germination
Far red light (730 nm) blocks germination
After alternate R/FR color of final flash decides outcome
Pigment is photoreversible! -> helped purify it!
Looked for pigment that absorbs first at 666 nm, then 730

36. Phytochrome
Red light (666 nm) promotes germination
Far red light (730 nm) blocks germination
After alternate R/FR color of final flash decides outcome
Pigment is photoreversible! -> helped purify it!
Looked for pigment that absorbs first at 666 nm, then 730
Made as inactive cytoplasmic Pr that absorbs at 666 nm

37. Phytochrome
Made as inactive cytoplasmic Pr that absorbs at 666 nm or in blue
Converts to active Pfr that absorbs far red (730nm)

38. Types of Phytochrome Responses
Two categories based on speed
Rapid biochemical events
Morphological changes

39. Types of Phytochrome Responses
Two categories based on speed
Rapid biochemical events
Morphological changes
Lag time also varies from minutes to weeks

40. Types of Phytochrome Responses
Two categories based on speed
Rapid biochemical events
Morphological changes
Lag time also varies from minutes to weeks: numbers of steps after Pfr vary

41. Types of Phytochrome Responses
Lag time also varies from minutes to weeks: numbers of steps after Pfr vary
"Escape time" until a response can no longer be reversed by FR also varies

42. Types of Phytochrome Responses
Lag time also varies from minutes to weeks: numbers of steps after Pfr vary
"Escape time" until a response can no longer be reversed by FR also varies: time taken for Pfr to do its job
Conclusions: phytochrome acts on many processes in many ways

43. Types of Phytochrome Responses
Two categories based on speed
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2

44. Types of Phytochrome Responses
Two categories based on speed
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr

45. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible!

46. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible! But action spectrum same as Pr

47. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible! But action spectrum same as Pr
Induced by FR!

48. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible! But action spectrum same as Pr
Induced by FR!
Obey law of reciprocity:
1 nmol/m-2 x 100 s =
100 nmol/m-2 x 1 sec

49. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible! But action spectrum same as Pr
Induced by FR!
Obey law of reciprocity:
1 nmol/m-2 x 100 s =
100 nmol/m-2 x 1 sec
Examples: Cab gene
induction, oat
coleoptile growth

50. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
Changes 0.02% of Pr to Pfr
Are not FR-reversible! But action spectrum same as Pr
Induced by FR!
Obey law of reciprocity:
1 nmol/m-2 x 100 s =
100 nmol/m-2 x 1 sec
Examples: Cab gene
induction, oat
coleoptile growth
2. LF: induced by
1 µmol/m-2,
1000 µmol/m-2

51. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
Are FR-reversible!

52. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
Are FR-reversible! Need > 3% Pfr

53. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
Are FR-reversible! Need > 3% Pfr
Obey law of reciprocity

54. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
Are FR-reversible! Need > 3% Pfr
Obey law of reciprocity
Examples : Lettuce seed
Germination, mustard
photomorphogenesis,
inhibits flowering in SDP

55. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
Are FR-reversible! Need > 3% Pfr
Obey law of reciprocity
Examples : Lettuce seed
Germination, mustard
photomorphogenesis,
inhibits flowering in SDP
3. HIR: require prolonged
exposure to higher fluence

56. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Effect is proportional to
Fluence

57. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Effect is proportional to
Fluence
Disobey law of reciprocity
Are not FR-reversible!

58. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Effect is proportional to fluence
Disobey law of reciprocity
Are not FR-reversible!
Some are induced by FR!

59. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Effect is proportional to fluence
Disobey law of reciprocity
Are not FR-reversible!
Some are induced by FR!
Examples: inhibition of
hypocotyl elongation in
many seedlings,
Anthocyanin synthesis

60. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Effect is proportional to fluence
Disobey law of reciprocity
Are not FR-reversible!
Some are induced by FR!
Examples: inhibition of
hypocotyl elongation in
many seedlings,
Anthocyanin synthesis
Different responses =
Different phytochromes

61. Types of Phytochrome Responses
3 classes based on fluence (amount of light needed)
VLF:induced by 0.1 nmol/m-2 , 50nmol/m-2
2. LF: induced by 1 µmol/m-2, µmol/m-2
3. HIR: require prolonged exposure to higher fluence
Different responses = Different phytochromes:
3 in rice, 5 in Arabidopsis

62. Types of Phytochrome Responses
Different responses = Different phytochromes:
3 in rice, 5 in Arabidopsis
PHYA mediates VLF and HIR due to FR

63. Types of Phytochrome Responses
Different responses = Different phytochromes:
3 in rice, 5 in Arabidopsis
PHYA mediates VLF and HIR due to FR
Very labile in light

64. Types of Phytochrome Responses
Different responses = Different phytochromes:
3 in rice, 5 in Arabidopsis
PHYA mediates VLF and HIR due to FR
Very labile in light
2. PHYB mediates LF and HIR due to R
Stable in light

65. Types of Phytochrome Responses
PHYA mediates VLF and HIR due to FR
Very labile in light
2. PHYB mediates LF and HIR due to R
Stable in light
3. Roles of PHYs C, D & E not so clear

66. Types of Phytochrome Responses
PHYA mediates VLF and HIR due to FR
Very labile in light
2. PHYB mediates LF and HIR due to R
Stable in light
3. Roles of PHYs C, D & E not so clear
PHYA & PHYB are often antagonistic.

67. Types of Phytochrome Responses
PHYA & PHYB are often antagonistic.
In sunlight PHYB mainly controls development

68. Types of Phytochrome Responses
PHYA & PHYB are often antagonistic.
In sunlight PHYB mainly controls development
In shade PHYA 1st controls development, since FR is high

69. Types of Phytochrome Responses
PHYA & PHYB are often antagonistic.
In sunlight PHYB mainly controls development
In shade PHYA 1st controls development, since FR is high
But PHYA is light-labile; PHYB takes over & stem grows
"shade-avoidance"

70. Phytochrome
Pr has cis-chromophore

71. Phytochrome
Pr has cis-chromophore
Red converts it to trans = active shape

72. Phytochrome
Pr has cis-chromophore
Red converts it to trans = active shape
Far-red reverts it to cis

73. Phytochrome
Pfr is a protein kinase: acts by kinasing key proteins
some stays in cytoplasm & activates ion pumps

74. Phytochrome
Pfr is a protein kinase: acts by kinasing key proteins
some stays in cytoplasm & activates ion pumps
Rapid responses are due to changes in ion fluxes

75. Phytochrome
Pfr is a protein kinase: acts by kinasing key proteins
some stays in cytoplasm & activates ion pumps
Rapid responses are due to changes in ion fluxes
Increase growth by activating PM H+ pump

76. Phytochrome
Pfr is a protein kinase: acts by kinasing key proteins
some stay in cytoplasm & activate ion pumps
Rapid responses are due to changes in ion fluxes
most enter nucleus and kinase transcription factors

77. Phytochrome
some stay in cytoplasm & activate ion pumps
Rapid responses are due to changes in ion fluxes
most enter nucleus and kinase transcription factors
Slow responses are due to changes in gene expression

78. Phytochrome
most enter nucleus and kinase transcription factors
Slow responses are due to changes in gene expression
Many targets of PHY are transcription factors, eg PIF3

79. Phytochrome
most enter nucleus and kinase transcription factors
Slow responses are due to changes in gene expression
Many targets of PHY are transcription factors, eg PIF3
Activate cascades of genes for photomorphogenesis

80. Phytochrome
Slow responses are due to changes in gene expression
Many targets of PHY are transcription factors, eg PIF3
Activate cascades of genes for light responses
Some overlap, and some are unique to each phy

81. Phytochrome
Slow responses are due to changes in gene expression
Many targets of PHY are transcription factors, eg PIF3
Activate cascades of genes for light responses
Some overlap, and some are unique to each phy
20% of genes are light-regulated

82. Phytochrome
20% of genes are light-regulated
Protein degradation is important for light regulation

83. Phytochrome
20% of genes are light-regulated
Protein degradation is important for light regulation
Cop mutants can’t degrade specific proteins

84. Phytochrome
Protein degradation is important for light regulation
Cop mutants can’t degrade specific proteins
COP1/SPA targets specific transcription factors for degradation

85. Phytochrome
Protein degradation is important for light regulation
Cop mutants can’t degrade specific proteins
COP1/SPA targets specific
TF for degradation
DDA1/DET1/COP10 target
other proteins for degradation

86. Phytochrome
Protein degradation is important for light regulation
Cop mutants can’t degrade specific proteins
COP1/SPA targets specific
TF for degradation
DDA1/DET1/COP10 target
other proteins for degradation
Other COPs form part of
COP9 signalosome

87. Phytochrome
Protein degradation is important for light regulation
Cop mutants can’t degrade specific proteins
COP1/SPA targets specific TF for degradation
DDA1/DET1/COP10 target other proteins
Other COPs form part of COP9 signalosome
W/O COPs these TF act in dark

88. Phytochrome
COPs target specific TF for degradation
W/O COPs they act in dark
In light COP1 is exported to cytoplasm so TF can act
Tags PHYA by itself on the way out!

89. Other Phytochrome Responses
In shade avoidance FR stimulates IAA synthesis from trp!
Occurs in < 1 hour

90. Other Phytochrome Responses
In shade avoidance FR stimulates IAA synthesis from trp!
Occurs in < 1 hour
Also occurs in response to endogenous ethylene!

91. Other Phytochrome Responses
Flowering under short days is controlled via protein deg
COP & CUL4 mutants flower early

92. Other Phytochrome Responses
Flowering under short days is controlled via protein deg
COP & CUL4 mutants flower early
Accumulate FT (Flowering locus T) mRNA early
FT mRNA abundance shows strong circadian rhythm

93. Other Phytochrome Responses
Circadian rhythms
Many plant responses, some developmental, some physiological, show circadian rhythms

94. Circadian rhythms
Many plant responses, some developmental, some physiological, show circadian rhythms
Leaves move due to circadian ion fluxes in/out of dorsal & ventral motor cells

95. Circadian rhythms
Many plant responses show circadian rhythms
Once entrained, continue in constant dark

96. Circadian rhythms
Many plant responses show circadian rhythms
Once entrained, continue in constant dark, or light

97. Circadian rhythms
Many plant responses show circadian rhythms
Once entrained, continue in constant dark, or light!
Gives plant headstart on photosynthesis, other processes that need gene expression

98. Circadian rhythms
Many plant responses show circadian rhythms
Once entrained, continue in constant dark, or light!
Gives plant headstart on photosynthesis, other processes that need gene expression
eg elongation at night!

99. Circadian rhythms
Gives plant headstart on photosynthesis, other processes that need gene expression
eg elongate at night!
Endogenous oscillator is temperature-compensated, so runs at same speed at all times

100. Circadian rhythms
Endogenous oscillator is temperature-compensated, so runs at same speed at all times
Is a negative feedback loop of transcription-translation
Light & TOC1 activate LHY & CCA1 at dawn

101. Circadian rhythms
Light & TOC1 activate LHY & CCA1 at dawn
LHY & CCA1 repress TOC1 in day, so they decline too

102. Circadian rhythms
Light & TOC1 activate LHY & CCA1 at dawn
LHY & CCA1 repress TOC1 in day, so they decline too
At night TOC1 is activated (not enough LHY & CCA1)

103. Circadian rhythms
Light & TOC1 activate LHY & CCA1 at dawn
LHY & CCA1 repress TOC1 in day, so they decline too
At night TOC1 is activated (not enough LHY & CCA1)
Phytochrome entrains the clock

104. Circadian rhythms
Light & TOC1 activate LHY & CCA1 at dawn
LHY & CCA1 repress TOC1 in day, so they decline too
At night TOC1 is activated (not enough LHY & CCA1)
Phytochrome entrains the clock So does blue light

105. Blue Light Responses
Circadian Rhythms

106. Blue Light Responses
Circadian Rhythms
Solar tracking

107. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism

108. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation

109. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement

110. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement
Stomatal opening

111. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement
Stomatal opening
Gene expression

112. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement
Stomatal opening
Gene expression
Flowering in Arabidopsis

113. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement
Stomatal opening
Gene expression
Flowering in Arabidopsis
Responses vary in their fluence requirements

114. Blue Light Responses
Circadian Rhythms
Solar tracking
Phototropism
Inhibiting stem elongation
Chloroplast movement
Stomatal opening
Gene expression
Flowering in Arabidopsis
Responses vary in their fluence requirements & lag times

115. Blue Light Responses
Responses vary in their fluence requirements & lag time
Stomatal opening is reversible by green light; others aren’t

116. Blue Light Responses
Responses vary in their fluence requirements & lag time
Stomatal opening is reversible by green light; others aren’t
Multiple blue receptors with
different functions!

117. Blue Light Responses
Responses vary in their fluence requirements & lag time
Stomatal opening is reversible by green light; others aren’t
Multiple blue receptors with
different functions!
Identified by mutants

118. Blue Light Responses
Responses vary in their fluence requirements & lag time
Stomatal opening is reversible by green light; others aren’t
Multiple blue receptors with
different functions!
Identified by mutants, then clone
the gene and identify the protein

119. Blue Light Responses
Responses vary in their fluence requirements & lag time
Stomatal opening is reversible by green light; others aren’t
Multiple blue receptors with
different functions!
Identified by mutants, then clone
the gene and identify the protein
Cryptochromes repress hypocotyl
elongation

120. Blue Light Responses
Cryptochromes repress hypocotyl elongation
Stimulate flowering

121. Blue Light Responses
Cryptochromes repress hypocotyl elongation
Stimulate flowering
Set the circadian clock (in humans, too!)

122. Blue Light Responses
Cryptochromes repress hypocotyl elongation
Stimulate flowering
Set the circadian clock (in humans, too!)
Stimulate anthocyanin synthesis

123. Blue Light Responses
Cryptochromes repress hypocotyl elongation
Stimulate flowering
Set the circadian clock (in humans, too!)
Stimulate anthocyanin synthesis
3 CRY genes

124. Blue Light Responses
3 CRY genes
All have same basic structure:
Photolyase-like domain binds FAD and a pterin (MTHF) that absorbs blue & transfers energy to FAD in photolyase
(an enzyme that uses light energy to repair pyr dimers)

125. Blue Light Responses
3 CRY genes
All have same basic structure:
Photolyase-like domain binds FAD and a pterin (MTHF) that absorbs blue & transfers energy to FAD in photolyase
(an enzyme that uses light energy to repair pyr dimers)
DAS binds COP1 & has nuclear localization signals

126. Blue Light Responses
3 CRY genes
All have same basic structure:
Photolyase-like domain binds FAD and a pterin (MTHF) that absorbs blue & transfers energy to FAD in photolyase
(an enzyme that uses light energy to repair pyr dimers)
DAS binds COP1 & has nuclear localization signals
CRY1 & CRY2 kinase proteins after absorbing blue

127. Blue Light Responses
3 CRY genes
CRY1 & CRY2 kinase proteins after absorbing blue
CRY3 repairs mt & cp DNA!

128. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth

129. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth
Opens anion channels in PM

130. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth
Opens anion channels in PM
Stimulates anthocyanin synthesis

131. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth
Opens anion channels in PM
Stimulates anthocyanin synthesis
Entrains the circadian clock

132. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth
Opens anion channels in PM
Stimulates anthocyanin synthesis
Entrains the circadian clock
Also accumulates in nucleus & interacts with PHY & COP1 to regulate photomorphogenesis, probably by kinasing substrates

133. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
Triggers rapid changes in PM potential & growth
Opens anion channels in PM
Stimulates anthocyanin synthesis
Entrains the circadian clock
Also accumulates in nucleus & interacts with PHY & COP1 to regulate photomorphogenesis, probably by kinasing substrates
2. CRY2 controls flowering

134. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
2. CRY2 controls flowering: little effect on other processes
Light-labile

135. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth: light-stable
2. CRY2 controls flowering: little effect on other processes
Light-labile
3. CRY3 enters cp & mito, where binds & repairs DNA!

136. Blue Light Responses
3 CRY genes
CRY1 regulates blue effects on growth
2. CRY2 controls flowering: little effect on other processes
CRY3 enters cp & mito, where binds & repairs DNA!
Cryptochromes are not
involved in phototropism or
stomatal opening!

137. Blue Light Responses
Cryptochromes are not involved in phototropism or
stomatal opening!
Phototropins are!

138. Blue Light Responses
Phototropins are involved in phototropism & stomatal opening!
Many names (nph, phot, rpt) since found by several different mutant screens

139. Phototropins
Many names (nph, phot, rpt) since found by several different mutant screens
Mediate blue light-induced growth enhancements

140. Phototropins
Many names (nph, phot, rpt) since found by several different mutant screens
Mediate blue light-induced growth enhancement & blue light-dependent activation of the plasma membrane H+-ATPase in guard cells

141. Phototropins
Many names (nph, phot, rpt) since found by several different mutant screens
Mediate blue light-induced growth enhancement & blue light-dependent activation of the plasma membrane H+-ATPase in guard cells
Contain light-activated serine-threonine kinase domain and LOV1 (light-O2-voltage) and LOV2 repeats

142. Phototropins
Many names (nph, phot, rpt) since found by several different mutant screens
Mediate blue light-induced growth enhancement & blue light-dependent activation of the plasma membrane H+-ATPase in guard cells
Contain light-activated serine-threonine kinase domain and LOV1 (light-O2-voltage) and LOV2 repeats
LOV1 & LOV2 bind FlavinMonoNucleotide cofactors

143. Phototropins
Many names (nph, phot, rpt) since found by several different mutant screens
Mediate blue light-induced growth enhancement & blue light-dependent activation of the plasma membrane H+-ATPase in guard cells
Contain light-activated serine-threonine kinase domain and LOV1 (light-O2-voltage) and LOV2 repeats
LOV1 & LOV2 bind FlavinMonoNucleotide cofactors
After absorbing blue rapidly autophosphorylate & kinase other proteins

144. Phototropins
After absorbing blue rapidly autophosphorylate & kinase other proteins
1 result = phototropism
due to uneven auxin
transport

145. Phototropins
After absorbing blue rapidly autophosphorylate & kinase other proteins
1 result = phototropism
due to uneven auxin
transport
Send more to side away
from light!

146. Phototropins
After absorbing blue rapidly autophosphorylate & kinase other proteins
1 result = phototropism
due to uneven auxin
transport
Send more to side away
from light!
Phot 1 mediates LF

147. Phototropins
After absorbing blue rapidly autophosphorylate & kinase other proteins
1 result = phototropism
due to uneven auxin
transport
Send more to side away
from light!
PHOT 1 mediates LF
PHOT2 mediates HIR

148. Phototropins
2nd result = stomatal opening via stimulation of guard cell PM proton pump
Also requires photosynthesis by guard cells!

149. Phototropins
2nd result = stomatal opening via stimulation of guard cell PM proton pump
Also requires photosynthesis by guard cells & signaling from xanthophylls

150. Phototropins
2nd result = stomatal opening via stimulation of guard cell PM proton pump
Also requires photosynthesis by guard cells & signaling from xanthophylls
npq mutants don’t
make zeaxanthin &
lack specific blue
response

151. Phototropins
2nd result = stomatal opening via stimulation of guard cell PM proton pump
Also requires photosynthesis by guard cells & signaling from xanthophylls
npq mutants don’t
make zeaxanthin &
lack specific blue
response
Basic idea: open when pump in K+

152. Phototropins
2nd result = stomatal opening via stimulation of guard cell PM proton pump
Also requires photosynthesis by guard cells & signaling from xanthophylls
npq mutants don’t
make zeaxanthin &
lack specific blue
response
Basic idea: open when pump in K+
Close when pump out K+

153. Phototropins
Basic idea: open when pump in K+
Close when pump out K+
Control is hideously complicated!

154. Phototropins
Basic idea: open when pump in K+
Close when pump out K+
Control is hideously complicated!
Mainly controlled by blue light

155. Phototropins
Basic idea: open when pump in K+
Close when pump out K+
Control is hideously complicated!
Mainly controlled by blue light, but red also plays role

156. Phototropins
Basic idea: open when pump in K+
Close when pump out K+
Control is hideously complicated!
Mainly controlled by blue light,
but red also plays role
Light intensity is also important

157. Phototropins
Mainly controlled by blue light, but red also plays role
Light intensity is also important due to effect on
[photosynthate] in guard cells

158. Phototropins
Mainly controlled by blue light, but red also plays role
Light intensity is also important due to effect on
[photosynthate] in guard cells
PHOT1 &2 also help

159. Phototropins
Mainly controlled by blue light, but red also plays role
Light intensity is also important due to effect on
[photosynthate] in guard cells
PHOT1 &2 also help
Main GC blue
receptor is zeaxanthin!

160. Phototropins
Mainly controlled by blue light, but red also plays role
Light intensity is also important due to effect on
[photosynthate] in guard cells
PHOT1 &2 also help
Main GC blue
receptor is zeaxanthin!
Reason for green reversal

161. Phototropins
Mainly controlled by blue light, but red also plays role
Light intensity is also important due to effect on
[photosynthate] in guard cells
PHOT1 &2 also help
Main GC blue
receptor is zeaxanthin!
Reason for green reversal
water stress overrides light!

162. Phototropins
water stress overrides light: roots make Abscisic Acid: closes stomates & blocks opening regardless of other signals!