1. Plant defense responses Hypersensitive response
Prepare a 10’ talk for Friday March 22 on plant defenses or describe interactions between plants & pathogens, pests or symbionts
Plant defense responses
Hypersensitive response
Systemic acquired resistance
Innate immunity
Phytoalexins
Defensins
Oxidative burst
Some possible pests
Nematodes
Rootworms
Aphids
Thrips
Gypsy moths
hemlock woolly adelgid
Some possible pathogens
Agrobacterium tumefaciens
Agrobacterium rhizogenes
Pseudomonas syringeae
Pseudomonas aeruginosa
Viroids
DNA viruses
RNA viruses
Fungi
Oomycetes
Some possible symbionts
N-fixing bacteria
N-fixing cyanobacteria
Endomycorrhizae
Ectomycorrhizae
Burkholderia ambifaria

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

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

4. 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)

5. 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

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

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

8. 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

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

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

11. 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)

12. 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

13. 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

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

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

16. 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

17. 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

18. 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

19. 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

20. 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

21. 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

22. 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!

23. 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!

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

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

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

27. 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

28. 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

29. 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

30. 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

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

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

33. 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

34. 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

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

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

37. 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

38. 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+

39. 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+

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

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

42. 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

43. 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

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

45. 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

46. 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!

47. 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

48. 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!

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

50. UV-B perception
Plants also use UV-B to control development

51. UV-B perception
Plants also use UV-B to
control development

52. UV-B perception
Plants also use UV-B to
control development

53. UV-B perception
Plants also use UV-B to control development
Absorbed by UVR8: goes from inactive dimer to active monomer

54. UV-B perception
Plants also use UV-B to control development
Absorbed by UVR8: goes from inactive dimer to active monomer
+ve regulators = COP1 & HY5

55. UV-B perception
Plants also use UV-B to control development
Absorbed by UVR8: goes from inactive dimer to active monomer
+ve regulators = COP1 & HY5
-ve regulators =
RUP1 & RUP2

56. Growth regulators
Auxins
Cytokinins
Gibberellins
Abscisic acid
Ethylene
Brassinosteroids
Strigolactones
All are small
organics: made in
one part, affect
another part

57. Growth regulators
All are small organics: made in one part, affect another part
Treating a plant tissue with a hormone is like putting a dime in a vending machine. It depends on the machine, not the dime!

58. Auxin
First studied by Darwins!
Showed that a "transmissible influence" made at tips caused bending lower down

59. Auxin
First studied by Darwins!
Showed that a "transmissible influence" made at tips caused bending lower down
No tip, no curve!

60. Auxin
First studied by Darwins!
Showed that a "transmissible influence" made at tips caused bending lower down
No tip, no curve!
1913:Boysen-Jensen showed that diffused through agar blocks but not through mica

61. Auxin
1913:Boysen-Jensen showed that diffused through agar blocks but not through mica
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark

62. Auxin
1913:Boysen-Jensen showed that diffused through agar blocks but not through mica
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark
Uneven amounts of "transmissible influence" makes bend

63. Auxin
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark
Uneven amounts of "transmissible influence" makes bend
1926: Went showed that a chemical that diffused from tips into blocks caused growth

64. Auxin
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark
Uneven amounts of "transmissible influence" makes bend
1926: Went showed that a chemical that diffused from tips into blocks caused growth
If placed asymmetrically get bending due to asymmetrical growth

65. Auxin
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark
Uneven amounts of "transmissible influence" makes bend
1926: Went showed that a chemical that diffused from tips into blocks caused growth
If placed asymmetrically get bending due to asymmetrical growth
Amount of bending depends on [auxin]

66. Auxin
1919: Paal showed that if tip was replaced asymmetrically, plant grew asymmetrically even in dark
Uneven amounts of "transmissible influence" makes bend
1926: Went showed that a chemical that diffused from tips into blocks caused growth
If placed asymmetrically get bending due to asymmetrical growth
Amount of bending depends on [auxin]
1934: Indole-3-Acetic acid (IAA) from the urine of pregnant women was shown to cause bending

67. IAA IBA 4-CI-IAA PA Auxin
1934: Indole-3-Acetic acid (IAA) from the urine of pregnant women was shown to cause bending
IAA is the main auxin in vivo.
Others include Indole-3-butyric acid (IBA), 4-Chloroindole-3-acetic acid and phenylacetic acid (PA)
IAA
IBA
4-CI-IAA PA

68. IAA Auxin IAA is the main auxin in vivo.
Many synthetic auxins have been identified
IAA

69. IAA Auxin IAA is the main auxin in vivo.
Many synthetic auxins have been identified
No obvious structural similarity, yet all work!
IAA

70. IAA Auxin IAA is the main auxin in vivo.
Many synthetic auxins have been identified
No obvious structural similarity, yet all work!
Widely used in agriculture
IAA

71. IAA Auxin IAA is the main auxin in vivo.
Many synthetic auxins have been identified
No obvious structural similarity, yet all work!
Widely used in agriculture
to promote growth (flowering, cuttings)
IAA

72. IAA Auxin IAA is the main auxin in vivo.
Many synthetic auxins have been identified
No obvious structural similarity, yet all work!
Widely used in agriculture
to promote growth (flowering, cuttings)
as weed killers!
Agent orange was 1:1
2,4-D and 2,4,5-T
IAA

73. IAA Auxin weed killers! Agent orange was 1:1 2,4-D and 2,4,5-T
2,4,5-T was contaminated
with dioxin, a carcinogen
IAA

74. IAA Auxin weed killers! Agent orange was 1:1 2,4-D and 2,4,5-T
2,4,5-T was contaminated
with dioxin, a carcinogen
2,4-D is still widely used:
selectively kills dicots
IAA

75. Auxin
weed killers!
2,4-D is still widely used: selectively kills dicots
Controls weeds in monocot crops
(corn, rice, wheat)
Mech unclear: may cause excess ethylene
or ABA production.
IAA

76. Auxin
>90%of IAA is conjugated to sugars in vivo!

77. Auxin
>90%of IAA is conjugated to sugars in vivo!
Inactive, but readily activated!

78. Auxin
>90%of IAA is conjugated to sugars in vivo!
Inactive, but readily activated!
Best way to measure [auxin] is bioassay!

79. Auxin
>90%of IAA is conjugated to sugars in vivo!
Inactive, but readily activated!
Best way to measure [auxin] is bioassay!
Critical concentration varies between tissues

80. Auxin
>90%of IAA is conjugated to sugars in vivo!
Inactive, but readily activated!
Best way to measure [auxin] is bioassay!
Critical concentration varies between tissues
Roots are much more sensitive
than leaves!

81. Auxin
Critical concentration varies between tissues
Roots are much more sensitive than leaves!
Made in leaves & transported to roots so [IAA] decreases going down the plant
Most cells are IAA sinks!