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

2. Auxin signaling
Auxin receptors eg TIR1 are E3 ubiquitin ligases!
Upon binding auxin they activate complexes targeting AUX/IAA proteins for degradation!
AUX/IAA inhibit ARF
transcription factors,
so this turns on
"early genes"
Some early genes turn on
'late genes" needed for
development

3. Auxin signaling
ABP1 is a different IAA receptor localized in ER
Activates PM H+ pump by sending it to PM & keeping it there
Does not affect gene expression!

4. Auxin & other growth regulators
Some "late genes" synthesize ethylene (normally a wounding response): how 2,4-D kills?
Auxin/cytokinin determines
whether callus forms roots or shoots

5. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division

6. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division
van Overbeek (1941): coconut milk stimulates division

7. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division
van Overbeek (1941): coconut milk stimulates division
Miller… Skoog (1955): degraded DNA stimulates division!

8. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division
van Overbeek (1941): coconut milk stimulates division
Miller… Skoog (1955): degraded DNA stimulates division!
Kinetin was the breakdown product

9. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division
van Overbeek (1941): coconut milk stimulates division
Miller… Skoog (1955): degraded DNA stimulates division!
Kinetin was the breakdown product
Derived from adenine

10. Cytokinins
Discovered as factors which induce cultured cells to divide
Haberlandt (1913): phloem chemical stimulates division
van Overbeek (1941): coconut milk stimulates division
Miller… Skoog (1955): degraded DNA stimulates division!
Kinetin was the breakdown product
Derived from adenine
Requires auxin to stimulate division

11. Cytokinins
Requires auxin to stimulate division
Kinetin/auxin determines tissue formed (original fig)

12. Cytokinins
Requires auxin to stimulate division
Kinetin/auxin determines tissue formed
Inspired search for natural cytokinins
Miller& Letham (1961) ± simultaneously found zeatin in corn
Kinetin trans- Zeatin

13. Cytokinins
Miller& Letham (1961) ± simultaneously found zeatin
Later found in many spp including coconut milk
Kinetin trans-Zeatin

14. Cytokinins
Miller& Letham (1961) ±
simultaneously found zeatin
Later found in many spp
including coconut milk
Trans form is more active,
but both exist (& work)
Many other natural &
synthetics have been identified

15. Cytokinins
Many other natural & synthetics have been identified
Like auxins, many are bound to sugars or nucleotides

16. Cytokinins
Many other natural & synthetics have been identified
Like auxins, many are bound to sugars or nucleotides
Inactive, but easily converted

17. Cytokinin Synthesis
Most cytokinins are made at root
apical meristem & transported to
sinks in xylem

18. Cytokinin Synthesis
Most cytokinins are made at root
apical meristem & transported to
sinks in xylem
Therefore have inverse gradient
with IAA

19. Cytokinin Synthesis
Most cytokinins are made at root
apical meristem & transported to
sinks in xylem
Therefore have inverse gradient
with IAA
Why IAA/CK affects
development

20. Cytokinin Synthesis
Most cytokinins are made at root
apical meristem & transported to
sinks in xylem
Therefore have inverse gradient
with IAA
Why IAA/CK affects development
Rapidly metabolized by sink

21. Cytokinin Effects
Regulate cell division
Need mutants defective in CK metabolism or signaling to detect this in vivo

22. Cytokinin Effects
Regulate cell division
Need mutants defective in CK metabolism or signaling to detect this in vivo
SAM & plants are smaller when
[CK]

23. Cytokinin Effects
SAM & plants are smaller when [CK]
Roots are longer!

24. Cytokinin Effects
Usually roots have too much CK: inhibits division!
Cytokinins mainly root & shoot meristems

25. Cytokinin Effects
Cytokinins mainly root & shoot meristems
Control G1-> S & G2-> M transition

26. Cytokinin Effects
Promote lateral bud growth

27. Cytokinin Effects
Promote lateral bud growth
Delay leaf senescence

28. Cytokinin Effects
Promote lateral bud growth
Delay leaf senescence
Promote cp development, even in dark

29. Cytokinin Receptors
Receptors were identified by mutation
Resemble bacterial 2-component signaling systems

30. Cytokinin Action
1.Cytokinin binds receptor's extracellular domain

31. Cytokinin Action
1.Cytokinin binds receptor's extracellular domain
2. Activated protein kinases His kinase & receiver domains

32. Cytokinin Action
1.Cytokinin binds receptor's extracellular domain
2. Activated protein kinases His kinase & receiver domains
3. Receiver kinases His-P transfer relay protein (AHP)

33. Cytokinin Action
1.Cytokinin binds receptor's extracellular domain
2. Activated protein kinases His kinase & receiver domains
3. Receiver kinases His-P transfer
relay protein (AHP)
4. AHP-P enters nucleus &
kinases ARR response regulators

34. Cytokinin Action
4. AHP-P enters nucleus &
kinases ARR response
regulators
5. Type B ARR induce type A

35. Cytokinin Action
4. AHP-P enters nucleus &
kinases ARR response
regulators
5. Type B ARR induce type A
6. Type A create cytokinin
responses

36. Cytokinin Action
4. AHP-P enters nucleus &
kinases ARR response
regulators
5. Type B ARR induce type A
6. Type A create cytokinin
responses
7. Most other effectors are unknown
but D cyclins is one effect.

37. Auxin & other growth regulators
Some "late genes" synthesize ethylene (normally a wounding response): how 2,4-D kills?
Auxin/cytokinin determines whether callus forms roots or shoots
Auxin induces Gibberellins

38. Gibberellins
Discovered by studying "foolish seedling" disease in rice
Hori (1898): caused by a fungus

39. Gibberellins
Discovered by studying "foolish seedling" disease in rice
Hori (1898): caused by a fungus
Sawada (1912): growth is caused by fungal stimulus

40. Gibberellins
Discovered by studying "foolish seedling" disease in rice
Hori (1898): caused by a fungus
Sawada (1912): growth is caused by fungal stimulus
Kurosawa (1926): fungal filtrate causes these effects

41. Gibberellins
Discovered by studying "foolish seedling" disease in rice
Kurosawa (1926): fungal filtrate causes these effects
Yabuta (1935): purified gibberellins from filtrates of
Gibberella fujikuroi cultures

42. Gibberellins
Discovered by studying "foolish seedling" disease in rice
Kurosawa (1926): fungal filtrate causes these effects
Yabuta (1935): purified gibberellins from filtrates of
Gibberella fujikuroi cultures
Discovered in
plants in 1950s

43. Gibberellins
Discovered in plants in 1950s
"rescued" some dwarf corn & pea mutants

44. Gibberellins
Discovered in plants in 1950s
"rescued" some dwarf corn & pea mutants
Made rosette plants bolt

45. Gibberellins
Discovered in plants in 1950s
"rescued" some dwarf corn & pea mutants
Made rosette plants bolt
Trigger adulthood in
ivy & conifers

46. Gibberellins
"rescued" some dwarf corn & pea mutants
Made rosette plants bolt
Trigger adulthood in ivy & conifers
Induce growth
of seedless fruit

47. Gibberellins
"rescued" some dwarf corn & pea mutants
Made rosette plants bolt
Trigger adulthood in ivy & conifers
Induce growth of seedless fruit
Promote seed germination

48. Gibberellins
"rescued" some dwarf corn & pea mutants
Made rosette plants bolt
Trigger adulthood in ivy & conifers
Induce growth of seedless fruit
Promote seed germination
Inhibitors shorten stems: prevent lodging

49. Gibberellins
"rescued" some dwarf corn
& pea mutants
Made rosette plants bolt
Trigger adulthood in ivy
& conifers
Induce growth of seedless fruit
Promote seed germination
Inhibitors shorten stems:
prevent lodging
>136 gibberellins (based on
structure)!

50. Gibberellins
>136 gibberellins (based on
structure)!
Most plants have >10

51. Gibberellins
>136 gibberellins (based on
structure)!
Most plants have >10
Activity varies dramatically!

52. Gibberellins
>136 gibberellins (based on
structure)!
Most plants have >10
Activity varies dramatically!
Most are precursors or
degradation products

53. Gibberellins
>136 gibberellins (based on
structure)!
Most plants have >10
Activity varies dramatically!
Most are precursors or
degradation products
GAs 1, 3 & 4 are most bioactive

54. Gibberellin signaling
Used mutants to learn about GA signaling

55. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis

56. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis
Varies during development

57. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis
Varies during development
Others hit GA signaling
Gid = GA insensitive

58. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis
Varies during development
Others hit GA signaling
Gid = GA insensitive
encode GA receptors

59. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis
Varies during development
Others hit GA signaling
Gid = GA insensitive
encode GA receptors
Sly = E3 receptors 59

60. Gibberellin signaling
Used mutants to learn about GA signaling
Many are involved in GA synthesis
Varies during development
Others hit GA signaling
Gid = GA insensitive
encode GA receptors
Sly = E3 receptors
DELLA (eg rga) =
repressors of GA signaling

61. Gibberellins
GAs 1, 3 & 4 are most bioactive
Act by triggering degradation
of DELLA repressors

62. Gibberellins
GAs 1, 3 & 4 are most bioactive
Made at many locations in plant
Act by triggering degradation
of DELLA repressors
w/o GA DELLA binds & blocks activator (GRAS)

63. Gibberellins
Act by triggering degradation of DELLA repressors
w/o GA DELLA binds & blocks activator
bioactive GA binds GID1; GA-GID1 binds DELLA & marks for destruction

64. Gibberellins
Act by triggering degradation of DELLA repressors
w/o GA DELLA binds & blocks activator
bioactive GA binds GID1; GA-GID1 binds DELLA & marks for destruction
GA early genes are
transcribed, start
GA responses

65. Gibberellins & barley germination
GA made by embryo diffuse to aleurone & trigger events leading to germination

66. GA & stem elongation
GA increase elongation, but lag >>> IAA

67. GA & stem elongation
GA increase elongation, but lag >>> IAA
Increase cell wall creepage, but don't change pH (much)

68. GA & stem elongation
GA increase elongation, but lag >>> IAA
Increase cell wall creepage, but don't change pH (much)
Part of effect is increased
expansin gene expression

69. GA & stem elongation
GA increase elongation, but lag >>> IAA
Increase cell wall creepage, but don't change pH (much)
Part of effect is increased
expansin gene expression
Another part is increased
cell division