1. Seeds Seeds are unique feature of plants

2. Seeds Seeds are unique feature of plants Plant dispersal units

3. Seeds Seeds are unique feature of plants Plant dispersal units Must survive unfavorable conditions until they reach suitable place (and time) to start next generation

4. Seeds Seeds are unique feature of plants Plant dispersal units Must survive unfavorable conditions until they reach suitable place (and time) to start next generation Are dormant

5. Seeds Seeds are unique feature of plants Plant dispersal units Must survive unfavorable conditions until they reach suitable place (and time) to start next generation Are dormant; dehydration is key

6. Seeds Seeds are unique feature of plants Plant dispersal units Must survive unfavorable conditions until they reach suitable place (and time) to start next generation Are dormant; dehydration is key Germinate when conditions are right

7. Seeds Germinate when conditions are right Need way to sense conditions while dormant

8. Seeds Germinate when conditions are right Need way to sense conditions while dormant Need reserves to nourish seedling until it is established

9. Seeds (Usually) required for fruit development!

10. Seeds (Usually) required for fruit development! Role of fruit is to aid seed dispersal!

11. Seed Development (Usually) required for fruit development! Role of fruit is to aid seed dispersal! Unfertilized flowers don’t develop fruit

12. Seed Development (Usually) required for fruit development! Role of fruit is to aid seed dispersal! Unfertilized flowers don’t develop fruits The growth regulators GA, auxin or cytokinin can all induce parthenocarpy

13. Seed Development (Usually) required for fruit development! Role of fruit is to aid seed dispersal! Unfertilized flowers don’t develop fruits The growth regulators GA, auxin or cytokinin can all induce parthenocarpy GA + auxin or GA + cytokinin work best

14. Seed Development (Usually) required for fruit development! Role of fruit is to aid seed dispersal! Unfertilized flowers don’t develop fruits The growth regulators GA, auxin or cytokinin can all induce parthenocarpy GA + auxin or GA + cytokinin work best Hormones from embryo stimulate fruit development

15. Seed Development Hormones from embryo stimulate fruit development Other floral organs make inhibitor that blocks fruit development until they abscise

16. Seed Development Hormones from embryo stimulate fruit development Other floral organs make inhibitor that blocks fruit development until they abscise Divide seed development into three phases of ± equal time

17. Seed Development Divide seed development into three phases of ± equal time 1.Morphogenesis

18. Seed Development Divide seed development into three phases of ± equal time 1.Morphogenesis 2.Maturation

19. Seed Development Divide seed development into three phases of ± equal time 1.Morphogenesis 2.Maturation 3.Dehydration and dormancy

20. Seed Development End result is seed with embryo packaged inside protective coat

21. Seed Development End result is seed with embryo packaged inside protective coat Seed coat is maternal tissue!

22. Seed Development End result is seed with embryo packaged inside protective coat Seed coat is maternal tissue! Derived from epidermal tissue surrounding ovule

23. Seed Development Seed coat is maternal tissue! Derived from epidermal tissue surrounding ovule Determines shape of the seed!

24. Seed Development Seed coat is maternal tissue! Derived from epidermal tissue surrounding ovule Determines shape of the seed! Testa mutants have odd-shaped seeds

25. Seed Development Seed coat is maternal tissue! Derived from epidermal tissue surrounding ovule Determines shape of the seed! Testa mutants have odd-shaped seeds embryo grows to fill shape set by testa!

26. Seed Development End result is seed with embryo packaged inside protective coat Endosperm feeds developing embryo (3n grows faster)

27. Seed Development End result is seed with embryo packaged inside protective coat Endosperm feeds developing embryo (3n grows faster) In many dicots endosperm is absorbed as seed develops

28. Seed Development End result is seed with embryo packaged inside protective coat Endosperm feeds developing embryo (3n grows faster) In many dicots endosperm is absorbed as seed develops Often leave a thin layer of endosperm just inside testa

29. Seed Development End result is seed with embryo packaged inside protective coat Endosperm feeds developing embryo (3n grows faster) In many dicots endosperm is absorbed as seed develops Often leave a thin layer of endosperm just inside testa Seeds have three different genetic compositions!

30. Seed Development End result is seed with embryo packaged inside protective coat Endosperm feeds developing embryo (3n grows faster) In many dicots endosperm is absorbed as seed develops In many monocots endosperm is seedling food

31. Seed Development 1.Embryogenesis 2.Maturation: cell division ± ceases, but cells still expand

32. Seed Development 1.Embryogenesis 2.Maturation: cell division ± ceases, but cells still expand Controlled by different genes: viviparous mutants have normal morphogenesis but don’t mature

33. Seed Development 1.Embryogenesis 2.Maturation: cell division ± ceases, but cells still expand Controlled by different genes: viviparous mutants have normal morphogenesis but don’t mature Many morphogenesis mutants show normal maturation

34. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds

35. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds ABA made by maternal tissue initiates this process

36. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds ABA made by maternal tissue initiates this process Seed [ABA] increases as enter maturation phase

37. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds ABA made by maternal tissue initiates this process Seed [ABA] increases as enter maturation phase Switch to ABA synthesis by embryo & endosperm during maturation

38. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds Storage compounds are key for seedlings and crops

39. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds Storage compounds are key for seedlings and crops Proteins, lipids & carbohydrates but vary widely

40. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds Storage compounds are key for seedlings and crops Proteins, lipids & carbohydrates but vary widely Many 2˚ metabolites

41. Seed Development Maturation: cell division ± ceases, but cells still expand Activate new genes for making storage compounds Storage compounds are key for seedlings and crops Proteins, lipids & carbohydrates but vary widely Next prepare for desiccation as ABA made by embryo (+endosperm) increases

42. Seed Development Next prepare for desiccation as ABA made by embryo (+endosperm) increases ABA peaks at mid-maturation, then declines (but not to 0)

43. Seed Development Next prepare for desiccation as ABA made by embryo (+endosperm) increases ABA peaks at mid-maturation, then declines (but not to 0) Blocks vivipary during maturation

44. Seed Development Next prepare for desiccation as ABA made by embryo (+endosperm) increases Make proteins & other molecules (eg trehalose) that help tolerate desiccation

45. Seed Development Next prepare for desiccation as ABA made by embryo (+endosperm) increases Make proteins & other molecules (eg trehalose) that help tolerate desiccation Next dehydrate (to 5% moisture content) and go dormant

46. Seed Development Next dehydrate (to 5% moisture content) and go dormant Very complex: 2 classes of dormancy 1.Coat-imposed 2.embryo dormancy

47. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake.

48. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake. 2.Mechanical constraint

49. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake. 2.Mechanical constraint 3.Interference with gas exchange.

50. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake. 2.Mechanical constraint 3.Interference with gas exchange 4.Retaining inhibitors (ABA)

51. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake. 2.Mechanical constraint 3.Interference with gas exchange 4.Retaining inhibitors (ABA) 5.Inhibitor production (ABA)

52. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) 1.Preventing water uptake. 2.Mechanical constraint 3.Interference with gas exchange 4.Retaining inhibitors (ABA) 5.Inhibitor production (ABA) Embryo dormancy (Zygotic effect)

53. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) Embryo dormancy (Zygotic effect) 1.Making inhibitors (ABA?)

54. Seed Development Coat-imposed Coat-imposed dormancy (maternal effect) Embryo dormancy (Zygotic effect) 1.Making inhibitors (ABA?) 2.Absence of activators (GA)

55. Seed Development Coordinated with fruit ripening: fruit’s job is to protect & disperse seed Seeds remain dormant until sense appropriate conditions: some Lotus germinated after 2000 years!

56. Seed germination Seeds remain dormant until sense appropriate conditions: some Lotus germinated after 2000 years! Water

57. Seed germination Seeds remain dormant until sense appropriate conditions: some Lotus germinated after 2000 years! Water Temperature: some seeds require vernalization = prolonged cold spell

58. Seed germination Seeds remain dormant until sense appropriate conditions: some Lotus germinated after 2000 years! Water Temperature: some seeds require vernalization = prolonged cold spell May break down hydrophobic seed coat

59. Seed germination Seeds remain dormant until sense appropriate conditions: Water Temperature: some seeds require vernalization = prolonged cold spell May break down hydrophobic seed coat May allow inhibitor (eg ABA) to go away

60. Seed germination Seeds remain dormant until sense appropriate conditions: Water Temperature: some seeds require vernalization = prolonged cold spell May break down hydrophobic seed coat May allow inhibitor (eg ABA) to go away May allow synthesis of specific RNAs

61. Seed germination Seeds remain dormant until sense appropriate conditions: Water Temperature: some seeds require vernalization = prolonged cold spell May break down hydrophobic seed coat May allow inhibitor (eg ABA) to go away May allow synthesis of specific RNAs Many require light: says photosynthesis is possible

62. Seed germination Seeds remain dormant until sense appropriate conditions: Water Temperature: some seeds require vernalization = prolonged cold spell Many require light: says photosynthesis is possible often small seeds with few reserves

63. Seed germination Seeds remain dormant until sense appropriate conditions: Many require light: says that they will soon be able to photosynthesize: often small seeds with few reserves Hormones can also trigger (or stop) germination ABA blocks it GA stimulates it

64. Seed germination Seeds remain dormant until sense appropriate conditions: Many require light: says that they will soon be able to photosynthesize: often small seeds with few reserves Hormones can also trigger (or stop) germination ABA blocks it GA stimulates it Germination is a two step process Imbibition

65. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it.

66. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it. Seeds with endosperm pop testa first, then endosperm

67. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it. Seeds with endosperm pop testa first, then endosperm Separate processes: can pop testa but not endosperm

68. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it. Seeds with endosperm pop testa first, then endosperm Separate processes: can pop testa but not endosperm Testa and endosperm have different genotypes!

69. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it. Seeds with endosperm pop testa first, then endosperm Next embryo must start metabolism and cell elongation

70. Seed germination Germination is a two step process Imbibition is purely physical: seed swells as it absorbs water until testa pops. Even dead seeds do it. Next embryo must start metabolism and cell elongation This part is sensitive to the environment, esp T & pO 2

71. Seed germination Germination is a two step process Next embryo must start metabolism and cell elongation This part is sensitive to the environment, esp T & pO 2 Hormones also play a complex role

72. Seed germination Germination is a two step process Next embryo must start metabolism and cell elongation This part is sensitive to the environment, esp T & pO 2 Hormones also play a complex role GA, Ethylene and BR all stimulate

73. Seed germination Germination is a two step process Next embryo must start metabolism and cell elongation This part is sensitive to the environment, esp T & pO 2 Hormones also play a complex role GA, Ethylene and BR all stimulate ABA blocks

74. Seed germination Germination is a two step process Next embryo must start metabolism and cell elongation This part is sensitive to the environment, esp T & pO 2 Once radicle has emerged, vegetative growth begins