1. The Plant Kingdom: Seed Plants
Chapter 28

2. Learning Objective 1
Compare the features of gymnosperms and angiosperms

3. Two Groups of Seed Plants
Gymnosperms
seeds are totally exposed or borne on the scales of cone
ovary wall does not surround the ovules
Angiosperms
flowering plants
produce seeds within a fruit (a mature ovary)

4. Gymnosperm and Angiosperm Evolution

5. Gymnosperms Angiosperms Gnetophytes Ginkgoes Conifers Cycads Evolution
of flowering plants
Figure 28.2: Gymnosperm and angiosperm evolution.
This cladogram shows one hypothesis of phylogenetic relationships among living seed plants, based on structural evidence and molecular comparisons. The arrangement of the phyla shown here may change as future analyses help clarify relationships.
Evolution of seeds
Fig. 28-2, p. 602

6. KEY CONCEPTS
Seed plants include gymnosperms and angiosperms

7. Learning Objective 2 Trace the steps in the life cycle of a pine
Compare its sporophyte and gametophyte generations

8. Conifers

9. Gymnosperms Angiosperms Gnetophytes Ginkgoes Conifers Cycads
Figure 28.3: Conifers.
(a) Colorado blue spruce (Picea pungens) is a coniferous evergreen tree native to Colorado, Wyoming, Utah, and New Mexico. Spruces are important ornamental plants, as shown in this New Jersey garden. (b, c) Leaf variation in conifers. (b) Needles of white pine (Pinus strobus). (c) Small, scalelike leaves of American arborvitae (Thuja occidentalis).
Fig (1), p. 603

10. Fig. 28-3 (a-c), p. 603 Figure 28.3: Conifers.
(a) Colorado blue spruce (Picea pungens) is a coniferous evergreen tree native to Colorado, Wyoming, Utah, and New Mexico. Spruces are important ornamental plants, as shown in this New Jersey garden. (b, c) Leaf variation in conifers. (b) Needles of white pine (Pinus strobus). (c) Small, scalelike leaves of American arborvitae (Thuja occidentalis).
Fig (a-c), p. 603

11. Pine Life Cycle 1 Pine tree Pine gametophytes a mature sporophyte
extremely small
nutritionally dependent on sporophyte generation

12. Pine Life Cycle 2 Pine is heterosporous
produces microspores and megaspores in separate cones
Male cones produce microspores that develop into pollen grains (immature male gametophytes)
carried by air currents to female cones

13. Pine Life Cycle 3 Female cones produce megaspores
One of each four megaspores (meiosis) develops into a female gametophyte
within an ovule (megasporangium)

14. Pine Life Cycle 4 Pollination Pollen tube After fertilization
transfer of pollen to female cones
Pollen tube
grows through megasporangium to egg within archegonium
After fertilization
zygote develops into embryo encased inside seed adapted for wind dispersal

15. Pine Life Cycle

16. Each scale bears two microsporangia 2 Microsporangium
Microspores, each of which develops into a pollen grain
Scale from a male cone
Pollen grains are transferred to the female cone by wind 3
Male cone 3 4
Scale from a female cone
Female gametophyte
Each scale bears two ovules (megasporangia)
Megasporangium
Megaspore Growing pollen tube
Ovule
HAPLOID (n) GAMETOPHYTE GENERATION
Meiosis
Immature female cone
Fertilization
DIPLOID (2n) SPOROPHYTE GENERATION
Zygote 5
Papery wings
Second sperm nucleus
Sperm nucleus united with egg nucleus
Figure 28.4: Life cycle of pine.
One major advantage of gymnosperms over the seedless vascular plants is the production of wind-borne pollen grains. See text for a detailed description.
Pollen tube
Seed coat
Male cones (pollen cones) 1 6
Mature female cone (seed cone)
Embryo
Two seeds on the upper surface of the scale
Newly germinated seedling
Female gametophyte (nutritive tissue)
Pine (mature sporophyte)
Fig. 28-4, p. 604

17. Insert “Pine life cycle”
pine_life_cycle.swf

18. Learning Objective 3
What features distinguish gymnosperms from bryophytes and ferns?

19. Gymnosperms Are vascular plants Produce seeds
unlike bryophytes
Produce seeds
unlike bryophytes and ferns
Produce wind-borne pollen grains
unlike ferns and other seedless vascular plants

20. KEY CONCEPTS
Gymnosperms produce exposed seeds, usually in cones borne on the sporophytes

21. Learning Objective 4
What are the four phyla of gymnosperms?

22. Conifers (Phylum Coniferophyta)
Largest phylum of gymnosperms
Woody plants that bear needles (leaves that are usually evergreen)
produce seeds in cones
Most are monoecious
have male and female reproductive parts in separate cones on same plant

23. Male and Female Cones

24. KEY CONCEPTS
Conifers are the most diverse and numerous of the four living gymnosperm phyla

25. Cycads (Phylum Cycadophyta)
Palmlike or fernlike in appearance
Are dioecious
have male and female reproductive structures on separate plants
but reproduce with pollen and seeds in conelike structures

26. Cycads

27. Gymnosperms Angiosperms Gnetophytes Ginkgoes Conifers Cycads
Figure 28.6: Cycads.
Fig (1), p. 605

28. Female strobilus (seed cone)
Figure 28.6: Cycads.
Female strobilus (seed cone)
Fig. 28-6a, p. 605

29. Figure 28.6: Cycads.
Fig. 28-6b, p. 605

30. Phylum Ginkgophyta Ginkgo biloba
only surviving species in phylum
deciduous, dioecious tree
Female ginkgo produces fleshy seeds directly on branches

31. Ginkgo

32. Gymnosperms Angiosperms Gnetophytes Ginkgoes Conifers Cycads
Figure 28.7: Ginkgo, or maidenhair tree.
Fig (1), p. 606

33. Figure 28.7: Ginkgo, or maidenhair tree.
Fig. 28-7a, p. 606

34. Figure 28.7: Ginkgo, or maidenhair tree.
Fig. 28-7b, p. 606

35. Gnetophytes (Phylum Gnetophyta)
Share some traits with angiosperms

36. Gymnosperms Angiosperms Gnetophytes Ginkgoes Conifers Cycads
Figure 28.8: Gnetophytes.
Fig (1), p. 607

37. Gnetophytes

38. Learning Objective 5
What features distinguish flowering plants from other plants?

39. Flowering Plants Angiosperms (phylum Anthophyta)
Vascular plants that produce flowers and seeds enclosed within a fruit
Most diverse and successful plant group

40. Flowering Plants

41. Flowering Plants Flower Ovules enclosed within ovary
sepals, petals, stamens, carpels
functions in sexual reproduction
Ovules enclosed within ovary
unlike gymnosperms
After fertilization
ovules become seeds
ovary develops into fruit

42. Floral Structure

43. Fig. 28-10a, p. 609 Figure 28.10: Floral structure.
(a) An Arabidopsis thaliana flower.
Fig a, p. 609

44. Pollen grain (each will produce two sperm cells)
Female floral parts
Male floral parts
Pollen grain (each will produce two sperm cells)
Stigma
PISTIL (consisting of one or more carpels)
Style
Anther
STAMEN
Ovary
Filament
Ovules (each
producing one egg cell)
Petal
Figure 28.10: Floral structure.
(b) This cutaway view of an Arabidopsis flower shows the details of basic floral structure. Each flower has four sepals (two are shown), four petals (two are shown), six stamens, and one long pistil. Four of the stamens are long, and two are short (two long and two short are shown). Pollen grains develop within sacs in the anthers. In Arabidopsis, the compound pistil consists of two carpels that each contain numerous ovules. This flower is both a complete and a perfect flower.
Sepal
Receptacle
Peduncle
Fig b, p. 609

45. Parts of a Flower

46. Petals
Sepals
Figure 28.11: Parts of a flower.
Fig a, p. 610

47. Stamen
Pistil
Figure 28.11: Parts of a flower.
Fig b, p. 610

48. Simple and Compound Pistils

49. Stigma Ovules Style Ovary wall Ovary Fig. 28-12a, p. 611
Figure 28.12: Simple and compound pistils.
Fig a, p. 611

50. One carpel Ovules Stigma Style Ovary wall Ovary Fig. 28-12b, p. 611
Figure 28.12: Simple and compound pistils.
Ovary
Fig b, p. 611

51. One carpel Ovules Stigma Style Ovary wall Ovary Stepped Art
Figure 28.12: Simple and compound pistils.
Stepped Art
Fig b, p. 611

52. KEY CONCEPTS
Angiosperms produce ovules enclosed within carpels; following fertilization, seeds develop from the ovules, and the ovaries of carpels become fruits

53. Learning Objective 6 Explain the life cycle of a flowering plant
Describe double fertilization

54. Flowering Plant Life Cycle 1
Sporophyte generation dominant
Gametophytes extremely reduced in size
nutritionally dependent on sporophyte generation
Heterosporous
produce microspores, megaspores in flower

55. Flowering Plant Life Cycle 2
Microspore develops into a pollen grain (immature male gametophyte)
One of each four megaspores (meiosis) develops into embryo sac (female gametophyte)

56. Flowering Plant Life Cycle 3
Embryo sac contains seven cells with eight nuclei
Egg cell and central cell with two polar nuclei participate in fertilization

57. Flowering Plant Life Cycle

58. Developing pollen tube of mature male gametophyte Pollination
Each microspore develops into a pollen grain 6
Embryo sac (mature female gametophyte) 5
Pollen grain (immature male gametophyte)
Microspore
Tetrad of microspores
Pollen tube 3
Polar nuclei
Megaspore
Two sperm cells
HAPLOID (n) GAMETOPHYTE GENERATION
Egg nucleus
Meiosis
Double fertilization
DIPLOID (2n) SPOROPHYTE GENERATION 7
Ovary 4 2
Endosperm (3n)
Megasporocyte
Zygote (2n)
Figure 28.13: Life cycle of flowering plants.
A significant feature of the flowering plant life cycle is double fertilization, in which one sperm cell unites with the egg, forming a zygote, and the other sperm cell unites with the two polar nuclei, forming a triploid cell that gives rise to endosperm. See text for a detailed description.
Megasporangium (ovule)
Fruit 8
Embryo
Seed
Seed coat
Microsporocytes within microsporangia
Seedling
Anther 1
Flower of mature sporophyte
Fig , p. 612

59. Double Fertilization Characteristic of flowering plants
Results in formation of
diploid zygote
triploid endosperm

60. Insert “Monocot life cycle”
angiosperm_cycle.swf

61. Explore plant life cycles by clicking on the figures in ThomsonNOW.

62. Learning Objective 7
Contrast eudicots and monocots, the two largest classes of flowering plants

63. Monocots (Class Monocotyledones)
Most have floral parts in threes
Seeds each contain 1 cotyledon
Endosperm
nutritive tissue in mature seeds

64. Eudicots (Class Eudicotyledones)
Usually have floral parts in fours or fives
or multiples thereof
Seeds each contain 2 cotyledons
Cotyledons
nutritive organs in mature seeds
absorbed nutrients in endosperm

65. Monocot and Eudicot

66. Learning Objective 8
What are the evolutionary adaptations of flowering plants?

67. Reproduction Flowering plants reproduce sexually by forming flowers
After double fertilization, seeds form within fruits
Wind, water, insects, animals transfer pollen grains

68. Structures Efficient water-conducting vessel elements in xylem
Efficient carbohydrate-conducting sieve tube elements in phloem

69. KEY CONCEPTS
Angiosperms, which compose a single phylum, dominate the land and exhibit great diversity in both vegetative and reproductive structures

70. Insert “Flower parts”
flower_parts.swf

71. Learn more about flower structure by clicking on the figure in ThomsonNOW.

72. Learning Objective 9
Summarize the evolution of gymnosperms from seedless vascular plants
Trace the evolution of flowering plants from gymnosperms

73. Evolution 1 Seed plants arose from seedless vascular plants
Progymnosperms
seedless vascular plants
had megaphylls and “modern” woody tissue
probably gave rise to conifers and seed ferns

74. Progymnosperm
Seed Fern

75. Evolution 2
Seed ferns
probably gave rise to cycads and ginkgo
Evolution of gnetophytes, particularly their relationship to flowering plants, is unclear

76. Evolution 3
Flowering plants probably descended from gymnosperms with specialized features
leaves with broad, expanded blades
closed carpels
Flowering plants likely arose only once

77. Fossil Angiosperms

78. Figure 28.17: The oldest known fossil angiosperm.
This fossil of Archaefructus shows a carpel-bearing stem. Discovered in northeastern China, it is about 125 million years old.
Carpel
Ovule
5 mm
Fig , p. 615

79. Scars on reproductive axis
Pistils
Scars on reproductive axis
Figure 28.18: Fossil flower.
The fossilized flower of the extinct plant Archaeanthus linnenbergeri, which lived about 100 mya. The scars on the reproductive axis (receptacle) may show where stamens, petals, and sepals were originally attached but abscised (fell off). Many spirally arranged pistils were still attached at the time this flower was fossilized.
7 mm
Fig , p. 615

80. Evolution of Flowering Plants

81. Evolution of vessel elements
Basal Angiosperms
Core Angiosperms
Amborella
Water lilies
Star anise
Magnoliids
Monocots
Eudicots
Figure 28.19: Evolution of flowering plants.
Evolution of vessel elements
Evolution of flowering plants
Fig a, p. 616

82. Figure 28.19: Evolution of flowering plants.
Fig b, p. 616

83. Figure 28.19: Evolution of flowering plants.
Fig c, p. 616

84. Figure 28.19: Evolution of flowering plants.
Fig d, p. 616

85. Figure 28.19: Evolution of flowering plants.
Fig e, p. 616

86. KEY CONCEPTS
Gymnosperms and angiosperms evolved from ancestral seedless vascular plants