1. Gymnosperms & Angiosperms
Seed Plants
Gymnosperms & Angiosperms

2. Evolution Of Land Plants
REMEMBER:
Terrestrial plants evolved from a green algal ancestor
The earliest land plants were nonvascular, spore producers (bryophytes)
Ferns were the 1st vascular, spore producing plants
Gymnosperms & angiosperms were the 1st vascular, seed plants

4. Characteristics of Seed Plants
Multicellular
Autotrophic
Alternation of Generations
Reproduce by Seeds
Vascular tissue for transport
Heterosporous – make female megaspores & male microspores
Dandelion dispersing seeds

5. Reasons for Success on Land
Waxy cuticle
Stomata with guard cells to open & close
Gametes protected in tissue called Gametangia
Pollen tube to transfer sperm to the egg instead of water
Seeds protect developing embryo & contain food

6. Seeds and Fruits

7. Seeds Seeds contain a young, developing plant embryo
Seeds are covered with a protective seed coat (testa)
Inside is stored food or endosperm that the young plant uses as it begins to sprout or germinate
Seeds form from ripened ovules after fertilization

8. Parts of a Seed Embryo Primary root or Radicle
One or two embryonic leaves called Cotyledons
Plumule becomes the shoot
Stem like portion below cotyledons called Hypocotyl
Stem like portion above cotyledons called Epicotyl

9. Parts of a Seed

11. Endosperm (3n)
Seed Coat
Cotyledon
Plumule
Epicotyl
Hypocotyl
Radicle

12. Seed Dispersal
Seeds must be scattered (dispersed) away from the parent plant
Testa (seed coats) may last thousands of years
Seeds eaten by animals aren’t digested but pass out with wastes

13. Seed Dispersal
Seeds may have adaptations such as stickers, hooks, or fuzz to adhere to animals

14. Seed Dispersal Both water and wind can scatter seeds Wind Dispersal
Water Dispersal

15. Seed Germination Early growth of plant embryo
Begins when seed absorbs water & breaks seed coat (testa)
Embryo uses stored food of cotyledons to begin growing

16. Fruits Form when ovary with ovules (eggs) ripens
May be dry and hardened (nuts)
May be enlarged and fleshy (berries, apples, tomatoes)
Used to help disperse seeds

17. Types of Fruits Simple fruits – form from a single ovary (apple)
Aggregate fruits – forms from several ovaries of the same flower (blackberry)
Multiple fruit – forms from several ovaries of different flowers (inflorescence)

19. Plants with Vascular Tissue

20. Taxonomy of Vascular Seed Plants
Phylum Gnetophyta: Ephedra, Gnetum
Phylum Cycadophyta: Cycads
Phylum Ginkgophyta: Ginkgo
Phylum Coniferophyta: Conifers
Phylum Anthophyta: Flowering plants
gymnosperrms
angiosperms

21. Sporophyte microsporangium megasporangiumx microspores megasporesx microgametophyte megagametophytex antheridium archegonium lsperm eggmm

22. Seed plants (Ch.30)
Tiny gametophytes protected in ovules and pollen grains
Advantages of seeds
Gymnosperms have “naked seeds”
Angiosperms have seeds in fruits
Monocots
Eudicots

23. 12: Gymnosperms and Angiosperms
Intro and evolution
Life cycle and reproduction
Uses and significance
Angiosperms: Flowering plants
Monocots vs. dicots

24. Kingdom Plantae Evolutionary tree of plants
From primitive more advanced traits
__________
Gymnosperms
_______
Bryophytes
Flowers
________
Green alga
ancestor
Vascular 
Terrestrial 

25. GYMNOSPERMS
Introduction – Gymnosperm means “naked seed” (From the Greek: gymnos = naked; sperm = seed)
More advanced than ferns – do not have spores, they have seeds.
The seeds of the gymnosperms lack a protective enclosure (unlike flowering plants which have flowers and fruit).
Examples of gymnosperms:
Conifers (pine trees), cycads, ginkgo biloba

26. Evolution of gymnosperms
Gymnosperms evolved from fern-like ancestors
Advancements of gymnosperms over ferns:
1. Seed (plant embryo, food storage tissue, and seed coat)
2. Gymnosperms do not depend on water for fertilization (have air-borne pollen)
3. Have a more dominant sporophyte generation
4. Have a more efficient vascular system

27. Gymnosperm life cycle Exhibits alternation of generations
Sporophyte generation (2n) is dominant
Gametophyte generation (1n) is contained in and dependent on the sporophyte generation
Gymnosperm life cycle

28. Gymnosperm lifecycle

29. Sporophyte generation
Sporophyte produces two types of spores (heterosporous)
Megasporangium – undergoes meiosis to produce megaspores (female gametophyte)
sporangium – undergoes meiosis to produce haploid microspores, germinate to produce male gametophyte (pollen)
Many gymnosperms use wind for pollination and seed dispersal

30. Wood produced by gymnosperms
Gymnosperms have a very efficient and effective vascular system
Usually woody plants
Xylem  wood of a tree
Phloem  bark of the tree
Wood is formed from secondary growth

31. Primary vs. secondary growth
1. Primary growth – occurs in apical meristems of shoots and roots
Results in increase in length
2. Secondary growth – derived from secondary or lateral meristems
Results in increase in girth (width)
Common in trees (wood and bark)

32. Secondary growth
The cambium forms secondary xylem and secondary phloem
Wood – is secondary xylem; cells are dead at maturity and only cell wall remains
Bark – is secondary phloem (conducts food)

33. Annual rings
Annual rings – xylem formed by the vascular cambium during one growth season
Early Spring wood – vessel diameter is large, xylem walls are thinner
Late Summer wood – vessel diameter is small, walls are thicker
Tropical trees: have no annual rings, because seasons are so similar

34. Vascular tissue: Trees
Vascular tissue is located on the outer layers of the tree.
bark
wood
_______
Vascular cambium
________
copyright cmassengale

35. Gymnosperms Conifers are most important group of gymnosperms
Largest and most familiar group
Bare seeds in cones
Staminate cones – male cones
Ovulate cones – _________ cones
Seeds produced on an open scale
(Do not produce flowers or fruit)

36. Gymnosperms Mainly woody plants that include
Oldest living trees: bristlecone pine, yrs old!
Most massive trees (giant sequoia): up to 375 ft. tall, 41 ft wide!
Tallest living trees (redwoods)

37. Conifers Conifers adapted to temperate to cold regions
Narrow leaves (needles) help to conserve water
Covered by resins – for protection from predators, fire, etc.

38. Other gymnosperms
Cycads – short shrubs, native to tropical regions (look like palms)
Ginkgo biloba – a “living fossil”, male and female tree, used as a medicinal plant

39. Other gymnosperms
Welwitschia – a bizarre gymnosperm plant that grows in Namib desert (So. Africa).
Live up to 2000 years in these extreme conditions!
Only makes two leaves throughout its life. It takes water from sea mist

40. Significance of gymnosperms
Ecological importance:
Provide food and habitat for wildlife
Forests prevent soil erosion
Reduce greenhouse-effect gasses
Economic and commercial importance:
Lumber for wood, paper, etc.
Resins – wood, furniture, etc.
Ornamental plants (trees, landscaping)
Food – pine nuts (pesto, etc.)

41. ANGIOSPERMS Angiosperm means “covered seed” Have flowers
Have fruits with seeds
Live everywhere – dominant plants in the world
260,000 species (88% of Plant Kingdom)
Angiosperms are the most successful and advanced plants on earth

42. Evolution of Angiosperms
Advancements over gymnosperms:
Angiosperms have flowers – many use pollinators
Fruits and seeds – adapted for dispersal
Double fertilization of the endosperm in the seed

43. Angiosperm life cycle
Flower has male and female sex organs

44. Flower structure
Male sex organs: Stamens, composed of anther – organ that produces pollen (male gametophyte)
Female sex organs: The carpel
Ovary is the enlarged basal portion of carpel that contains the ovules (female gametophyte)
The stigma is the receptive portion of the carpel for pollen grains to adhere

45. Flower structure Non-reproductive parts:
Sepals (green) are the outermost whorl of leaf-like bracts
Petals (usually colored) are the inner whorl of leaf-like bracts
Both can have various shapes and colors
Tepals -_______________

46. Angiosperm life cycle
Heterosporous: forms two different types of spores (micro- and megaspores; male and female spores)
Male – pollen grains contain tube nucleus and generative cell (2 sperm nuclei)
Female – female gametophyte contains egg and 2 polar nuclei

47. Angiosperm lifecycle
Flowering plants exhibit alternation of generations. The large, familiar flowering plant is the diploid sporophyte, while the haploid gametophyte stages are microscopic. The unique feature about the life cycle of flowering plants is a double fertilization that produces a diploid zygote and a triploid endosperm or nutritive tissue.

48. Double fertilization
Pollen grain germinates on stigma forming a pollen tube, which grows down style to the ovary
Pollen has 2 haploid sperm nuclei, which travel to the ovary
One sperm nucleus fertilizes the haploid egg forming the 2n zygote
Another sperm nucleus unites with the 2 polar nuclei, forming the triploid (3n) endosperm

49. Seeds
Fertilized egg grows into a ___________, which grows into plant embryo
Endosperm is stored food tissue – for the embryo to grow
Mature ovule becomes the seed coat and/or fruit

50. Monocot vs. dicot Angiosperms are divided into monocots and dicots
As the zygote grows into the embryo, the first leaves of the young sporophyte develop and are called as cotyledons (seed leaves)
Monocots have one cotyledon (corn, lily, etc).
Dicots have two cotyledons (bean, oak, etc).

51. Comparing monocot vs. dicot plants
FEATURE
MONOCOTS
DICOTS
Cotyledons 1 2
Leaf venation
parallel
broad
Root system
Fibrous
Tap
Number of floral parts
In 3’s
In 4’s or 5’s
Vascular bundle position
Scattered
Arranged in a circle
Woody or herbaceous
Herbaceous
Either

52. Monocot vs. dicot
Number of cotyledons: one vs. two

53. Monocot vs. dicot Leaf venation pattern: Monocot is parallel
Dicot is net pattern

54. Monocot vs. dicot root
Monocot: Fibrous root
Dicot: Tap root

55. copyright cmassengale
Monocot vs. dicot
Flower parts:
Monocot: in groups of three
Dicot: in groups of four or five
copyright cmassengale

56. Monocot vs. dicot Vascular bundle position: Monocot: _____________
Dicot: arranged in a circle

57. Monocot vs. dicot Stem type: Monocot: Herbaceous
Dicot: herbaceous or woody

58. Summary: Monocot vs. dicot

59. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Fig Notice how the importance of the gametophypte dwindles as we move from mosses to ferns to seed plants. The gametophyte of a seed plant is microscopic and not green (does not carry out photosynthesis)

60. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Lots of specialized terms are used to describe the life cycle of see plants. Here, we will use the fewest we can, and simply drastically. Fig
This whole structure is a ovule (integument, the cells of the megasporangium, and the cells of the megaspore). The megaspore is formed by meiosis, so is a haploid gametophyte, the rest is diploid sporophyte.

61. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Lots of specialized terms are used to describe the life cycle of see plants. Here, we will use the fewest we can, and simply drastically. Fig
One of the female gametophyte cells becomes an egg (n). The rest divide to produce the rest of the cells of the female gametophyte. A male gametophyte (n), or pollen grain, enters the ovule, and the nucleus of one of its cells acts like a sperm, and fertilizes the egg (= zygote).

62. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Lots of specialized terms are used to describe the life cycle of see plants. Here, we will use the fewest we can, and simply drastically. Fig
The haploid female gametophyte (minus the cell that became the egg) becomes a mass of tissue that will provide a food supply for the new embryo developing from the zygote. The integument becomes a hard seed coat. Note that the embryo stops developing until it germinates - thus the “baby plant” in a peanut!

63. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
The advantages of seeds are pretty obvious - there is no need for the gametophyte to live in a damp place so sperm can swim to the egg - seed plants can, and do, live everywhere.

64. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Gymnosperms are seed plants that do not have a fruit around the seed, and thus have “naked seeds”. Most of us think of gymnosperms as just “pines” (or conifers), but there is quite a diversity. Ginkos live on campus - have you seen one? The “fruit” is not really a fruit, but part of the ovule..
pine
gingko

65. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Angiosperms do not have naked seeds, but seeds surrounded by a n extra layer of tissue that forms a fruit (which may be juicy or dry). Fig. 30.8, 30.9

66. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
But of course, angiosperms also have flowers! Fig You do not have to memorize all the parts, but know that that most flowers have both male, pollen producing parts, and female ovules.

67. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Almost all angiosperms fall naturally into two groups, monocots (one cotyledon, or seed leaf) and dicots (two cotyledons). A few dicots don’t form a clade, but the huge majoroty that do are called true dicots, or eudicots. Fig (p. 603)

68. Seed plants (Ch.30)
protected gametophytes
advantages of seeds gymnosperms
angiosperms
monocots
eudicots
Fig Angiosperms and animals have evolved very intricate mutualistic interactions involving pollination - interactions that benefit both.

69. Learning goals: Lecture 3, Biological Diversity (Plants and Fungi)
Readings: Chapters 29, 30, and 31 (read all of these, but the parts covered in lecture are most likely to be on a test ).
Land Plants I- how land plants colonized land (Ch. 29)
Land plants evolved from green algae; terrestrial adaptations; alternation of generations; bryophytes dominated by gametophyte generation; ferns dominated by sporophyte
Land plants II - Seed plants (Ch.30)
Tiny gametophytes protected in ovules and pollen; advantages of seeds; Gymnosperms have “naked seeds”; Angiosperms have seeds in fruits; Monocots, Eudicots
Fungi (Ch. 31)
Characteristics; fungi reproduce by spores; fungal origins and relationships; importance

71. Pine Life-Cycle

72. pollen cone
male or pollen cone
Female or ovulate cone
ovulate cone

73. male cone
microsporophyll
microsporangium

74. ovule .mega- sporangium female cone
scale “megasporophyll”

75. seeds
scale

76. Coniferophyta
Yew
Juniper

77. Coniferophyta
Bristlecone Pine

78. Coniferophyta
Giant Redwood or
Sequoia

79. Hemlock
Coniferophyta
Spruce

80. Coniferophyta
Bald Cypress

81. Douglas Fir
Coniferophyta
Fir

82. Cycadophyta: cycads

83. Ginkgophyta: Ginkgo biloba

84. Gnetophyta: Ephedra mormon tea

85. Gnetophyta: Gnetum

86. Gnetophyta: Welwitschia

87. Leaves: Many different sizes, shapes. (Pine needles, cabbage, oak, etc
* Capture sun’s energy for photosynthesis
* Structure of a leaf:
- Upper surface cells
- Chloroplasts
- Veins with xylem and phloem
- Underside surface cells
- Stomata
(“stoma” in Greek means “mouth”, opening)

88. The Structure of a Leaf

89. Cuticle
Upper Epidermis
Palisade mesophyll
Vascular Bundle
Spongy mesophyll
Lower Epidermis

91. VENATION

92. Transpiration = process of evaporation from leaves.
* Too much evaporation and the plant shrivels and dies
* Closing the stomata helps slow down transpiration.

93. Stems: support the plant and carry substances between the roots and leaves.
* Some stems also store food (starches) like in asparagus.
* They vary in size and shape:
- Boabab tree has a huge stems.
- Cabbage have short, hidden stems.

95. * Structure of stems: - Herbaceous (soft) [dandelions,tomato plants]
- Woody (hard) like trees and rose bushes
- Both have xylem and phloem, but woody stems have extra layers:
Outer Bark
Inner Bark (phloem)
Cambium (to produce new phloem and xylem)
Sapwood (active xylem - still transporting)
Heartwood (inactive xylem); just gives strength
Pith (center storing food & water in young trees)

96. Parts of a Woody Stem

97. Annual Rings = xylem rings
* Spring Xylem is wide & light brown (grows rapidly)
* Summer Xylem is thin & darker (grow slower)
* Each pair of light & dark rings = one year’s growth.

99. Roots: (Anchors. Absorbs water & nutrients from soil) * Two Types
1. Taproot = deep into soil
2. Fibrous Roots = several branching main roots
* Root structure
- Root Cap the rounded tip containing dead cells.
- Root hairs increase surface absorption area
- Cambium produces xylem and phloem tissues.
- Xylem transports substances up to the plant
- Phloem brings food down to the growing root

100. Fibrous Roots
Tap Root

101. Root:
Internal
Structure

102. Roots do not absorb water and minerals through a smooth Epidermis
Roots do not absorb water and minerals through a smooth Epidermis.  Tiny, hairlike projections called ROOT HAIRS on the epidermis absorb water and dissolved minerals from the soil.  Root Hairs also INCREASE the Surface Area of the Plant Roots. 

103. Epidermis
Cortex
Pith
Xylem
Phloem
Endodermis
Dicot Root
Monocot Root

104. Gymnosperms Gymnosperm = seed plant that produces naked seeds.
* Many have needlelike or scalelike leaves and deep root systems.
* Note the book says fossils indicate there were many more gymnosperms in the past than today. This is because the global flood 4,000 years ago wiped out many plants.
(The dates given by many books of millions of years are false guesses. See the booklet by Dr. Humphreys.)

105. Types of Gymnosperms: - Cycads (look like palm trees with large cones)
- Ginkgo (only the Ginkgo biloba survives today)
- Gnetophytes (found only in deserts
- Conifers (largest & most common, pines, cedars, etc.)
[Conifers are evergreens: keep needles all year]

106. Oldest living organism – Bristlecone Pine About 4,000 years old = just after Noah’s Flood.

107. Reproduction of Gymnosperms:
* Cones – covered in scales, both male and female cones are produced.
- Pollen is produced by male cones, and pollen are tiny cells that later become sperm cells.
Ovule is a structure containing an egg cell. Pollination = transfer of pollen from male structure to female part.
(Pollen falls from a male cone to a female cone and fertilizes an ovule, which develops into a seed, with the zygote as the embryo part of the seed. It can take two years for seeds to mature, then the cones open & wind carries the seeds off.)

108. The Life Cycle
Of a Gymnosperm

109. Angiosperms Angiosperms – Two characteristics: 1. flowers 2. fruit
(To remember, think: “Angie” likes flowers, but “Gym” does not.)
* They produce seeds inside a fruit.
* Flower = angiosperm reproductive structure
* Fruit starts as an Ovary = where the seeds develop

110. Flower Structure: Not all flowers have same parts
Flower Structure: Not all flowers have same parts. Some have only male parts.
* Sepals = leaf-like structures covering a bud.
* Petals = colorful structures of an open flower.
* Stamens = male parts (stalks topped by knobs)
* Pistils = the female parts in the center of the flower.
- Stigma = sticky tip of the pistil
- Style = tube connecting stigma to ovary.

113. The Structure of a Flower

114. Flower Structure Petal Sepal Ovule Stigma Filament Style Anther Ovary
Receptacle
Petal
Sepal
Ovule

115. Life Cycle
Of an
Angiosperm

116. Reproduction of Angiosperms:
* Pollination = Pollen falls on a stigma when wind, bees, or bats carry it. (Sugar-rich nectar in the flower attracts bees or bats.)
* Fertilization = sperm & egg join together in the flower’s ovule.
- The zygote develops into the embryo part of the seed.
- The ovary around the seed develops into a fruit.
(Apples, cherries, tomatoes, squash, etc. are all fruit.)
* Dispersal – animals eat the fruit and the seeds come out the other end.

117. Two types of Angiosperms:
1. Monocots – have only one seed leaf (cotyledon)
(grasses, corn, wheat, rice, lilies, tulips)
(flowers have either 3 petals or a multiple of 3 petals)
(long slender leaves with veins parallel like train rails)
(vascular tissue scattered randomly in the stem)
2. Dicots – have two cotyledons
(roses, violets, plus oak, maple, bean, and apple trees)
(flowers have 4 or 5 petals or multiples of these numbers)
(leaves are wide, with veins branches off one another)
(vascular tissue bundles arranged in a circle)
Angiosperms are used for food, clothing (cotton), Michael’s medicine (digoxin)

118. Seed Structure Examples:

119. Plant Responses and Growth

120. Tropism = a plant’s growth response toward or away from a stimulus.
* Positive tropism is when it grows toward a stimulus.
* Negative is when it grows away from it.
* Stimuli can be light, touch, and even gravity.
- Touch (thigmotropism) [vines coil around anything they touch.]
- Light (phototropism)
[leaves, stems, etc, grow toward light.]
- Gravity (gravitropism)
(Positive) roots grow toward gravity’s pull
(Negative) stems grow away from its pull

121. Hormones = a chemical that affects how the plant grows and develops, & make tropism possible.
* Hormones also control germination, formation of flowers, stems, and the shedding of leaves and ripening of fruit.
* Auxin is an important hormone that speeds up plant cell growth rate.
- If light shines on one side of a stem, auxin moves to the shaded side and causes that side to grow faster so the stem bends toward the light as it grows.

122. Life Spans of Angiosperms:
* Annuals = complete a life cycle in one year.
(pansies, wheat, tomatoes, cucumbers, etc)
* Biennials = complete life cycle in two years.
(Second year they produce flowers and seeds.)
(Parsley, celery, etc)
* Perennials = live for more than two years (Oak tree, honeysuckles, etc)
(Roots and stems survive the winter)