1. Chapter 30
Reproduction and Domestication of Flowering Plants

2. Overview: Flowers of Deceit
Insects help angiosperms to reproduce sexually with distant members of their own species
For example, male Campsoscolia wasps mistake Ophrys flowers for females and attempt to mate with them
The flower is pollinated in the process
Unusually, the flower does not produce nectar and the male receives no benefit
© 2011 Pearson Education, Inc.
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings

3. Figure 38.1
Figure 38.1 Why is this wasp trying to mate with this flower?

4. Mutualistic symbioses are common between plants and other species
Many angiosperms lure insects with nectar; both plant and pollinator benefit
Mutualistic symbioses are common between plants and other species
Angiosperms can reproduce sexually and asexually
Angiosperms are the most important group of plants in terrestrial ecosystems and in agriculture
© 2011 Pearson Education, Inc.
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings

5. Flowers, double fertilization, and fruits are unique features of the angiosperm life cycle
Plant lifecycles are characterized by the alternation between a multicellular haploid (n) generation and a multicellular diploid (2n) generation
Diploid sporophytes (2n) produce spores (n) by meiosis; these grow into haploid gametophytes (n)
Gametophytes produce haploid gametes (n) by mitosis; fertilization of gametes produces a sporophyte
© 2011 Pearson Education, Inc.

6. In angiosperms, the sporophyte is the dominant generation, the large plant that we see
The gametophytes are reduced in size and depend on the sporophyte for nutrients
The angiosperm life cycle is characterized by “three Fs”: flowers, double fertilization, and fruits
For the Discovery Video Plant Pollination, go to Animation and Video Files.
© 2011 Pearson Education, Inc.

7. Germinated pollen grain (n) (male gametophyte) Stamen Stigma Carpel
Figure 38.2
Anther
Germinated pollen grain (n) (male gametophyte)
Stamen
Stigma
Carpel
Anther
Style
Ovary
Filament
Ovary
Pollen tube
Ovule
Embryo sac (n) (female gametophyte)
Sepal
FERTILIZATION
Petal
Egg (n)
Sperm (n)
Receptacle
Mature sporophyte plant (2n)
Zygote (2n)
(a)
Structure of an idealized flower
Key
Haploid (n)
Seed
Germinating seed
Figure 38.2 An overview of angiosperm reproduction.
Diploid (2n)
Seed
Embryo (2n) (sporophyte)
Simplified angiosperm life cycle
(b)
Simple fruit

8. Structure of an idealized flower
Figure 38.2a
Stamen
Stigma
Carpel
Anther
Style
Filament
Ovary
Sepal
Petal
Figure 38.2 An overview of angiosperm reproduction.
Receptacle
(a)
Structure of an idealized flower

9. Germinated pollen grain (n) (male gametophyte)
Figure 38.2b
Anther
Germinated pollen grain (n) (male gametophyte)
Ovary
Pollen tube
Ovule
Embryo sac (n) (female gametophyte)
FERTILIZATION
Egg (n)
Sperm (n)
Zygote (2n)
Mature sporophyte plant (2n)
Key
Figure 38.2 An overview of angiosperm reproduction.
Seed
Haploid (n)
Germinating seed
Diploid (2n)
Seed
Embryo (2n) (sporophyte)
(b)
Simplified angiosperm life cycle
Simple fruit

10. Flower Structure and Function
Flowers are the reproductive shoots of the angiosperm sporophyte; they attach to a part of the stem called the receptacle
Flowers consist of four floral organs: sepals, petals, stamens, and carpels
Stamens and carpels are reproductive organs; sepals and petals are sterile
© 2011 Pearson Education, Inc.

11. A carpel has a long style with a stigma on which pollen may land
A stamen consists of a filament topped by an anther with pollen sacs that produce pollen
A carpel has a long style with a stigma on which pollen may land
At the base of the style is an ovary containing one or more ovules
A single carpel or group of fused carpels is called a pistil
© 2011 Pearson Education, Inc.

12. Complete flowers contain all four floral organs
Incomplete flowers lack one or more floral organs, for example stamens or carpels
Clusters of flowers are called inflorescences
© 2011 Pearson Education, Inc.

13. Development of Male Gametophytes in Pollen Grains
Pollen develops from microspores within the microsporangia, or pollen sacs, of anthers
Each microspore undergoes mitosis to produce two cells: the generative cell and the tube cell
A pollen grain consists of the two-celled male gametophyte and the spore wall
© 2011 Pearson Education, Inc.

14. If pollination succeeds, a pollen grain produces a pollen tube that grows down into the ovary and discharges two sperm cells near the embryo sac
© 2011 Pearson Education, Inc.

15. Female gametophyte (embryo sac)
Figure 38.3
Development of a male gametophyte (in pollen grain)
(a)
(b)
Development of a female gametophyte (embryo sac)
Microsporangium (pollen sac)
Megasporangium
Microsporocyte
Ovule
Megasporocyte
MEIOSIS
Integuments
Microspores (4)
Micropyle
Surviving megaspore
Each of 4 microspores
MITOSIS
Ovule
Antipodal cells (3)
Male gametophyte (in pollen grain)
Generative cell (will form 2 sperm)
Figure 38.3 The development of male and female gametophytes in angiosperms.
Polar nuclei (2)
Female gametophyte (embryo sac)
Egg (1)
Nucleus of tube cell
Integuments
Synergids (2)
20 m
Ragweed pollen grain (colorized SEM)
Key to labels
Embryo sac
Haploid (n)
75 m
100 m
(LM)
Diploid (2n)
(LM)

16. Development of a male gametophyte (in pollen grain) (a)
Figure 38.3a
Development of a male gametophyte (in pollen grain)
(a)
Microsporangium (pollen sac)
Microsporocyte
MEIOSIS
Microspores (4)
Each of 4 microspores
MITOSIS
Male gametophyte (in pollen grain)
Generative cell (will form 2 sperm)
Figure 38.3 The development of male and female gametophytes in angiosperms.
Nucleus of tube cell
20 m
Key to labels
Ragweed pollen grain (colorized SEM)
Haploid (n)
75 m
(LM)
Diploid (2n)

17. Development of Female Gametophytes (Embryo Sacs)
The embryo sac, or female gametophyte, develops within the ovule
Within an ovule, two integuments surround a megasporangium
One cell in the megasporangium undergoes meiosis, producing four megaspores, only one of which survives
The megaspore divides, producing a large cell with eight nuclei
© 2011 Pearson Education, Inc.

18. This cell is partitioned into a multicellular female gametophyte, the embryo sac
© 2011 Pearson Education, Inc.

19. Female gametophyte (embryo sac)
Figure 38.3b
(b)
Development of a female gametophyte (embryo sac)
Megasporangium
Ovule
Megasporocyte
MEIOSIS
Integuments
Micropyle
Surviving megaspore
MITOSIS
Ovule
Antipodal cells (3)
Figure 38.3 The development of male and female gametophytes in angiosperms.
Polar nuclei (2)
Female gametophyte (embryo sac)
Egg (1)
Integuments
Synergids (2)
Key to labels
Embryo sac
Haploid (n)
100 m
Diploid (2n)
(LM)

20. Pollination
In angiosperms, pollination is the transfer of pollen from an anther to a stigma
Pollination can be by wind, water, or animals
Wind-pollinated species (e.g., grasses and many trees) release large amounts of pollen
© 2011 Pearson Education, Inc.

21. Abiotic Pollination by Wind Pollination by Bees
Figure 38.4a
Abiotic Pollination by Wind
Pollination by Bees
Common dandelion under normal light
Hazel staminate flowers (stamens only)
Figure 38.4 Exploring: Flower Pollination
Hazel carpellate flower (carpels only)
Common dandelion under ultraviolet light

22. Pollination by Moths and Butterflies Pollination by Flies
Figure 38.4b
Pollination by Moths and Butterflies
Pollination by Flies
Pollination by Bats
Anther
Moth
Fly egg
Stigma
Blowfly on carrion flower
Long-nosed bat feeding on cactus flower at night
Moth on yucca flower
Pollination by Birds
Figure 38.4 Exploring: Flower Pollination
Hummingbird drinking nectar of columbine flower

23. Coevolution of Flower and Pollinator
Coevolution is the evolution of interacting species in response to changes in each other
Many flowering plants have coevolved with specific pollinators
The shapes and sizes of flowers often correspond to the pollen transporting parts of their animal pollinators
For example, Darwin correctly predicted a moth with a 28 cm long tongue based on the morphology of a particular flower
© 2011 Pearson Education, Inc.

24. Figure 38.5
Figure 38.5 Coevolution of a flower and an insect pollinator.

25. Double Fertilization
After landing on a receptive stigma, a pollen grain produces a pollen tube that extends between the cells of the style toward the ovary
Double fertilization results from the discharge of two sperm from the pollen tube into the embryo sac
One sperm fertilizes the egg, and the other combines with the polar nuclei, giving rise to the triploid food-storing endosperm (3n)
© 2011 Pearson Education, Inc.

26. 1 Pollen grain Stigma Pollen tube 2 sperm Style Ovary Ovule
Figure 1
Pollen grain
Stigma
Pollen tube
2 sperm
Style
Ovary
Ovule
Polar nuclei
Figure 38.6 Growth of the pollen tube and double fertilization.
Egg
Micropyle

27. 1 2 Pollen grain Stigma Pollen tube Ovule Polar nuclei 2 sperm Style
Figure 1 2
Pollen grain
Stigma
Pollen tube
Ovule
Polar nuclei
2 sperm
Style
Egg
Ovary
Ovule
Synergid
Polar nuclei
Figure 38.6 Growth of the pollen tube and double fertilization.
2 sperm
Egg
Micropyle

28. Endosperm nucleus (3n) (2 polar nuclei plus sperm)
Figure 1 2 3
Pollen grain
Stigma
Endosperm nucleus (3n) (2 polar nuclei plus sperm)
Pollen tube
Ovule
Polar nuclei
2 sperm
Style
Egg
Ovary
Zygote (2n)
Ovule
Synergid
Polar nuclei
Figure 38.6 Growth of the pollen tube and double fertilization.
2 sperm
Egg
Micropyle

29. Seed Development, Form, and Function
After double fertilization, each ovule develops into a seed
The ovary develops into a fruit enclosing the seed(s)
© 2011 Pearson Education, Inc.

30. Endosperm Development
Endosperm development usually precedes embryo development
In most monocots and some eudicots, endosperm stores nutrients that can be used by the seedling
In other eudicots, the food reserves of the endosperm are exported to the cotyledons
© 2011 Pearson Education, Inc.

31. Embryo Development
The first mitotic division of the zygote splits the fertilized egg into a basal cell and a terminal cell
The basal cell produces a multicellular suspensor, which anchors the embryo to the parent plant
The terminal cell gives rise to most of the embryo
The cotyledons form and the embryo elongates
© 2011 Pearson Education, Inc.

32. Ovule Proembryo Endosperm nucleus Suspensor Integuments Cotyledons
Figure 38.7
Ovule
Proembryo
Endosperm nucleus
Suspensor
Integuments
Cotyledons
Zygote
Basal cell
Shoot apex
Root apex
Seed coat
Suspensor
Terminal cell
Figure 38.7 The development of a eudicot plant embryo.
Basal cell
Endosperm
Zygote

33. Ovule Endosperm nucleus Integuments Zygote Terminal cell Basal cell
Figure 38.7a
Ovule
Endosperm nucleus
Integuments
Zygote
Figure 38.7 The development of a eudicot plant embryo.
Terminal cell
Basal cell
Zygote

34. Proembryo Suspensor Cotyledons Basal cell Shoot apex Root apex
Figure 38.7b
Proembryo
Suspensor
Cotyledons
Basal cell
Shoot apex
Root apex
Seed coat
Suspensor
Figure 38.7 The development of a eudicot plant embryo.
Endosperm

35. Structure of the Mature Seed
The embryo and its food supply are enclosed by a hard, protective seed coat
The seed enters a state of dormancy
A mature seed is only about 5–15% water
© 2011 Pearson Education, Inc.

36. In some eudicots, such as the common garden bean, the embryo consists of the embryonic axis attached to two thick cotyledons (seed leaves)
Below the cotyledons the embryonic axis is called the hypocotyl and terminates in the radicle (embryonic root); above the cotyledons it is called the epicotyl
The plumule comprises the epicotyl, young leaves, and shoot apical meristem
© 2011 Pearson Education, Inc.

37. (a) Common garden bean, a eudicot with thick cotyledons
Figure 38.8
Seed coat
Epicotyl
Hypocotyl
Radicle
Cotyledons
(a) Common garden bean, a eudicot with thick cotyledons
Seed coat
Endosperm
Cotyledons
Epicotyl
Hypocotyl
Radicle
(b) Castor bean, a eudicot with thin cotyledons
Figure 38.8 Seed structure.
Scutellum (cotyledon)
Pericarp fused with seed coat
Endosperm
Coleoptile
Epicotyl
Hypocotyl
Coleorhiza
Radicle
(c) Maize, a monocot

38. (a) Common garden bean, a eudicot with thick cotyledons
Figure 38.8a
Seed coat
Epicotyl
Hypocotyl
Radicle
Cotyledons
Figure 38.8 Seed structure.
(a) Common garden bean, a eudicot with thick cotyledons

39. The seeds of some eudicots, such as castor beans, have thin cotyledons
© 2011 Pearson Education, Inc.

40. (b) Castor bean, a eudicot with thin cotyledons
Figure 38.8b
Seed coat
Endosperm
Cotyledons
Epicotyl
Hypocotyl
Radicle
Figure 38.8 Seed structure.
(b) Castor bean, a eudicot with thin cotyledons

41. A monocot embryo has one cotyledon
Grasses, such as maize and wheat, have a special cotyledon called a scutellum
Two sheathes enclose the embryo of a grass seed: a coleoptile covering the young shoot and a coleorhiza covering the young root
© 2011 Pearson Education, Inc.

42. Scutellum (cotyledon) Pericarp fused with seed coat
Figure 38.8c
Scutellum (cotyledon)
Pericarp fused with seed coat
Endosperm
Coleoptile
Epicotyl
Hypocotyl
Coleorhiza
Radicle
Figure 38.8 Seed structure.
(c) Maize, a monocot

43. Seed Dormancy: An Adaptation for Tough Times
Seed dormancy increases the chances that germination will occur at a time and place most advantageous to the seedling
The breaking of seed dormancy often requires environmental cues, such as temperature or lighting changes
© 2011 Pearson Education, Inc.

44. Seed Germination and Seedling Development
Germination depends on imbibition, the uptake of water due to low water potential of the dry seed
The radicle (embryonic root) emerges first
Next, the shoot tip breaks through the soil surface
© 2011 Pearson Education, Inc.

45. In many eudicots, a hook forms in the hypocotyl, and growth pushes the hook above ground
Light causes the hook to straighten and pull the cotyledons and shoot tip up
© 2011 Pearson Education, Inc.

46. Foliage leaves Cotyledon Epicotyl Hypocotyl Cotyledon Cotyledon
Figure 38.9
Foliage leaves
Cotyledon
Epicotyl
Hypocotyl
Cotyledon
Cotyledon
Hypocotyl
Hypocotyl
Radicle
Seed coat
(a) Common garden bean
Foliage leaves
Figure 38.9 Two common types of seed germination.
Coleoptile
Coleoptile
Radicle
(b) Maize

47. Foliage leaves Cotyledon Epicotyl Hypocotyl Cotyledon Cotyledon
Figure 38.9a
Foliage leaves
Cotyledon
Epicotyl
Hypocotyl
Cotyledon
Cotyledon
Hypocotyl
Hypocotyl
Figure 38.9 Two common types of seed germination.
Radicle
Seed coat
(a) Common garden bean

48. In maize and other grasses, which are monocots, the coleoptile pushes up through the soil
© 2011 Pearson Education, Inc.

49. Foliage leaves Coleoptile Coleoptile Radicle (b) Maize Figure 38.9b
Figure 38.9 Two common types of seed germination.
Radicle
(b) Maize

50. Fruit Form and Function
A fruit develops from the ovary
It protects the enclosed seeds and aids in seed dispersal by wind or animals
A fruit may be classified as dry, if the ovary dries out at maturity, or fleshy, if the ovary becomes thick, soft, and sweet at maturity
© 2011 Pearson Education, Inc.

51. Fruits are also classified by their development
Simple, a single or several fused carpels
Aggregate, a single flower with multiple separate carpels
Multiple, a group of flowers called an inflorescence
© 2011 Pearson Education, Inc.

52. Pineapple inflorescence
Figure 38.10
Stigma
Style
Carpels
Stamen
Flower
Petal
Ovary
Stamen
Stamen
Sepal
Stigma
Ovary (in receptacle)
Ovule
Ovule
Pea flower
Raspberry flower
Pineapple inflorescence
Apple flower
Each segment develops from the carpel of one flower
Remains of stamens and styles
Carpel (fruitlet)
Stigma
Sepals
Seed
Ovary
Figure Developmental origin of fruits.
Stamen
Seed
Receptacle
Pea fruit
Raspberry fruit
Pineapple fruit
Apple fruit
(a) Simple fruit
(b) Aggregate fruit
(c) Multiple fruit
(d) Accessory fruit

53. Carpels Stamen Ovary Stamen Stigma Ovule Pea flower Raspberry flower
Figure 38.10a
Carpels
Stamen
Ovary
Stamen
Stigma
Ovule
Pea flower
Raspberry flower
Carpel (fruitlet)
Stigma
Seed
Ovary
Figure Developmental origin of fruits.
Stamen
Pea fruit
Raspberry fruit
(a) Simple fruit
(b) Aggregate fruit

54. Pineapple inflorescence
Figure 38.10b
Stigma
Style
Flower
Petal
Stamen
Sepal
Ovary (in receptacle)
Ovule
Pineapple inflorescence
Apple flower
Remains of stamens and styles
Each segment develops from the carpel of one flower
Sepals
Figure Developmental origin of fruits.
Seed
Receptacle
Pineapple fruit
Apple fruit
(c) Multiple fruit
(d) Accessory fruit

55. An accessory fruit contains other floral parts in addition to ovaries
© 2011 Pearson Education, Inc.

56. Fruit dispersal mechanisms include
Water
Wind
Animals
© 2011 Pearson Education, Inc.

57. Dispersal by Wind Dispersal by Water Dandelion fruit Tumbleweed
Figure 38.11a
Dispersal by Wind
Dandelion fruit
Tumbleweed
Dandelion “seeds” (actually one-seeded fruits)
Winged seed of the tropical Asian climbing gourd Alsomitra macrocarpa
Winged fruit of a maple
Dispersal by Water
Figure Exploring: Fruit and Seed Dispersal
Coconut seed embryo, endosperm, and endocarp inside buoyant husk

58. Dispersal by Animals Fruit of puncture vine (Tribulus terrestris)
Figure 38.11b
Dispersal by Animals
Fruit of puncture vine (Tribulus terrestris)
Squirrel hoarding seeds or fruits underground
Ant carrying seed with nutritious “food body” to its nest
Figure Exploring: Fruit and Seed Dispersal
Seeds dispersed in black bear feces

59. Flowering plants reproduce sexually, asexually, or both
Many angiosperm species reproduce both asexually and sexually
Sexual reproduction results in offspring that are genetically different from their parents
Asexual reproduction results in a clone of genetically identical organisms
© 2011 Pearson Education, Inc.

60. Mechanisms of Asexual Reproduction
Fragmentation, separation of a parent plant into parts that develop into whole plants, is a very common type of asexual reproduction
In some species, a parent plant’s root system gives rise to adventitious shoots that become separate shoot systems
© 2011 Pearson Education, Inc.

61. Figure 38.12
Figure Asexual reproduction in aspen trees.

62. Apomixis is the asexual production of seeds from a diploid cell
© 2011 Pearson Education, Inc.

63. Advantages and Disadvantages of Asexual Versus Sexual Reproduction
Asexual reproduction is also called vegetative reproduction
Asexual reproduction can be beneficial to a successful plant in a stable environment
However, a clone of plants is vulnerable to local extinction if there is an environmental change
© 2011 Pearson Education, Inc.

64. However, only a fraction of seedlings survive
Sexual reproduction generates genetic variation that makes evolutionary adaptation possible
However, only a fraction of seedlings survive
Some flowers can self-fertilize to ensure that every ovule will develop into a seed
Many species have evolved mechanisms to prevent selfing
© 2011 Pearson Education, Inc.

65. Mechanisms That Prevent Self-Fertilization
Many angiosperms have mechanisms that make it difficult or impossible for a flower to self-fertilize
Dioecious species have staminate and carpellate flowers on separate plants
© 2011 Pearson Education, Inc.

66. Staminate flowers (left) and carpellate flowers (right)
Figure 38.13
Staminate flowers (left) and carpellate flowers (right)
of a dioecious species
(a)
Figure Some floral adaptations that prevent self-fertilization.
Stamens
Styles
Styles
Stamens
Thrum flower
Pin flower
(b) Thrum and pin flowers

67. Others have stamens and carpels that mature at different times or are arranged to prevent selfing
© 2011 Pearson Education, Inc.

68. The most common is self-incompatibility, a plant’s ability to reject its own pollen
Researchers are unraveling the molecular mechanisms involved in self-incompatibility
Some plants reject pollen that has an S-gene matching an allele in the stigma cells
Recognition of self pollen triggers a signal transduction pathway leading to a block in growth of a pollen tube
© 2011 Pearson Education, Inc.

69. Vegetative Propagation and Agriculture
Humans have devised methods for asexual propagation of angiosperms
Most methods are based on the ability of plants to form adventitious roots or shoots
© 2011 Pearson Education, Inc.

70. Clones from Cuttings
Many kinds of plants are asexually reproduced from plant fragments called cuttings
A callus is a mass of dividing undifferentiated cells that forms where a stem is cut and produces adventitious roots
© 2011 Pearson Education, Inc.
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings

71. Grafting
A twig or bud can be grafted onto a plant of a closely related species or variety
The stock provides the root system
The scion is grafted onto the stock
© 2011 Pearson Education, Inc.

72. Test-Tube Cloning and Related Techniques
Plant biologists have adopted in vitro methods to create and clone novel plant varieties
A callus of undifferentiated cells can sprout shoots and roots in response to plant hormones
© 2011 Pearson Education, Inc.

73. (a) (b) (c) Developing root Figure 38.14
Figure Cloning a garlic plant.
(a)
(b)
(c)
Developing root

74. Transgenic plants are genetically modified (GM) to express a gene from another organism
Protoplast fusion is used to create hybrid plants by fusing protoplasts, plant cells with their cell walls removed
© 2011 Pearson Education, Inc.

75. Figure 38.15
Figure Protoplasts.
50 m

76. Humans modify crops by breeding and genetic engineering
Humans have intervened in the reproduction and genetic makeup of plants for thousands of years
Hybridization is common in nature and has been used by breeders to introduce new genes
Maize, a product of artificial selection, is a staple in many developing countries
© 2011 Pearson Education, Inc.

77. Figure 38.16
Figure Maize: a product of artificial selection.

78. Plant Breeding
Mutations can arise spontaneously or can be induced by breeders
Plants with beneficial mutations are used in breeding experiments
Desirable traits can be introduced from different species or genera
The grain triticale is derived from a successful cross between wheat and rye
© 2011 Pearson Education, Inc.

79. Plant Biotechnology and Genetic Engineering
Plant biotechnology has two meanings
In a general sense, it refers to innovations in the use of plants to make useful products
In a specific sense, it refers to use of GM organisms in agriculture and industry
Modern plant biotechnology is not limited to transfer of genes between closely related species or varieties of the same species
© 2011 Pearson Education, Inc.

80. Reducing World Hunger and Malnutrition
Genetically modified plants may increase the quality and quantity of food worldwide
Transgenic crops have been developed that
Produce proteins to defend them against insect pests
Tolerate herbicides
Resist specific diseases
© 2011 Pearson Education, Inc.

81. Nutritional quality of plants is being improved
For example, “Golden Rice” is a transgenic variety being developed to address vitamin A deficiencies among the world’s poor
© 2011 Pearson Education, Inc.

82. Cassava roots harvested in Thailand
Figure 38.17
Figure Impact: Fighting World Hunger with Transgenic Cassava
Cassava roots harvested in Thailand

83. Reducing Fossil Fuel Dependency
Biofuels are made by the fermentation and distillation of plant materials such as cellulose
Biofuels can be produced by rapidly growing crops such as switchgrass and poplar
Biofuels would reduce the net emission of CO2, a greenhouse gas
The environmental implications of biofuels are controversial
© 2011 Pearson Education, Inc.

84. The Debate over Plant Biotechnology
Some biologists are concerned about risks of releasing GM organisms (GMOs) into the environment
© 2011 Pearson Education, Inc.

85. Issues of Human Health
One concern is that genetic engineering may transfer allergens from a gene source to a plant used for food
Some GMOs have health benefits
For example, maize that produces the Bt toxin has 90% less of a cancer-causing toxin than non-Bt corn
Bt maize has less insect damage and lower infection by Fusarium fungus that produces the cancer-causing toxin
© 2011 Pearson Education, Inc.

86. GMO opponents advocate for clear labeling of all GMO foods
© 2011 Pearson Education, Inc.

87. Possible Effects on Nontarget Organisms
Many ecologists are concerned that the growing of GM crops might have unforeseen effects on nontarget organisms
© 2011 Pearson Education, Inc.

88. Addressing the Problem of Transgene Escape
Perhaps the most serious concern is the possibility of introduced genes escaping into related weeds through crop-to-weed hybridization
This could result in “superweeds” that would be resistant to many herbicides
© 2011 Pearson Education, Inc.

89. Efforts are underway to prevent this by introducing
Male sterility
Apomixis
Transgenes into chloroplast DNA (not transferred by pollen)
Strict self-pollination
© 2011 Pearson Education, Inc.
© 2011 Pearson Education, Inc.