1. AIM:
How can natural selection be
observed?
Warm – up:
Describe one piece of evidence that
supports evolution

2. Selection Pressures
• What type of environmental resistances
exist to keep populations stable?

3. Selection:
Advantages & Disadvantages

4. Selection:
Advantages & Disadvantages
• Organisms with characteristics that aid in
their survival have a selective advantage
and therefore have high natality

5. Selection:
Advantages & Disadvantages
• Organisms with characteristics that aid in
their survival have a selective advantage
and therefore have high natality
• Organisms with unfavorable
characteristics are at a selective
disadvantage and therefore have high
mortality

6. Fitness Body size & egg laying in water striders
• Ability of an organism to
pass on its alleles to
subsequent generations,
compared with individuals of
the same species

7. Fitness Body size & egg laying in water striders
• Ability of an organism to
pass on its alleles to
subsequent generations,
compared with individuals of
the same species

8. Fitness Body size & egg laying in water striders
• Ability of an organism to
pass on its alleles to
subsequent generations,
compared with individuals of
the same species

9. Fitness Body size & egg laying in water striders
• Ability of an organism to
pass on its alleles to
subsequent generations,
compared with individuals of
the same species

10. Types of Natural Selection

11. Types of Natural Selection
• The frequency of an allele in a population
typically has a normal distribution

12. Types of Natural Selection
• The frequency of an allele in a population
typically has a normal distribution
• Natural selection affects a gene pool (all the
alleles and genes in a population) by increasing
the frequency of advantageous alleles and
decreasing the frequency of disadvantageous
alleles.

13. Stabilizing Selection
In an unchanging environment, the extreme variations are
selected against and the intermediate characteristics have a
selective advantage.

14. Directional Selection
Favors one extreme of the phenotype and results in a shift
of the mean phenotype. Generally follows some type of
environmental change.

15. Directional Selection
Favors one extreme of the phenotype and results in a shift
of the mean phenotype. Generally follows some type of
environmental change.

16. Disruptive Selection
Favors the extreme phenotypes and selects against
intermediates. Leads to a bimodal distribution.
What happens if the two groups are unable to interbreed?

17. Individuals DON’T evolve…

18. Individuals DON’Tdon’t survive…
Individuals survive or evolve…

19. Individuals are selected

20. Individuals are selected
Populations evolve

21. Variation & natural selection

22. Variation & natural selection
• Variation is the raw material for natural
selection

23. Variation & natural selection
• Variation is the raw material for natural
selection
– there have to be differences within population

24. Variation & natural selection
• Variation is the raw material for natural
selection
– there have to be differences within population
– some individuals must be more fit than others

25. Where does Variation come
from? Wet year
Beak depth
Dry year
Dry year Dry year
1977 1980 1982 1984
11
offspring (mm)
Beak depth of
10
9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

26. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
1977 1980 1982 1984
11
offspring (mm)
Beak depth of
10
9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

27. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
11
offspring (mm)
Beak depth of
10
9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

28. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
offspring (mm)
Beak depth of
10
9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

29. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

30. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
Medium ground finch
8
8 9 10 11
Mean beak depth of parents (mm)

31. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
Mean beak depth of parents (mm)

32. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
• recombination of alleles Mean beak depth of parents (mm)

33. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
• recombination of alleles Mean beak depth of parents (mm)
– new arrangements in every offspring

34. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
• recombination of alleles Mean beak depth of parents (mm)
– new arrangements in every offspring
• new combinations = new phenotypes

35. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
• recombination of alleles Mean beak depth of parents (mm)
– new arrangements in every offspring
• new combinations = new phenotypes
– spreads variation

36. Where does Variation come
from? Wet year
Beak depth
• Mutation Dry year
Dry year
Dry year
– random changes to DNA 1977 1980 1982 1984
• errors in mitosis & meiosis 11
• environmental damage
offspring (mm)
Beak depth of
10
• Sex 9
– mixing of alleles 8
Medium ground finch
8 9 10 11
• recombination of alleles Mean beak depth of parents (mm)
– new arrangements in every offspring
• new combinations = new phenotypes
– spreads variation
• offspring inherit traits from parent

37. Mutation & Variation

38. Mutation & Variation

39. Mutation & Variation
• Mutation creates variation

40. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing

41. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence

42. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence
– changes amino acid sequence?

43. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence
– changes amino acid sequence?
– changes protein?

44. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence
– changes amino acid sequence?
– changes protein?
• changes structure?

45. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence
– changes amino acid sequence?
– changes protein?
• changes structure?
• changes function?

46. Mutation & Variation
• Mutation creates variation
– new mutations are constantly appearing
• Mutation changes DNA sequence
– changes amino acid sequence?
– changes protein?
• changes structure?
• changes function?
– changes in protein may
change phenotype &
therefore change fitness

47. Antibiotic Resistance

48. Antibiotic Resistance

49. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.

50. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.

51. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.
Process:

52. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.
Process:
- A mutation produces an individual bacterium
with an allele that allows it to produce an
enzyme that deactivates the enzyme or that
reduces the number of target receptors on the
membrane.

53. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.
Process:
- A mutation produces an individual bacterium
with an allele that allows it to produce an
enzyme that deactivates the enzyme or that
reduces the number of target receptors on the
membrane.
- The bacteria becomes resistant and therefore
will survive and reproduce other antibiotic
resistant bacteria.

54. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.
Process:
- A mutation produces an individual bacterium
with an allele that allows it to produce an
enzyme that deactivates the enzyme or that
reduces the number of target receptors on the
membrane.
- The bacteria becomes resistant and therefore
will survive and reproduce other antibiotic
resistant bacteria.
- The antibiotic applies a selection pressure

55. Antibiotic Resistance
• Due to overuse of antibiotics, many strains of
bacteria have developed resistance to them.
Process:
- A mutation produces an individual bacterium
with an allele that allows it to produce an
enzyme that deactivates the enzyme or that
reduces the number of target receptors on the
membrane.
- The bacteria becomes resistant and therefore
will survive and reproduce other antibiotic
resistant bacteria.
- The antibiotic applies a selection pressure

56. DDT Resistance in Anopheline
Mosquitoes

57. The malarial parasite is spread by
anopheline mosquitoes

58. The malarial parasite is spread by
anopheline mosquitoes
The spread of malaria can
be controlled by
controlling mosquito
numbers

59. The malarial parasite is spread by
anopheline mosquitoes
The spread of malaria can
be controlled by
controlling mosquito
numbers
One way of controlling
mosquito numbers is to use
an insecticide like DDT
DDT

60. Not every mosquito will be killed each time
we spray

61. Not every mosquito will be killed each time
we spray

62. Not every mosquito will be killed each time
we spray
Some will survive to repopulate the area, so…

63. Not every mosquito will be killed each time
we spray
Some will survive to repopulate the area, so…
…we must spray frequently.

64. Random mutation may produce mosquitoes which are
resistant to the effects of DDT…

65. Random mutation may produce mosquitoes which are
resistant to the effects of DDT…

66. Random mutation may produce mosquitoes which are
resistant to the effects of DDT…
…these are more likely to survive and pass on their
genes to the next generation

67. NOTE

68. NOTE
A resistant mosquito does not
need to be totally resistant to
the effects of DDT…

69. NOTE
A resistant mosquito does not
need to be totally resistant to
the effects of DDT…
… it may just be able to
survive higher does of
DDT than ‘normal’
mosquitoes.

70. The next generation contains more resistant
mosquitoes

71. The next generation contains more resistant
mosquitoes

72. The next generation contains more resistant
mosquitoes
Again, they are more likely to survive to reproduce, so…

73. The next generation contains more resistant
mosquitoes
Again, they are more likely to survive to reproduce, so…
…the proportion of the population which is resistant to
DDT increases

74. With each successive generation…

75. With each successive generation…
…the proportion of the mosquito population which is
resistant to DDT increases.

76. Eventually…

77. Eventually…
…the whole population may consist of
resistant mosquitoes

79. Spraying with DDT produces the
selective pressure which favours
the resistant mosquitoes.

80. Spraying with DDT produces the
selective pressure which favours
the resistant mosquitoes.
Because they can resist the effects of DDT,
the resistant mosquitoes are said to have a
selective advantage

81. It may not be able to increase the
dose of DDT used:

82. It may not be able to increase the
dose of DDT used:
- higher doses may be dangerous
to humans

83. It may not be able to increase the
dose of DDT used:
- higher doses may be dangerous
to humans
- higher doses may be too
damaging to other wildlife

84. It may not be able to increase the
dose of DDT used:
- higher doses may be dangerous
to humans
- higher doses may be too
damaging to other wildlife
Using higher doses of DDT will
also produce the selective
pressure which will favour
mosquitoes with even higher
levels of resistance

85. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed

86. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed

87. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed

88. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed

89. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed
Year % dark % light

90. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed
Year % dark % light
1848 5 95

91. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed
Year % dark % light
1848 5 95
1895 98 2

92. Peppered Moths
• Dark vs. light variants
• Polymorphism: two or more adult body forms contained
within a single species and can interbreed
Year % dark % light
1848 5 95
1895 98 2
1995 19 81

93. Peppered Moths

94. Peppered Moths
• What was the selection factor?

95. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England

96. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution

97. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution

98. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark

99. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England

100. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees

101. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees
• killed lichen = dark colored bark

102. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees
• killed lichen = dark colored bark
– mid 1900s = pollution controls

103. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees
• killed lichen = dark colored bark
– mid 1900s = pollution controls
• clean air laws

104. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees
• killed lichen = dark colored bark
– mid 1900s = pollution controls
• clean air laws
• return of lichen = light colored bark

105. Peppered Moths
• What was the selection factor?
– early 1800s = pre-industrial England
• low pollution
• lichen growing on trees = light colored bark
– late 1800s = industrial England
• factories = soot coated trees
• killed lichen = dark colored bark
– mid 1900s = pollution controls
• clean air laws
• return of lichen = light colored bark
– industrial melanism