1. Broad Patterns of Evolution
Unit 4.5
Broad Patterns of Evolution 1

2. Overview: Lost Worlds
Past organisms were very different from those now alive
The fossil record shows evidence of macroevolution, broad changes above the species level; for example
The emergence of terrestrial vertebrates
The impact of mass extinctions
The origin of flight in birds 2

3. Figure 23.1
Figure 23.1 On what continent did these dinosaurs roam? 3

4. Cryolophosaurus skull
Figure 23.UN01
Figure 23.UN01 In-text figure, Cryolophosaurus skull, p. 436
Cryolophosaurus skull 4

5. Concept 23.1: The fossil record documents life’s history
The fossil record reveals changes in the history of life on Earth 5

6. 6 100 mya Rhomaleosaurus victor 175 200 Dimetrodon 270 Tiktaalik 300
Figure 23.2
1 m
100
mya
Rhomaleosaurus
victor
175
0.5 m
200
Dimetrodon
270
Tiktaalik
300
4.5 cm
Coccosteus cuspidatus
375
400
1 cm
Hallucigenia
Figure 23.2 Documenting the history of life
500
510
2.5 cm
Dickinsonia
costata
560
Stromatolites
600
1,500
3,500
Tappania 6

7. The Fossil Record
Sedimentary rocks are deposited into layers called strata and are the richest source of fossils
The fossil record indicates that there have been great changes in the kinds of organisms on Earth at different points in time 7

8. Few individuals have fossilized, and even fewer have been discovered
The fossil record is biased in favor of species that
Existed for a long time
Were abundant and widespread
Had hard parts 8

9. How Rocks and Fossils Are Dated
Sedimentary strata reveal the relative ages of fossils
The absolute ages of fossils can be determined by radiometric dating
A “parent” isotope decays to a “daughter” isotope at a constant rate
Each isotope has a known half-life, the time required for half the parent isotope to decay 9

10. ½ ¼ ⅛ 10 Accumulating “daughter” isotope Fraction of parent
Figure 23.3
Accumulating
“daughter”
isotope
Fraction of parent
isotope remaining
Figure 23.3 Radiometric dating
Remaining
“parent”
isotope ⅛ 1 16 1 2 3 4
Time (half-lives) 10

11. Radiocarbon dating can be used to date fossils up to 75,000 years old
For older fossils, some isotopes can be used to date volcanic rock layers above and below the fossil 11

12. The Geologic Record
The geologic record is a standard time scale dividing Earth’s history into the Hadean, Archaean, Proterozoic, and Phanerozoic eons
The Phanerozoic encompasses most of the time that animals have existed on Earth
The Phanerozoic is divided into three eras: the Paleozoic, Mesozoic, and Cenozoic
Major boundaries between geological divisions correspond to extinction events in the fossil record 12

13. Table 23.1
Table 23.1 The geologic record 13

14. Table 23.1a
Table 23.1a The geologic record (part 1: Hadean eon through Paleozoic era) 14

15. Table 23.1b
Table 23.1b The geologic record (part 2: Mesozoic era and Cenozoic era) 15

16. Stromatolites date back 3.5 billion years ago
The oldest known fossils are stromatolites, rocks formed by the accumulation of sedimentary layers on bacterial mats
Stromatolites date back 3.5 billion years ago
Prokaryotes were Earth’s sole inhabitants for more than 1.5 billion years 16

17. Early prokaryotes released oxygen into the atmosphere through the process of photosynthesis
The increase in atmospheric oxygen that began 2.4 billion years ago led to the extinction of many organisms
The eukaryotes flourished in the oxygen-rich atmosphere and gave rise to multicellular organisms 17

18. The Origin of New Groups of Organisms
Mammals belong to the group of animals called tetrapods
The evolution of unique mammalian features can be traced through gradual changes over time 18

19. 19 †Dimetrodon †Very late (non- mammalian) cynodonts
Figure 23.4
Reptiles
(including
dinosaurs and birds)
Key to skull bones
Articular
Dentary
OTHER
TETRA-
PODS
Quadrate
Squamosal
†Dimetrodon
Early cynodont (260 mya)
Synapsids
†Very late (non- mammalian) cynodonts
Temporal
fenestra
(partial view)
Therapsids
Cynodonts
Mammals
Hinge
Synapsid (300 mya)
Later cynodont (220 mya)
Temporal
fenestra
Hinge
Figure 23.4 Exploring the origin of mammals
Original hinge
New hinge
Therapsid (280 mya)
Very late cynodont (195 mya)
Temporal
fenestra
Hinge
Hinge 19

20. Synapsids (300 mya) had single-pointed teeth, large temporal fenestra, and a jaw hinge between the articular and quadrate bones 20

21. Therapsids (280 mya) had large dentary bones, long faces, and specialized teeth, including large canines 21

22. 22 Synapsid (300 mya) Therapsid (280 mya) Key to skull bones Articular
Figure 23.4b
Synapsid (300 mya)
Key to skull bones
Articular
Quadrate
Dentary
Temporal
fenestra
Squamosal
Hinge
Therapsid (280 mya)
Figure 23.4b Exploring the origin of mammals (part 2: synapsids and therapsids)
Temporal
fenestra
Hinge 22

23. Early cynodonts (260 mya) had large dentary bones in the lower jaw, large temporal fenestra in front of the jaw hinge, and teeth with several cusps 23

24. Later cynodonts (220 mya) had teeth with complex cusp patterns and an additional jaw hinge between the dentary and squamosal bones 24

25. Very late cynodonts (195 mya) lost the original articular-quadrate jaw hinge
The articular and quadrate bones formed inner ear bones that functioned in transmitting sound
In mammals, these bones became the hammer (malleus) and anvil (incus) bones of the ear 25

26. 26 Early cynodont (260 mya) Later cynodont (220 mya)
Figure 23.4c
Early cynodont (260 mya)
Key to skull bones
Articular
Temporal
fenestra
(partial view)
Quadrate
Dentary
Squamosal
Hinge
Later cynodont (220 mya)
Original hinge
Figure 23.4c Exploring the origin of mammals (part 3: cynodonts)
New hinge
Very late cynodont (195 mya)
Hinge 26

27. Concept 23.2: The rise and fall of groups of organisms reflect differences in speciation and extinction rates
The history of life on Earth has seen the rise and fall of many groups of organisms
The rise and fall of groups depend on speciation and extinction rates within the group 27

28. 28 † † Lineage A † † † Common ancestor of lineages A and B Lineage B †
Figure 23.5 † †
Lineage A † † †
Common
ancestor of
lineages A
and B
Lineage B †
Figure 23.5 How speciation and extinction affect diversity 4 3 2 1
Millions of years ago 28

29. Plate Tectonics
At three points in time, the landmasses of Earth have formed a supercontinent: 1.1 billion, 600 million, and 250 million years ago
According to the theory of plate tectonics, Earth’s crust is composed of plates floating on Earth’s mantle
Tectonic plates move slowly through the process of continental drift
Oceanic and continental plates can separate, slide past each other, or collide
Interactions between plates cause the formation of mountains and islands and earthquakes 29

30. 30 North American Plate Eurasian Plate Juan de Fuca Plate Caribbean
Figure 23.7
North
American
Plate
Eurasian Plate
Juan
de Fuca
Plate
Caribbean
Plate
Philippine
Plate
Arabian
Plate
Indian
Plate
Cocos Plate
South
American
Plate
Pacific
Plate
Nazca
Plate
African
Plate
Australian
Plate
Figure 23.7 Earth’s major tectonic plates
Scotia
Plate
Antarctic
Plate 30

31. Consequences of Continental Drift
Formation of the supercontinent Pangaea about 250 million years ago had many effects
A deepening of ocean basins
A reduction in shallow water habitat
A colder and drier climate inland 31

32. Figure 23.8
Present
Collision of
India with
Eurasia
45 mya
Cenozoic
North America
Eurasia
Present-day
continents
65.5 mya
Africa
South
America
India
Madagascar
Australia
Antarctica
Laurasia
Laurasia and
Gondwana
landmasses
135 mya
Mesozoic
Gondwana
Figure 23.8 The history of continental drift during the Phanerozoic eon
The supercontinent
Pangaea
251 mya
Pangaea
Paleozoic 32

33. Separation of landmasses can lead to allopatric speciation
Continental drift can cause a continent’s climate to change as it moves north or south
Separation of landmasses can lead to allopatric speciation
For example, frog species in the subfamilies Mantellinae and Rhacophorinae began to diverge when Madagascar separated from India 33

34. 34 Mantellinae (Madagascar only): 100 species Rhacophorinae
Figure 23.9
Mantellinae
(Madagascar only):
100 species
Rhacophorinae
(India/southeast
Asia): 310 species 80 60 40 20 1 2
Millions of years ago (mya) 1 2
Figure 23.9 Speciation in frogs as a result of continental drift
India
Madagascar
88 mya
56 mya 34

35. The distribution of fossils and living groups reflects the historic movement of continents
For example, the similarity of fossils in parts of South America and Africa is consistent with the idea that these continents were formerly attached 35

36. Mass Extinctions
The fossil record shows that most species that have ever lived are now extinct
Extinction can be caused by changes to a species’ environment
At times, the rate of extinction has increased dramatically and caused a mass extinction
Mass extinction is the result of disruptive global environmental changes 36

37. The “Big Five” Mass Extinction Events
In each of the five mass extinction events, more than 50% of Earth’s species became extinct 37

38. (families per million years):
Figure 23.10
1,100 25
1,000
900 20
800
700 15
600
(families per million years):
Total extinction rate
Number of families:
500 10
400
300 5
200
Figure Mass extinction and the diversity of life
100
Era
Period
Paleozoic
Mesozoic
Cenozoic Q E O S D C P Tr J C P N
542
488
444
416
359
299
251
200
145
65.5
Time (mya) 38

39. The Permian mass extinction defines the boundary between the Paleozoic and Mesozoic eras 251 million years ago
This mass extinction occurred in less than 500,000 years and caused the extinction of about 96% of marine animal species 39

40. A number of factors might have contributed to these extinctions
Intense volcanism in what is now Siberia
Global warming resulting from the emission of large amounts of CO2 from the volcanoes
Reduced temperature gradient from equator to poles
Oceanic anoxia from reduced mixing of ocean waters 40

41. The Cretaceous mass extinction 65
The Cretaceous mass extinction 65.5 million years ago separates the Mesozoic from the Cenozoic
Organisms that went extinct include about half of all marine species and many terrestrial plants and animals, including most dinosaurs 41

42. The presence of iridium in sedimentary rocks suggests a meteorite impact about 65 million years ago
Dust clouds caused by the impact would have blocked sunlight and disturbed global climate
The Chicxulub crater off the coast of Mexico is evidence of a meteorite collision that dates to the same time 42

43. 43 Figure 23.11 Trauma for Earth and its Cretaceous life Figure 23.11
NORTH
AMERICA
Chicxulub
crater
Yucatán
Peninsula
Figure Trauma for Earth and its Cretaceous life 43

44. Is a Sixth Mass Extinction Under Way?
Scientists estimate that the current rate of extinction is 100 to 1,000 times the typical background rate
Extinction rates tend to increase when global temperatures increase
Data suggest that a sixth, human-caused mass extinction is likely to occur unless dramatic action is taken 44

45. Relative extinction rate of
Figure 23.12 3
Mass extinctions 2 1
Relative extinction rate of
marine animal genera −1
Figure Fossil extinctions and temperature −2 −3 −2 −1 1 2 3 4
Cooler
Warmer
Relative temperature 45

46. Consequences of Mass Extinctions
Mass extinction can alter ecological communities and the niches available to organisms
It can take 5–100 million years for diversity to recover following a mass extinction
The type of organisms residing in a community can change with mass extinction
For example, the percentage of marine predators increased after the Permian and Cretaceous mass extinctions
Mass extinction can pave the way for adaptive radiations 46

47. 47 50 Cretaceous mass extinction Permian mass extinction 40 30
Figure 23.13 50
Cretaceous
mass extinction
Permian mass
extinction 40 30
Predator genera (%) 20 10
Era
Period
Paleozoic
Mesozoic
Cenozoic
Figure Mass extinctions and ecology E O S D C P Tr J C P N
542
488
444
416
359
299
251
200
145
65.5 Q
Time (mya) 47

48. Adaptive Radiations
Adaptive radiation is the evolution of many diversely adapted species from a common ancestor
Adaptive radiations may follow
Mass extinctions
The evolution of novel characteristics
The colonization of new regions 48

49. Worldwide Adaptive Radiations
Mammals underwent an adaptive radiation after the extinction of terrestrial dinosaurs
The disappearance of dinosaurs (except birds) allowed for the expansion of mammals in diversity and size
Other notable radiations include photosynthetic prokaryotes, large predators in the Cambrian, land plants, insects, and tetrapods 49

50. 50 Ancestral mammal Monotremes (5 species) ANCESTRAL CYNODONT
Figure 23.14
Ancestral
mammal
Monotremes
(5 species)
ANCESTRAL
CYNODONT
Marsupials
(324
species)
Eutherians
(5,010
species)
Figure Adaptive radiation of mammals
250
200
150
100 50
Time (millions of years ago) 50

51. Regional Adaptive Radiations
Adaptive radiations can occur when organisms colonize new environments with little competition
The Hawaiian Islands are one of the world’s great showcases of adaptive radiation 51

52. 52 Figure 23.15 Adaptive radiation on the Hawaiian Islands
Close North American
relative, the tarweed
Carlquistia muirii
KAUAI
5.1
million
years
Dubautia laxa
MOLOKAI
1.3
million
years
MAUI
Argyroxiphium
sandwicense
OAHU
3.7
million
years
LANAI
HAWAII
0.4
million
years N
Figure Adaptive radiation on the Hawaiian Islands
Dubautia waialealae
Dubautia scabra
Dubautia linearis 52

53. KAUAI 5.1 million years MOLOKAI 1.3 million OAHU years 3.7 MAUI
Figure 23.15a
KAUAI
5.1
million
years
MOLOKAI
1.3 million
years
MAUI
OAHU
3.7
million
years
LANAI
HAWAII
0.4
million
years
Figure 23.15a Adaptive radiation on the Hawaiian Islands (part 1: map) N 53

54. Concept 23.3: Major changes in body form can result from changes in the sequences and regulation of developmental genes
Studying genetic mechanisms of change can provide insight into large-scale evolutionary change
Genes that program development influence the rate, timing, and spatial pattern of changes in an organism’s form as it develops into an adult 54

55. Changes in Rate and Timing
Heterochrony is an evolutionary change in the rate or timing of developmental events
It can have a significant impact on body shape
The contrasting shapes of human and chimpanzee skulls are the result of small changes in relative growth rates 55

56. 56 Chimpanzee infant Chimpanzee adult
Figure 23.16
Chimpanzee infant
Chimpanzee adult
Figure Relative skull growth rates
Chimpanzee fetus
Chimpanzee adult
Human fetus
Human adult 56

57. Another example of heterochrony can be seen in the skeletal structure of bat wings, which resulted from increased growth rates of the finger bones 57

58. Figure 23.17
Figure Elongated hand and finger bones in a bat wing
Hand and
finger bones 58

59. Heterochrony can alter the timing of reproductive development relative to the development of nonreproductive organs
In paedomorphosis, the rate of reproductive development accelerates compared with somatic development
The sexually mature species may retain body features that were juvenile structures in an ancestral species 59

60. Figure 23.18
Gills
Figure Paedomorphosis 60

61. Changes in Spatial Pattern
Substantial evolutionary change can also result from alterations in genes that control the placement and organization of body parts
Homeotic genes determine such basic features as where wings and legs will develop on a bird or how a flower’s parts are arranged 61

62. Hox genes are a class of homeotic genes that provide positional information during animal development
If Hox genes are expressed in the wrong location, body parts can be produced in the wrong location
For example, in crustaceans, a swimming appendage can be produced instead of a feeding appendage 62

63. The Evolution of Development
Adaptive evolution of both new and existing genes may have played a key role in shaping the diversity of life
Developmental genes may have been particularly important in this process 63

64. Changes in Gene Sequence
New morphological forms likely come from gene duplication events that produce new developmental genes
A possible mechanism for the evolution of six-legged insects from a many-legged crustacean ancestor has been demonstrated in lab experiments
Specific changes in the Ubx gene have been identified that can “turn off” leg development 64

65. 65 Hox gene 6 Hox gene 7 Hox gene 8 Ubx About 400 mya
Figure 23.19
Hox gene 6
Hox gene 7
Hox gene 8
Ubx
About 400 mya
Figure Origin of the insect body plan
Drosophila
Artemia 65

66. Changes in Gene Regulation
Changes in morphology likely result from changes in the regulation of developmental genes rather than changes in the sequence of developmental genes
For example, threespine sticklebacks in lakes have fewer spines than their marine relatives
The gene sequence remains the same, but the regulation of gene expression is different in the two groups of fish 66

67. Concept 23.4: Evolution is not goal oriented
Evolution is like tinkering—it is a process in which new forms arise by the slight modification of existing forms 67

68. Evolutionary Novelties
Most novel biological structures evolve in many stages from previously existing structures
Complex eyes have evolved from simple photosensitive cells independently many times
Exaptations are structures that evolve in one context but become co-opted for a different function
Natural selection can only improve a structure in the context of its current utility 68

69. 69 Figure 23.21 A range of eye complexity in molluscs
(a) Patch of pigmented cells
(b) Eyecup
Pigmented cells
(photoreceptors)
Pigmented
cells
Epithelium
Nerve
fibers
Nerve fibers
Example: Pleurotomaria, a
slit shell mollusc
Example: Patella, a limpet
(c) Pinhole camera-type eye
(d) Eye with primitive lens
(e) Complex camera lens-
type eye
Epithelium
Cellular
mass
(lens)
Cornea
Fluid-filled
cavity
Cornea
Figure A range of eye complexity in molluscs
Lens
Retina
Optic
nerve
Optic nerve
Optic
nerve
Pigmented
layer (retina)
Example: Murex, a marine
snail
Example: Nautilus
Example: Loligo, a squid 69

70. Evolutionary Trends
Extracting a single evolutionary progression from the fossil record can be misleading
Apparent trends should be examined in a broader context
The species selection model suggests that differential speciation success may determine evolutionary trends
Evolutionary trends do not imply an intrinsic drive toward a particular phenotype 70