1. The Cambrian Explosion
The Cambrian explosion refers to the sudden appearance of fossils resembling modern phyla in the Cambrian period (535 to 525 million years ago)
The Cambrian explosion provides the first evidence of predator-prey interactions

2. Fig 25-UN6
Animals 1 4
Billions of
years ago 2 3

3. 500 Sponges Cnidarians Annelids Molluscs Chordates Arthropods
Fig
500
Sponges
Cnidarians
Annelids
Molluscs
Chordates
Arthropods
Echinoderms
Brachiopods
Early
Paleozoic
era
(Cambrian
period)
Millions of years ago
542
Figure Appearance of selected animal phyla
Late
Proterozoic
eon

4. DNA analyses suggest that many animal phyla diverged before the Cambrian explosion, perhaps as early as 700 million to 1 billion years ago
Fossils in China provide evidence of modern animal phyla tens of millions of years before the Cambrian explosion
The Chinese fossils suggest that “the Cambrian explosion had a long fuse”

5. (a) Two-cell stage (b) Later stage 150 µm 200 µm Fig. 25-11
Figure Proterozoic fossils that may be animal embryos (SEM)
(a) Two-cell stage
(b) Later stage
150 µm
200 µm

6. The Colonization of Land
Fungi, plants, and animals began to colonize land about 500 million years ago
Plants and fungi likely colonized land together by 420 million years ago
Arthropods and tetrapods are the most widespread and diverse land animals
Tetrapods evolved from lobe-finned fishes around 365 million years ago

7. Fig 25-UN7
Colonization of land 1 4
Billions of
years ago 2 3

8. Video: Volcanic Eruption
Concept 25.4: The rise and fall of dominant groups reflect continental drift, mass extinctions, and adaptive radiations
The history of life on Earth has seen the rise and fall of many groups of organisms
Video: Volcanic Eruption
Video: Lava Flow

9. Continental Drift
At three points in time, the land masses of Earth have formed a supercontinent: 1.1 billion, 600 million, and 250 million years ago
Earth’s continents move slowly over the underlying hot mantle through the process of continental drift
Oceanic and continental plates can collide, separate, or slide past each other
Interactions between plates cause the formation of mountains and islands, and earthquakes

10. (a) Cutaway view of Earth (b) Major continental plates
Fig
North
American
Plate
Eurasian Plate
Crust
Juan de Fuca
Plate
Caribbean
Plate
Philippine
Plate
Arabian
Plate
Indian
Plate
Mantle
Cocos Plate
Pacific
Plate
South
American
Plate
Nazca
Plate
Outer
core
African
Plate
Australian
Plate
Inner
core
Figure Earth and its continental plates
Scotia Plate
Antarctic
Plate
(a) Cutaway view of Earth
(b) Major continental plates

11. (a) Cutaway view of Earth
Fig a
Crust
Mantle
Outer
core
Figure Earth and its continental plates
Inner
core
(a) Cutaway view of Earth

12. (b) Major continental plates
Fig b
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 Earth and its continental plates
Scotia Plate
Antarctic
Plate
(b) Major continental plates

13. Consequences of Continental Drift
Formation of the supercontinent Pangaea about 250 million years ago had many effects
A reduction in shallow water habitat
A colder and drier climate inland
Changes in climate as continents moved toward and away from the poles
Changes in ocean circulation patterns leading to global cooling

14. Present Cenozoic 65.5 135 Millions of years ago Mesozoic 251 Paleozoic
Fig
Present
Cenozoic
North America
Eurasia
65.5
Africa
South
America
India
Madagascar
Australia
Antarctica
Laurasia
135
Mesozoic
Millions of years ago
Gondwana
Figure The history of continental drift during the Phanerozoic eon
251
Pangaea
Paleozoic

15. Present Cenozoic Millions of years ago 65.5 North America Eurasia
Fig a
Present
Cenozoic
North America
Eurasia
Millions of years ago
65.5
Africa
Figure The history of continental drift during the Phanerozoic eon
India
South
America
Madagascar
Australia
Antarctica

16. 135 Mesozoic Millions of years ago 251 Paleozoic Laurasia Gondwana
Fig b
Laurasia
135
Gondwana
Mesozoic
Millions of years ago
Figure The history of continental drift during the Phanerozoic eon
251
Pangaea
Paleozoic

17. The break-up of Pangaea lead to allopatric speciation
The current distribution of fossils reflects the movement of continental drift
For example, the similarity of fossils in parts of South America and Africa is consistent with the idea that these continents were formerly attached

18. Mass Extinctions
The fossil record shows that most species that have ever lived are now extinct
At times, the rate of extinction has increased dramatically and caused a mass extinction

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

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

21. The Permian extinction defines the boundary between the Paleozoic and Mesozoic eras
This mass extinction occurred in less than 5 million years and caused the extinction of about 96% of marine animal species
This event might have been caused by volcanism, which lead to global warming, and a decrease in oceanic oxygen

22. 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

23. NORTH AMERICA Chicxulub crater Yucatán Peninsula Fig. 25-15
Figure Trauma for Earth and its Cretaceous life
For the Discovery Video Mass Extinctions, go to Animation and Video Files.

24. The presence of iridium in sedimentary rocks suggests a meteorite impact about 65 million years ago
The Chicxulub crater off the coast of Mexico is evidence of a meteorite that dates to the same time

25. 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
Data suggest that a sixth human-caused mass extinction is likely to occur unless dramatic action is taken

26. Consequences of Mass Extinctions
Mass extinction can alter ecological communities and the niches available to organisms
It can take from 5 to 100 million years for diversity to recover following a mass extinction
Mass extinction can pave the way for adaptive radiations

27. (percentage of marine genera)
Fig 50 40 30
(percentage of marine genera)
Predator genera 20 10
Paleozoic
Era
Period
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
Time (millions of years ago)

28. Adaptive Radiations
Adaptive radiation is the evolution of diversely adapted species from a common ancestor upon introduction to new environmental opportunities

29. 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

30. Ancestral mammal Monotremes (5 species) ANCESTRAL CYNODONT Marsupials
Fig
Ancestral
mammal
Monotremes
(5 species)
ANCESTRAL
CYNODONT
Marsupials
(324 species)
Eutherians
(placental
mammals;
5,010 species)
Figure Adaptive radiation of mammals
250
200
150
100 50
Millions of years ago

31. 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

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

33. 1.3 KAUAI MOLOKAI million 5.1 years million MAUI years OAHU 3.7
Fig a
1.3
million
years
KAUAI
5.1
million
years
MOLOKAI
MAUI
OAHU
3.7
million
years
LANAI
Figure Adaptive radiation on the Hawaiian Islands
HAWAII
0.4
million
years

34. Close North American relative, the tarweed Carlquistia muirii
Fig b
Figure Adaptive radiation on the Hawaiian Islands
Close North American relative,
the tarweed Carlquistia muirii

35. Dubautia waialealae Fig. 25-18c
Figure Adaptive radiation on the Hawaiian Islands
Dubautia waialealae

36. Fig d
Figure Adaptive radiation on the Hawaiian Islands
Dubautia laxa

37. Fig e
Figure Adaptive radiation on the Hawaiian Islands
Dubautia scabra

38. Argyroxiphium sandwicense
Fig f
Figure Adaptive radiation on the Hawaiian Islands
Argyroxiphium sandwicense

39. Dubautia linearis Fig. 25-18g
Figure Adaptive radiation on the Hawaiian Islands
Dubautia linearis

40. Concept 25.5: 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

41. Evolutionary Effects of Development Genes
Genes that program development control the rate, timing, and spatial pattern of changes in an organism’s form as it develops into an adult

42. 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
Animation: Allometric Growth

43. Figure 25.19 Relative growth rates of body parts
Newborn 2 5 15
Adult
Age (years)
(a) Differential growth rates in a human
Figure Relative growth rates of body parts
Chimpanzee fetus
Chimpanzee adult
Human fetus
Human adult
(b) Comparison of chimpanzee and human skull growth

44. (a) Differential growth rates in a human
Fig a
Figure Relative growth rates of body parts
Newborn 2 5 15
Adult
Age (years)
(a) Differential growth rates in a human

45. (b) Comparison of chimpanzee and human skull growth
Fig b
Chimpanzee fetus
Chimpanzee adult
Figure Relative growth rates of body parts
Human fetus
Human adult
(b) Comparison of chimpanzee and human skull growth

46. 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

47. Fig
Gills
Figure Paedomorphosis

48. 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

49. Hox genes are a class of homeotic genes that provide positional information during 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

50. Evolution of vertebrates from invertebrate animals was associated with alterations in Hox genes
Two duplications of Hox genes have occurred in the vertebrate lineage
These duplications may have been important in the evolution of new vertebrate characteristics

51. Hypothetical vertebrate ancestor (invertebrate)
Fig
Hypothetical vertebrate
ancestor (invertebrate)
with a single Hox cluster
First Hox
duplication
Hypothetical early
vertebrates (jawless)
with two Hox clusters
Second Hox
duplication
Figure Hox mutations and the origin of vertebrates
Vertebrates (with jaws)
with four Hox clusters

52. The Evolution of Development
The tremendous increase in diversity during the Cambrian explosion is a puzzle
Developmental genes may play an especially important role
Changes in developmental genes can result in new morphological forms

53. Changes in Genes
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

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

55. Changes in Gene Regulation
Changes in the form of organisms may be caused more often by changes in the regulation of developmental genes instead of changes in their sequence
For example three-spine 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

56. Differences in the coding sequence of the Pitx1 gene? Result: No
Fig
RESULTS
Test of Hypothesis A:
Differences in the coding
sequence of the Pitx1 gene?
Result: No
The 283 amino acids of the Pitx1 protein
are identical.
Test of Hypothesis B:
Differences in the regulation
of expression of Pitx1 ?
Pitx1 is expressed in the ventral spine
and mouth regions of developing marine
sticklebacks but only in the mouth region
of developing lake stickbacks.
Result:
Yes
Marine stickleback embryo
Lake stickleback embryo
Figure What causes the loss of spines in lake stickleback fish?
Close-up
of mouth
Close-up of ventral surface

57. Marine stickleback embryo Lake stickleback embryo
Fig a
Marine stickleback embryo
Lake stickleback embryo
Close-up
of mouth
Figure What causes the loss of spines in lake stickleback fish?
Close-up of ventral surface

58. Concept 25.6: 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

59. 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

60. (a) Patch of pigmented cells (b) Eyecup
Fig
Pigmented cells
(photoreceptors)
Pigmented
cells
Epithelium
Nerve fibers
Nerve fibers
(a) Patch of pigmented cells
(b) Eyecup
Fluid-filled cavity
Cellular
mass
(lens)
Cornea
Epithelium
Optic
nerve
Pigmented
layer (retina)
Optic nerve
(c) Pinhole camera-type eye
(d) Eye with primitive lens
Figure A range of eye complexity among molluscs
Cornea
Lens
Retina
Optic nerve
(e) Complex camera-type eye

61. Evolutionary Trends
Extracting a single evolutionary progression from the fossil record can be misleading
Apparent trends should be examined in a broader context

62. Figure 25.25 The branched evolution of horses
Recent
(11,500 ya)
Equus
Hippidion and other genera
Pleistocene
(1.8 mya)
Nannippus
Pliohippus
Pliocene
(5.3 mya)
Hipparion
Neohipparion
Sinohippus
Megahippus
Callippus
Archaeohippus
Miocene
(23 mya)
Merychippus
Anchitherium
Hypohippus
Parahippus
Miohippus
Oligocene
(33.9 mya)
Figure The branched evolution of horses
Mesohippus
Paleotherium
Epihippus
Propalaeotherium
Eocene
(55.8 mya)
Pachynolophus
Orohippus
Key
Grazers
Hyracotherium
Browsers

63. Oligocene (33.9 mya) Eocene (55.8 mya)
Fig a
Miohippus
Oligocene
(33.9 mya)
Mesohippus
Paleotherium
Epihippus
Propalaeotherium
Eocene
(55.8 mya)
Pachynolophus
Orohippus
Key
Figure The branched evolution of horses
Grazers
Hyracotherium
Browsers

64. Figure 25.25 The branched evolution of horses
Fig b
Recent
(11,500 ya)
Equus
Hippidion and other genera
Pleistocene
(1.8 mya)
Nannippus
Pliohippus
Pliocene
(5.3 mya)
Hipparion
Neohipparion
Sinohippus
Megahippus
Callippus
Archaeohippus
Miocene
(23 mya)
Figure The branched evolution of horses
Merychippus
Anchitherium
Hypohippus
Parahippus

65. According to the species selection model, trends may result when species with certain characteristics endure longer and speciate more often than those with other characteristics
The appearance of an evolutionary trend does not imply that there is some intrinsic drive toward a particular phenotype

66. Millions of years ago (mya)
Fig 25-UN8
1.2 bya:
First multicellular eukaryotes
535–525 mya:
Cambrian explosion
(great increase
in diversity of
animal forms)
500 mya:
Colonization
of land by
fungi, plants
and animals
2.1 bya:
First eukaryotes (single-celled)
3.5 billion years ago (bya):
First prokaryotes (single-celled)
500
4,000
3,500
3,000
2,500
2,000
1,500
1,000
Present
Millions of years ago (mya)

67. Ceno- Meso- zoic zoic Paleozoic Origin of solar system and Earth 1 4 2
Fig 25-UN9
Ceno-
zoic
Meso-
zoic
Paleozoic
Origin of solar system
and Earth 1 4
Proterozoic
Archaean
Billions of
years ago 2 3

68. Flies and fleas Caddisflies Moths and butterflies Herbivory
Fig 25-UN10
Flies and
fleas
Caddisflies
Moths and
butterflies
Herbivory

69. Ceno- zoic Meso- zoic Paleozoic Origin of solar system and Earth 1 4
Fig 25-UN11
Ceno-
zoic
Meso-
zoic
Paleozoic
Origin of solar system
and Earth 1 4
Proterozoic
Archaean
Billions of
years ago 2 3

70. You should now be able to:
Define radiometric dating, serial endosymbiosis, Pangaea, snowball Earth, exaptation, heterochrony, and paedomorphosis
Describe the contributions made by Oparin, Haldane, Miller, and Urey toward understanding the origin of organic molecules
Explain why RNA, not DNA, was likely the first genetic material

71. Describe and suggest evidence for the major events in the history of life on Earth from Earth’s origin to 2 billion years ago
Briefly describe the Cambrian explosion
Explain how continental drift led to Australia’s unique flora and fauna
Describe the mass extinctions that ended the Permian and Cretaceous periods
Explain the function of Hox genes