1. Tracing Evolutionary History Speciation in Real time
Chapter 15
Tracing Evolutionary History
Speciation in Real time

2. Are Birds Really Dinosaurs with Feathers?
Did birds evolve from dinosaurs? Or did they evolve from of earlier group of reptiles that are more closely related to today’s crocs and alligators?
Evolutionary biologists
Have been pondering this question for decades

3. Recent fossil finds
Support this notion:
1861 Archaeopteryx

4. MACROEVOLUTION AND EARTH’S HISTORY
15.1 The fossil record chronicles macroevolution
Macroevolution: activity
The cumulative effects of many speciation events over vast tracts of time and encompasses the origin of evolutionary novelties, such as feathers.
The fossil record
Documents the main events in the history of life
Glimpses of long term evolutionary changes
Allows science to create geological records

5. In the geologic record Major transitions in life-forms separate eras
Smaller changes divide eras into periods

6. The geologic record The oldest known fossils:
Table 15.1
The oldest known fossils:
Prokaryotes date back 3.5 billion years ago.
Eukaryotes date back 2.2 billion years ago.

7. Use Table 15.1 to estimate how long prokaryotes inhabited the Earth before Eukaryotes evolved.

8. 15.2 The actual ages of rocks and fossils mark geologic time
Radiometric dating
Measures the decay of radioactive isotopes
Can gauge the actual ages of fossils and the rocks in which they are found

9. 15.3 Continental drift has played a major role in macroevolution
Is the slow, incessant movement of Earth’s crustal plates on the hot mantle
Edge of one plate being pushed over edge of neighboring plate (zones of violent geologic events)
Antarctic Plate
Australian Plate
Split developing
Indian Plate
Eurasian Plate
North American Plate
South American Plate
Nazca Plate
Pacific Plate
Arabian Plate
African Plate
Figure 15.3A

10. The formation of Pangaea
Altered habitats and triggered extinctions
Figure 15.3B 65
135
245
Millions of years ago
Paleozoic
Mesozoic
Cenozoic
North America
Eurasia
Africa
South
America
India
Antarctica
Australia
Laurasia
Gondwana
Pangaea

11. The separation of the continents
Affected the distribution and diversification of organisms
North
America
South
Europe
Asia
Africa
Australia
= Living lungfishes
= Fossilized lungfishes
Figure 15.3C
Figure 15.3D

12. CONNECTION 15.4 Tectonic trauma imperils local life
Volcanoes and earthquakes result from plate tectonics
The movements of Earth’s crustal plates
San Andreas Fault
North
American
Plate
San Francisco
Santa Cruz
Los Angeles
Pacific
California
Figure 15.4A, B

13. 15.5 Mass extinctions were followed by diversification of life-forms
Occurred at the end of the Permian and Cretaceous periods

14. The Cretaceous extinction, which included the dinosaurs
May have been caused by an asteroid
Figure 15.5
North America
Chicxulub crater
Yucatán Peninsula

15. A rebound in diversity
Follows mass extinctions

16. PHYLOGENY AND SYSTEMATICS
15.6 Phylogenies are based on homologies in fossils and living organisms
Phylogeny, the evolutionary history of a group
Is based upon the fossils that are available to study
Is based on identifying homologous (similarities due to a shared ancestor) and molecular sequences that provide evidence of common ancestry
Generally, organisms that share very similar morphologies or similar DNA sequences are likely to be closely related.

17. Analogous similarities
Result from convergent evolution in similar environments
Species from different evolutionary branches may come to resemble another if they live in very similar environments
Figure 15.6
Two plants look similar (analogous) even though they are not closely related.
On the left is ocotillo, a plant that is grown in Baja California.
On the right is allauidia, which grows in the dessert of Madagascar.

18. Systematics Involves the analytical study of diversity and phylogeny
The evolutionary relationships between organisms

19. 15.7 Systematics connects classification with evolutionary history
Linnaeus’ system was not based upon genealogy or evolutionary relationships.
Two concepts of classification are still used today:
Binomial naming
Two part Latinized name
hierarchical
Taxonomists assign a binomial
Consisting of a genus (first part of the name)
and a species name (second part of the name), to each species
A genus
May include a group of related species

20. A genus May include a group of related species
Felis is the group in which a cat belong

21. Genera are grouped into progressively larger categories
Family, order, class, phylum, kingdom, and domain
Species
Genus
Family
Order
Class
Phylum
Kingdom
Domain
Felis
catus
Felidae
Carnivora
Mammalia
Chordata
Animalia
Eukarya
Figure 15.7A

22. A phylogenetic tree Is a hypothesis of evolutionary relationships
These branching diagrams reflect the hierarchical classification of groups nested within more inclusive groups
Species
Felis
catus
(domestic
cat)
Mephitis
mephitis
(striped skunk)
Lutra
lutra
(European
otter)
Canis
familiaris
(domestic dog)
lupus
(wolf)
Genus
Family
Order
Felidae
Carnivora
Mustelidae
Canidae
Figure 15.7B
The highest, or most inclusive taxon is at the bottom.
Each branch represents the divergence of two lineages from a common ancestor.

23. Using figure 15.7A How much of the classification do we share with the domestic cat?

24. 15.8 Cladograms are diagrams based on shared characters among species
Cladistics uses shared derived characters
To define monophyletic taxa
Identifying ‘clades’ provides branching patterns of evolution
Taxa
Ingroup
(Mammals)
Outgroup
(Reptiles)
Eastern box
turtle
Duck-billed
platypus
Red kangaroo
North American
beaver
Characters
Long gestation
Gestation
Hair, mammary glands
Vertebral column
Figure 15.8A 3 2 1

25. Shared derived characteristics
Groups that share a new, or derived, trait are more closely related to each other.
Shared primitive characters
Traits present in the ancestral groups
Taxa
Ingroup
(Mammals)
Outgroup
(Reptiles)
Eastern box
turtle
Duck-billed
platypus
Red kangaroo
North American
beaver
Characters
Long gestation
Gestation
Hair, mammary glands
Vertebral column
Figure 15.8A 3 2 1
Cladogram: illustrate patterns of shared characteristics

26. The simplest (most parsimonious) hypothesis
Creates the most likely phylogenetic tree
Figure 15.8B
Lizards
Snakes
Crocodiles
Birds
Common reptilian ancestor

27. 15.9 Molecular biology is a powerful tool in systematics
Molecular systematics
Develops phylogenetic hypotheses based on molecular comparisons
Brown bear
Polar
bear
Asiatic
black
American
black bear
Sun
Sloth
Spectacled
Giant
panda
Raccoon
Lesser
Pleistocene
Pliocene 10 15 20 25 30 35 40
Oligocene
Miocene
Millions of years ago
Ursidae
Procyonidae
Common ancestral
carnivorans
Figure 15.9A

28. Studies of ribosomal RNA sequences
Have shown that humans are more closely related to fungi than to green plants
Student
Mushroom
Tulip
Common ancestor
Figure 15.9B

29. DNA Comparisons Molecular comparisons of nucleic acids
Often pose technical challenges
Can reveal the most fundamental similarities or differences between species

30. Molecular Clocks Some regions of DNA
Change at a rate consistent enough to serve as molecular clocks to date evolutionary events

31. Genome Evolution Homologous genes Are found in many species Human
Chimpanzee
Gorilla
Orangutan
Common ancestor
Figure 15.9C

32. 15.10 Arranging life into kingdoms is a work in progress . Activity
In the five-kingdom system
Prokaryotes are in the kingdom Monera
Eukaryotes (plants, animals, protists, and fungi) are grouped in separate kingdoms
Monera
Protista
Plantae
Fungi
Animalia
Earliest
organisms
Prokaryotes
Eukoryotes
Figure 15.10A

33. Recognizes the prokaryotic domains Bacteria and Archaea Eukaryotes
The domain system
Recognizes the prokaryotic domains Bacteria and Archaea
Eukaryotes
Are placed in the domain Eukarya
Bacteria
Archaea
Eukarya
Earliest
organisms
Prokaryotes
Eukoryotes
Figure 15.10B