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The Fossil Record of
Evolution and Extinction
The Fossil Evidence of Evolution
1. Fossils show a pattern of change through geologic time of new species
appearing in the fossil record that are similar to existing species, but
different in one or more key attributes.
2. Fossils reveal the pattern of evolution through time. Evolution has not
proceeded smoothly and regularly. Instead, long intervals of geologic
time with low levels of species formation are punctuated by relatively
short intervals of extinction followed by bursts of evolution.
3. The discontinuities in the fossil record
form the boundaries of the Eons, Eras,
and Periods of geologic time.
4. Fossils provide information about how
major transitions between different
“types” (e.g. fish to tetrapods) unfolded.
Living organisms have many anatomical similarities that reveal their descent
from a common ancestor. Homologies in structures with different functions
don’t make sense from the perspective of design - they are the legacies of
evolution.
rhino
horse
mole
deer
bat
ancestral form
Fossils provide a range of related
species from which can be
constructed a plausible sequence of
transitional forms.
Evolution of the Tetrapod Limb
2006
1986
“Lobe-fin” fish
“Fishapods”
Tetrapods
(amphibian)
Tiktaalik
A ‘fishapod’ from the
Devonian of Canada
From the following article:
A Devonian tetrapod-like fish and the evolution of the tetrapod body plan
Edward B. Daeschler, Neil H. Shubin and Farish A. Jenkins, Jr
Nature 440, 757-763 (6 April 2006)
From the following article:
A Devonian tetrapod-like fish and the evolution of the tetrapod body plan
Edward B. Daeschler, Neil H. Shubin and Farish A. Jenkins, Jr
Nature 440, 757-763 (6 April 2006)
From the following article:
An exceptional Devonian fish from Australia sheds light on tetrapod origins
John A. Long, Gavin C. Young, Tim Holland, Tim J. Senden & Erich M. G. Fitzgerald
Nature 444, 199-202(9 November 2006)
Ever since Darwin published his Theory of Evolution in
1859, biologists have wondered, which group of animals are
the ancestors of birds?
Darwin’s friend and
defender Thomas Huxley
first suggested that the
newly discovered
dinosauria had many
skeletal features in
common with birds.
Archaeopteryx lithographica
Discovered in 1861
Bird features:
• feathers
• wings
• fused clavicle (wishbone)
• hollow bones
Dinosaur features:
• three - fingered hand with claws
• reptile skull with teeth
• long, stiff tail
Archaeopteryx lithographica
Bird features:
• feathers
• wings
• fused clavicle (wishbone)
Dinosaur features:
• three - fingered hand with claws
• reptile skull with teeth
• long, stiff tail
Archaeopteryx lithographica
Bird features:
• feathers
• wings
• fused clavicle
(wishbone)
Dinosaur features:
• three - fingered hand
with claws
• sharp teeth
• long, stiff tail
Skeletal homologies show that Archaeopteryx
and Birds are Coelurosaurian Dinosaurs
• ascending process on
astragalus
• semi-lunate carpal
Archaeopteryx and Birds are Maniraptora
• elongated middle digit on
hand
• clavicles fused to form furcula
(wishbone)
• elongated forelimbs
• bowed ulna
Archaeopteryx and Birds are Dromaeosaurs
• stiffened tail with
elongated zygopopheses
• truncated pubic boot
Deinonychus - a North American dinosaur similar to Velociraptor
Microraptor - Early Cretaceous, China
Feathers - the latest Dinosaur - Bird homology
Microraptor - Early Cretaceous, China
Microraptor
Microraptor
Microraptor
Microraptor
Fourwinged
dinosaurs
from China
Xing Xu, Zhonghe
Zhou, Xiaolin Wang,
Xuewen Kuang,
Fucheng Zhang
and Xiangke Du
Nature 421, 335-340
(23 January 2003)
Microraptor gui
Microraptor gui
Microraptor gui
Microraptor gui
Primitive Early Eocene bat from Wyoming and the evolution of flight and echolocation
Nancy B. Simmons, Kevin L. Seymour, Jörg Habersetzer & Gregg F. Gunnell
Nature 451, 818-821(14 February 2008)
Primitive Early Eocene bat from Wyoming and the evolution of flight and echolocation
Nancy B. Simmons, Kevin L. Seymour, Jörg Habersetzer & Gregg F. Gunnell
Nature 451, 818-821(14 February 2008)
Late Eocene
aquatic
Middle Eocene
Early Eocene
terrestrial
The Fossil Record
of Whale Evolution
Figure based on: Walking with whales, Christian de Muizon
Nature 413, 259-260(20 September 2001)
From the article:
Walking with whales
Christian de Muizon
Nature 413, 259-260(20 September 2001)
Ankle bone homologies
Mesonychid mammal
Primitive ungulate
mammal
Early terrestrial
whale
Early artiodactyl
Modern artiodactyl
Double pulley astragalus
Adaptive Radiation
Morphology
The geologically rapid (1-10’s of million years) evolution
of a variety of new species from a single ancestral stock.
Time
Adaptive Radiation
Triggered by several possible events:
• Evolution of a new organ that allows a species to invade
new ecospace.
Example: the adaptive radiation of amphibians and all
subsequent terrestrial vertebrates that followed the
evolution of tetrapods in the Devonian Period.
Adaptive Radiation
Triggered by several possible events:
• Extinction of an existing, dominant group of organisms,
vacating habitat and food sources.
Example: the adaptive radiation of mammals in the
Tertiary Period following the extinction of the dinosaurs.
Mesozoic
65 my
Cenozoic
Cenozoic
Adaptive Radiation
Triggered by several possible events:
• Evolution of adaptations that confer an advantage over
previously existing species.
Example: the adaptive radiation of flowering plants in the
Cretaceous Period, which evolved the ability to grow
faster and disperse farther than other plants.
Recent
Diagram showing
the relative rise in
dominance of
flowering plants
through the
Cretaceous.
Middle
flowering trees
Early
Cretaceous
Cretaceous
Late
Recent
after Crane, from Friis, Chaloner, and Crane, 1987
The Origin of Angiosperms. Cambridge University Press.
flowering shrubs
flowering herbs
Earliest
conifers, ginkos, bennettitaleans
ferns
Adaptive Radiation
Minor adaptive radiations are often triggered by the
colonization of newly available habitat. After arriving in
the new habitat, a species can evolve into a “swarm” of
new species within a few thousands of years.
Examples:
• Darwin’s finches on the Galapagos Islands.
• Fruit flies and honeycreepers (birds) on the Hawaiian
Islands.
• Cichlid fish in the rift lakes of East Africa.
Extinction
• Extinction occurs when the last individual of a species
dies.
• Extinction is forever. The same species never evolves
more than once.
Mass Extinction
• Many species going extinct in a short interval of
geologic time (less than several millions of years).
• Mass extinctions probably have many different causes,
all related to the disruption of habitats.
• There have been five unusually large mass extinctions
in the last 550 million years.
# of families of marine animals
Analyses of the fossil record show that
certain types of organisms share
similar patterns of evolution and
extinction through time - rising and
falling as a group.
The 5 Major Mass Extinctions
Important Mass Extinctions
• The Permo-Triassic mass extinction at 245 ma, which
may have eliminated 95% of all species of marine life.
Permo-Triassic Mass Extinctions
• Terrestrial ecosystems were also depleted as most species
of synapsid (“mammal-like reptiles”) go extinct.
• In the Triassic reptiles radiate into many new groups and
become the dominant terrestrial animals.
reptile
Cretaceous - Tertiary Mass Extinction
• The extinction of dinosaurs, marine reptiles, flying
reptiles, ammonites, and many species of plankton at 65
ma.
Pleistocene mass extinction
• The extinction of large mammals in North America at the
end of the last ice age 10,000 years ago (mammoths,
mastodons, camels, lions, rhinos, horses).
Neogene
Pleistocene
Paleogene
Cenozoic
Mesozoic
Tertiary
Quat.
Ma
Holocene
Pliocene
Miocene
Oligocene
Eocene
Paleocene
Cretaceous
Jurassic
Triassic
Carb.
Paleozoic
Permian
Pennsylvanian
Mississippian
Devonian
Silurian
Ordovician
Cambrian
0
.01
1.6
5
23
35
57
65
146
208
245
290
323
360
408
439
510
540
Holocene Mass Extinction
• The current mass extinction due to human over-hunting
and destruction of habitat on a global scale.
A mass extinction must involve
geologically abrupt disruption of
existing habitats on a global scale.
Climate change
Sea level change
Atmospheric change
Ocean chemistry change
Bernard
Many geologists have attempted to
attribute mass extinctions to rare
catastrophic events
Supernova
Asteroid Impact
Flood Basalt Volcanism
There is much good evidence for a big impact event
near the end of the Mesozoic.
But evidence associating
impacts with other mass
extinctions is vague or
absent.
Flood basalt eruptions cover immense regions in layer after layer of
basalt, releasing toxic and greenhouse gases into the atmosphere
over tens - hundreds of thousands of years.
Most mass extinctions seem to
correlate with times of major volcanic
eruptions.
The Real Reason Dinosaurs Became Extinct