Transcript Chapter 17:

Chapter 17:
The History of Life
17-1 The Fossil Record
What is a fossil?
Paleontologist: scientist who studies fossils
Fossil record: provides info about the past…
Incomplete!
How do fossils form?
Some trace of an organism must be preserved
Sedimentary rock
Several ways:
Imprint of soft parts
Replace bone/wood/shell with minerals
“perfect preservation”
**not all living things leave fossils!**
Interpreting Fossil Evidence
Must find them first- earth erodes
Use pieces- rarely see whole organisms
Look for similarities/differences between fossils and
current organisms
Date the fossil
Dating Fossils
1. relative dating- vertical order (oldest at bottom)
Index fossil: distinct fossil used to compare relative ages
of fossils
2. radioactive dating- uses half life of radioactive
element to determine age
Half life: length of time required for ½ radioactive
atoms to decay
Ex: carbon- 14 (decays) and carbon 12 (no decay)
Geologic Time Scale
Represents evolutionary time
Worldwide studies
Use relative dating to organize
Use radioactive dating to get specific date
17-2 Earth’s Early History
How did life begin? (loaded question)
Current scientific view:
Young earth struck by an object (another planet?)
Heat melted the earth- all elements rearranged
Settled by density (core, crust, atmosphere)
Water!
3.8 billion years ago: Earth cooled enough for water
Oceans formed- red from iron
Life began in the water!
How did life form?
Miller and Urey
Simulated earth’s early conditions in a lab:
“Primordial soup”
Hydrogen, methane, ammonia gases
Closed off experiment to any “life”
Electric spark (to simulate lightning)
Organic compounds formed! (amino acids)
Simple compounds of primitive earth can
create organic compounds
Free Oxygen and Life on Earth
bacteria-like organisms were first
Increase in photosynthetic bacteria:
O2 in water = ocean turns blue/green
O2 in air = sky turns blue
O2 kills many life forms
Others learn to adapt or live anaerobically
Origin of Eukaryotic Cells
Endosymbiotic theory: idea that eukaryotic organisms
formed from a symbiosis among different prokaryotic
organisms
Prokaryotes taken up by other prokaryotes
Learn to use O2= mitochondria
Photosynthetic= chloroplast
Increasing Diversity Among
Organisms
Sexual reproduction: adds genetic variation thru gene
shuffling
Multicellularity
Geologic Time Line Project
Work in groups of 3
You will be assigned a time period
You will have 20 min to find the following BASIC info
on your period and design a mini poster for it
Period Name
Era in which it belongs
3-5 defining characteristics
A visual- make it look nice!
Be sure to include your names
17-3 Evolution of Multicellular
Life
Precambrian Time (88% of life on earth so far)
Anaerobic to aerobic organisms
Eukaryotes formed
Multicellular organisms
Life in sea only
Paleozoic Era
Characterized by diversity of marine life
Cambrian Period:
“explosion” of invertebrate diversity
trilobites (arthropods)
Ordovician and Silurian Periods
Some movement to land
First vertebrate- jawless fish
Paleozoic Era (cont.)
Devonian Period
Age of the Fishes (sharks)
First vertebrates on land (amphibians)
Carboniferous and Permian Periods
Reptiles evolve from amphibians
Mass extinction: occurs when many organisms die out at
the same time
Mesozoic Era
Characterized by dinosaurs and flowering plants
Triassic Period
Age of the reptiles
Dinosaurs
First mammals (small shrews)
Jurassic Period
When dinosaurs ruled the earth…
First bird- Archaeopteryx
Mesozoic Era (cont.)
Cretaceous Period
T-Rex ruled
Flying reptiles and birds
Shrubs and flowering plants (fruits)
Mass extinction occurs - no more dinosaurs 
Cenozoic Era
Characterized as the age of the mammals
No more competition with dinosaurs
Adapted to land, sea and sky
Tertiary Period:
Insects, grazing animals (grass)
Quaternary Period:
Ice ages, mammoths
Early humans -> Homo sapiens
17-4 Patterns of Evolution
Macroevolution: large scale patterns of processes that
happen over a long period of time
Patterns/Trends:
1. extinction
2. adaptive radiation
3. convergent evolution
4. coevolution
5. punctuated equilibrium
6. developmental genes and body plans
1. Extinction
Remember Darwin? Fighting for resources?
Other causes include loss of an entire ecosystem (mass
extinctions)
Benefits: opens up habitats for survivors
Usually see a burst of evolution/diversity
2. Adaptive Radiation
Process where a single species or a small group of a
species evolves into several different forms that live in
different ways
Increases diversity of organisms
Ex: Darwin’s finches!
3. Convergent Evolution
Process by which unrelated organisms independently
evolve similarities when adapting to similar
environments
Ex: penguin (bird), shark (fish) and dolphin (mammal)
all develop streamline bodies and swimming
appendages
Analogous structures: structures that look and function
the same but have no common evolutionary history
4. Coevolution
Process by which two species evolve in response to
changes in each other
Ex: orchid’s spur hold nectar 40 cm down and a hawk
moth has a 40 cm long feeding tube
5. Punctuated Equilibrium*
Pattern of evolution in which long, stabile periods are
interrupted by brief periods of more rapid change
Darwin said gradualism (slow and steady)
Rapid evolution may be due to:
Genetic drift- small pop.
Founder effect- small pop.
Mass extinction- opens new habitats
6. Developmental Genes and
Body Plans
Remember hox genes?
Genes cause changes in physical body plan- natural
selection then acts on these changes
Ex: ancient insects= wings on all body segments and
modern insects have wings on only 1 or 2 segments