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Transcript
2.
Early history of Earth
1. 4.6 billion years old
1ST life  3.5 billion years ago


Fossils – any evidence of an organism that
lived long ago
Classified by the way they are found
Casts
 Trace Fossils
 Imprints
 Mold
 Petrified Fossils
 Preserved (amber) or frozen (whole organisms)
 Fossil Pollen

CASTS
TRACE FOSSILS
Markings or evidence of
animal activities
(ex. Footprints)



Mold of organism is
created & becomes
filled in by minerals in
the surrounding rock
Produces a replica of
the original organism
IMPRINTS

MOLD
Fossils form before
sediments harden into
rock

Organism is buried – it
decays & leaves an
empty space in the rock
that is the exact shape of
the organism
PETRIFIED FOSSILS


Hard parts of organisms
are sometimes
penetrated and replaced
by minerals, atom-foratom
When minerals harden,
an exact stone copy of
the original organism is
produced
PRESERVED OR FROZEN


Entire intact organism
can be found frozen in
ice or preserved in
fossilized tree sap
Rare but valuable!
because even the most
delicate parts of the
organism are usually
preserved
Fossil
Pollen
gives clues to
ancient climate
and
environmental
conditions
Fossils are found in
sedimentary rocks (small
pieces of sand/mud/clay

Relative Dating –
sedimentary layers
closer to Earth’s surface
are “younger”


Organisms are related to
the layer they’re found
Radiometric Dating –
finds absolute age of
fossils

Uses isotopes that break
down over time


1ST of January – Earth formed (4.6 bya)
March 20 –
Precambrian Era
begins
- oldest evidence
of life

Mid-October (!!) – end
of PreCambrian Era

Algae, sponges,
jellyfish

Mid-October – Paleozoic
Era begins

EXPLOSION of life
 Land plants!
 Earliest vertebrates
amphibians & reptiles

Continental drift separates continents

Triassic = 1ST small mammals

Jurassic = (mid-December) – Age of Dinosaurs

Cretaceous = larger mammals & flowering plants



Current era
“December 31” – Humans Appear
Fossil record shows evidence of many
extinctions
Early Ideas


Spontaneous generation – life was thought to be
produced from nonliving matter
Experiments of Francesco Redi (1668)



Disproved this theory for large organisms
Louis Pasteur (1800’s) disproved the belief that
microorganisms grew spontaneously from the air
Biogenesis = important law of biology  living
organisms come only from other living organisms




Question to be answered: How did life begin
on Earth?
Answers are based on experimental evidence…
not fossils
Alexander Oparin (1930’s) – proposed theory
that life began in the oceans (“primordial soup”)
Stanley Miller & Harold Urey (1953) –
simulated early Earth’s atmosphere; created
amino acids and organic compounds


Small pools of warm water  theorized to be
sites for production of proteins, ATP, and
nucleic acids… which become surrounded by a
membrane
Sidney Fox – produced protocells (large
ordered structure that carried out some
activities of life such as growth, division, &
metabolism)





1ST cells  anaerobic heterotroph
Prokaryotes – simple cells that did not use
Oxygen and got their food from their
surroundings
Over time  chemosynthetic autotrophs
appeared… could make their own food! Similar to
present day Archaebacteria that live in harsh
conditions (will learn about those later)
Finally – photosynthetic prokaryotes; 3.5 byo
fossils have been found in Australia
These cells produced Oxygen & started to change
Earth’s atmosphere; leading to evolution of aerobic
respiration  “oxygen revolution”
Presence of oxygen led to development of Ozone
(O3) layer that shielded Earth from UV rays &
allowed for evolution of more complex organisms
Charles Darwin & Natural Selection

Development of evolutionary theory –
1. geologic evidence showed Earth is very old
 2. Fossil evidence pointed to changes in life forms
over time
 3. Scientists wondered where species came from,
and how they changed over time
 4. Charles Darwin proposed an explanation that has
become accepted by the majority of scientists.




Founder of modern evolutionary theory
1831- naturalist aboard H.M.S. Beagle  spent 5
years on expedition to South America & South
Pacific Ocean
Visited Galapagos Islands  volcanic islands
1000km off western coast of Ecuador, SA




Observed & gathered many specimens
Back in England – influenced with population
studies & idea of struggle for survival
Conducted his own experiments with artificial
selection = breeding for specific traits
1859 – proposed mechanism of natural selection
for evolution

Stabilizing Selection
1. Favors average individuals
 2. Ex. Spider size = too large  can be captured/eaten!
Too small  can’t hunt well


Directional Selection
1. Favors one of the extreme forms of a trait
 2. Ex. Woodpeckers = looooong beaks may be more
favorable if insects live deep within trees


Disruptive Selection
1. Favors both extreme forms of a trait
 2. Ex. Limpet (mollusk) = both white & black forms can
hide on rocks; grey-colored forms are visible & tend to get
eaten by birds


Geographic Isolation
Physical barrier separates a pop. into groups
 This is what happens on islands


Reproductive Isolation
Organisms that once interbred are prevented from
producing fertile offspring
 May be the result of seasonal differences in mating


Polyploid Speciation
Results from chromosomes not separating during meiosis
 Results in an immediate new species  common in plants


Gradualism




Adaptive changes over time
Supported by the fossil record
Example  camels & horses
Punctuated Equilibrium
Rapid bursts of speciation with stable periods in
between
 May result from climate change
 Also supported by the fossil record
 Example  elephants


Adaptive Radiation

Process of evolution of an ancestral species into
many species that occupy different niches
Niche = role a species plays in a community
regarding food, space, reproduction, and how it
interacts w/nonliving factors

EX. Honeycreepers (birds) of Hawaiian Islands

 Similar in body size & shape
 VERY different in plumage & beak shape


Species begin to adapt to different
environmental conditions
Species become less & less alike
The common ancestral
mammal probably existed
about 190 m.y.a & with the
extinction of the dinosaurs,
underwent extensive
adaptive radiation to fill a
wide range of ecological
niches

Distantly related organisms evolve similar
traits


Response to similar environments & selection
pressures
Dolphins & fishes (yes this is correct if you’re talking about different
varieties/species)
Population Genetics & Evolution



1. within the lifetime of one individual, new features
cannot evolve
2. Natural selection operates only on populations
over many generations
B. Vocabulary for Population Genetics



1. Gene Pool = entire collection of genes in a
population
2. Genetic Equilibrium = population in which the
frequency of alleles does not change from generation
to generation
3. Frequency = how often a particular allele occurs
in the gene pool


Mutation – rare that mutations result in
favorable variation
Genetic Drift


Changes in allelic frequency by chance processes
More likely to occur in small populations
 why? In small populations, individuals with recessive
genes are more likely to mate


Ex. High incidence of polydactyly in an Amish
population in Pennsylvania
Migration of individuals in & out of
populations





Variations exist within populations
Some variations are more advantageous for
survival & reproduction that others
Organisms produce more offspring than can
survive
Over time, offspring of survivors will make up
a larger proportion of the population
Depending on environmental factors, after
MANY generations, a population may come to
look very different from the original
population


Structural adaptations arise over MANY
generations
Examples of Structural Adaptations
1. Mimicry = an organism copies, or mimics, another
Monarch
 2. Camouflage = an organism can blend in with it’s
butterflies
surroundings
have a bitter
awfultaste
3. to
Physiological Adaptations
CAN YOU SEE THE

birds…
 - changes in metabolic___________________?
processes
Viceroy’s don’t
produce
 the
- occurs very quickly in bacteria
same chemical,
 Antibiotic resistance
but birds learn
not to eat them
based on the
pattern


Fossils
Anatomical Studies

1. Homologous Structure
 Modified structure that is seen among different groups of
descendents
 EX. Forelimbs of crocodiles, bats & chickens
 Similarity of structure means organisms are closely related 

2. Analogous Structure
 Similar in function, but different in structure
 EX: Birds & butterfly wings have the same job (flight) but are
made of different materials

3. Vestigial Structure
 Structure without a function; shows structural change of a
species over time
 EX. Appendix; flightless birds; eyes of sightless cave fish

Studies of Embryos  similarities in embryo
appearance
Which one is the human?
Fish? Bird? Rabbit?

Genetic Studies  similarities in DNA patterns
suggest close ancestors