Transcript Evolution
Theory of Evolution
Introduction to Vocabulary
(Teacher Version)
Evolution
Evolution:
change in the traits of
a species over time (Loooong time)
Species: a group of organisms
who can produce fertile
offspring
Charles Darwin: developed the
theory of evolution called Natural
Selection
Phylogeny
Phylogeny: the evolutionary history of an
organism; this is used to classify organisms into
kingdoms, phyla, classes, etc.; a phylogenetic
tree or cladogram shows how organisms are
related to one another and how they evolved
examples of phylogenetic trees
Prove it….
Evidence to support Evolution
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Prentice Hall
Fossils
These are
imprints or
remains of
living things.
In undisturbed
layers of
sedimentary
rock, the
deeper it is,
the older it is.
Give us
information
about extinct
species.
Fossil Evidence: allows reconstruction of
evolutionary trees
Based on: Mader, S., Inquiry Into Life, McGraw-Hill
Anatomical (body shape) Evidence
homologous
structure: same structure
with different functions found in different
species and thought to be inherited from
common ancestors
ex: humans, whales, and bats all have the same # and type of
bones in the forelimbs but their functions are different
Anatomical Evidence
Anatomical
similarities
suggest
common
descent
Based on: Mader, S., Inquiry Into Life, McGraw-Hill
Here all
vertebrate
forelimbs
contain the
same set of
bones
Biogeographic Evidence
Geographical
Distribution
Similar, But
Unrelated Species
Embryology
Similarity in embryo development shows a close
relationship (vertebrate embryos all have tail &
gill slits)
Similarities in Embryology
The early stages, or embryos, of many animals with
backbones are very similar.
The same groups of embryonic cells develop in the
same order and in similar patterns to produce the
tissues and organs of all vertebrates.
Pharyngeal
pouches
Post-anal
tail
Chick embryo (LM)
Human embryo
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Prentice Hall
Molecular Data
DNA: by comparing the DNA sequences of two organisms or the amino acid
sequences made from the DNA, scientists can learn which organisms are
related; the more DNA two organisms have in common, the closer related
they are
•Using the table, compare the amino acid
sequence of the chimp and the human.
•Notice that for this protein the chimp and
human have the exact same sequence.
•Now compare the baboon and the human.
•Notice that there are 5 differences in the
sequence.
•This tells you that the human is more
closely related to the chimp than the
baboon.
Other Molecular Evidence
Fig. 27.6
Based on: Mader, S., Inquiry Into Life, McGraw-Hill
So how does it happen….
Methods of Evolution
Evolution (Natural or Man-made)
Artificial Selection
Natural provides a great variety of living things. In artificial
selection humans pick the varieties or characteristics that
are the most useful and selectively breed for those traits.
Natural Selection states that:
there is variation (differences) within populations
some variations are favorable (favorable variations
improve an organism’s ability to function and reproduce in
its own environment)
not all young produced in each generation can survive
individuals that survive and reproduce are those with
favorable variations; these individuals can then pass on
the favorable traits to their offspring
Example of Artificial Selection
Natural Selection
Does NOT Act Directly On Genes
Does Act On Phenotypes
The Phenotype Gives The Survival
Edge
Survivors Must Reproduce
Alters
Relative Frequency of Alleles
Over Time
Evolution
Acts On Populations
Does NOT Act On
Individuals
Natural Selection on Single Gene Traits
Key Concept
Natural Selection On Single-Gene
Traits Can Lead To Changes In
Allele Frequencies And Thus To
Evolution
Camouflage
Camouflage
Camouflage
Natural Selection on Single Gene Traits
BUT:
What If Black Allowed The
Lizard To Warm Up Faster &
Move Quicker??????
Natural Selection on Polygenic Traits
Traits
Controlled By More Than
One Gene
Effects
On Natural Selection Are
More Complex
Natural Selection on
Polygenic Traits
Natural selection can affect the distributions of
phenotypes in any of three ways:
directional
selection
stabilizing selection
disruptive selection
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Directional Selection
When individuals at one end of the curve have
higher fitness than individuals in the middle or at
the other end, directional selection takes place.
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Stabilizing
Selection
When individuals
near the center of
the curve have
higher fitness than
individuals at either
end of the curve,
stabilizing
selection takes
place.
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Prentice Hall
Disruptive Selection
When individuals at the upper and lower ends of the
curve have higher fitness than individuals near the
middle, disruptive selection takes place.
If Severe Enough, May Cause The Development Of
TWO Phenotypes
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Prentice Hall
Genetic Drift
Natural Selection Is Not The Only Source
of Evolutionary Change
In Small Populations, An Allele Can
Become More Or Less Common By
Chance
Genetic Drift
Key Concept:
In Small Populations, Individuals That Carry
A Particular Allele May Leave More
Descendents Than Other Individuals, Just
By Chance. Over Time, A Series Of Chance
Occurrences Of This Type Can Cause An
Allele To Become Common In A
Population
Circumstances That May Result
In Genetic Drift:
The
Founder’s Effect
The Bottlenose Effect
Genetic Drift
Founder
Effect
Colonization
Hawaiian
Of A New Habitat
Fruit Flies
Darwin’s Finches
Hawaiian Honey Creepers
Founder Effect
Genetic Drift
The Bottleneck Effect
Occurs
When Man Made, or Natural
Disasters Destroy Most Of A
Population. The Remaining Members
Usually Possess A Severely
Diminished Gene Pool
Evolution vs. Genetic Equilibrium
Under What Conditions Will Evolution
NOT Occur:
1.
2.
3.
4.
5.
Random Mating
Population Must Be Very Large
No Movement In or Out of Pop.
No Mutations
No Natural Selection
This is called the Hardy-Weinberg Principle (1908)
Key Concept:
Genetic Equilibrium will be maintained from Generation To
Generation if the 5 conditions are met.
Random Mating
All Members Of The Population Must
have An Equal Opportunity To
Produce Offspring
Large Population
Genetic Drift Has Less Effect On
Large Populations
No Movement Into or Out Of The Population
New Alleles Must Not Enter
Rare Alleles Must Not Be
Allowed To Leave
No Mutations
Mutations Introduce New Alleles
Causing A Change In Allele
Frequencies
No Natural Selection
All Genotypes Must Have Equal
Opportunity To Survive & Reproduce
No Phenotype Can Have An Advantage
Over Another
Extinction
A population is extinct when the last of that
species is dead.
Example: There are no more dinosaurs.
What happened? Their habitat was destroyed.
When they no longer have what they need to live,
they die.