BIO-121 Lab 10-Evolution 3.pptx PDF

Summary

This document discusses the theory of evolution, evidence of evolution including fossils, the geological timescale, biogeographical evidence, and mass extinctions. It covers concepts of natural selection, adaptation, and the history of life on Earth, through a series of slides with relevant information.

Full Transcript

Lab 10 - Evolution

BIO-121
27.1 Theory of Evolution 12

Darwin’s theory of natural selection.
Individual organisms within a population differ in terms of
their reproductive success.
Some individuals in a population have favorable traits that
enable them to better compete for limited resources.
Can devote more energy to reproduction and have more
offspring.
27.1 Theory of Evolution 13

Darwin’s theory of natural selection.
Organisms become adapted to conditions as the environment
changes.
Natural selection through differential reproductive success
shapes traits.
The result of this descent with modification is adaptation.
Adaptation—any evolved trait that helps an organism be
more suited to its environment.
27.2 Evidence of Evolution 2

Descent with modification.
All living things share the same fundamental
characteristics.
Made of cells.
Take chemicals and energy from the environment.
Respond to stimuli.
Reproduce.
Life’s diversity is due to organisms adapting to different
environments.
Features that enable them to survive in each environment
vary greatly.
Fossil Evidence 1

Fossils are remains and traces of past life or any
other direct evidence of past life.
Hard body parts most often preserved: shells, bones,
teeth.
Soft parts can be buried quickly so decomposition is never
completed.
Traces include footprints, burrows, casts.
Majority of fossils embedded in sedimentary rock.
Deposited in layers called strata.
Any stratum is older than the one above it and younger than the
one below it.
Fossil Evidence 2

Some fossils serve as transitional links between
groups.
Fossils of Archaeopteryx that lived 165 million years ago
serve as an example.
They display an intermediate form between dinosaurs
and birds.
Dinosaur features—jaws with teeth, a long, jointed tail.
Bird features—feathers and wings found in modern birds.
The fossils of Archaeopteryx are similar to other
transitional fossils in that they have some traits like their
ancestors and others like their descendants, rather than
intermediate traits.
Transitional Fossils

(a): ©Jason Edwards/Getty Images; (b): ©Joe Tucciarone
Fossil Evidence 3

Fossils of Ambulocetus natans suggest that
whales had a terrestrial ancestor.
It was the size of a large sea lion, with broad,
webbed feet on its forelimbs.
Its hindlimbs enabled walking and swimming.
It also had tiny hooves on its toes.
It had the primitive skull and teeth of early
whales.
Fossil Evidence 4

Modern whales still have remnants of a
hindlimb with fewer bones and bones
reduced in size.
As ancestors to whales adapted to an
increasing aquatic lifestyle, the location
of the nasal opening transitioned.
Tip of snout (Ambulocetus).
Midway between tip of snout and the
skull (Basilosaurus).
Now at the very top of the head in
modern whales.
Geological Timescale 1

History of Earth is divided into eras, then periods,
and then epochs.
Fossil record has helped determine the dates.
Two methods are used:
Relative dating method.
Determines the relative order of fossils and strata but not the
actual date.
Absolute method.
Radioactive dating techniques are used to assign an actual date
to a fossil.
Technique is based on the half-life of radioactive isotopes.
 Geological Timescale 2

The Geological Timescale: Major Divisions of Geological Time and Some of the
Major Evolutionary Events of Each Time Period
Era Period Epoch Million Plant Life Animal Life
Years Ago
(mya)
Cenozoic Quaternary Holocene current Humans influence Age of Homo
plant life. sapiens

Significant Extinction Event Underway
Cenozoic Quaternary Pleistocene 0.01 Herbaceous plants Presence of ice age
spread and diversify. mammals. Modern
humans appear.
Neogene Pliocene 2.6 Herbaceous First hominids
angiosperms flourish. appear.
Neogene Miocene 5.3 Grasslands spread as Apelike mammals
forests contract. and grazing
mammals flourish;
insects flourish.
Neogene Oligocene 23.0 Many modern Browsing mammals
families of flowering and monkeylike
plants evolve; primates appear.
appearance of
grasses.
 Geological Timescale 3

Cenozoic Paleogene Eocene 33.9 Subtropical forests All modern orders of
with heavy rainfall mammals are
thrive. represented.
Paleogene Paleocene 55.8 Flowering plants Ancestral primates,
continue to diversify. herbivores,
carnivores, and
insectivores appear.

Mass Extinction: 50% of all species, dinosaurs and most reptiles
Mesozoic Cretaceous N/A 65.5 Flowering plants Placental mammals
spread; appear; modern
conifers persist. insect groups
appear.

Jurassic N/A 145.5 Flowering plants Dinosaurs flourish;
appear. birds appear.

Mass Extinction: 48% of all species, including corals and ferns
Mesozoic Triassic N/A 199.6 Forests of conifers and First mammals
cycads dominate. appear; first
dinosaurs appear;
corals and molluscs
dominate seas.

Mass Extinction (“The Great Dying”): 83% of all species on land and sea
 Geological Timescale 4

Paleozoic Permian N/A 251.0 Gymnosperms Reptiles diversify;
diversify. amphibians
decline.
Carboniferous N/A 299.0 Age of great coal- Amphibians diversify;
forming forests: ferns, first reptiles appear; first
club mosses, and great radiation of
horsetails flourish. insects.

Mass Extinction: Over 50% of coastal marine species, corals
Paleozoic Devonian N/A 359.2 Flowering plants First insects and first
spread; conifers amphibians
persist. appear on land.

Silurian N/A 416.0 Seedless vascular Jawed fishes diversify
plants appear. and dominate the seas.

Mass Extinction: Over 57% of marine species
Paleozoic Ordovician N/A 443.7 Nonvascular land Invertebrates spread
plants appear. and diversify;
first jawless and then
jawed fishes
appear.
 Geological Timescale 5

Paleozoic Cambrian N/A 488.3 Marine algae flourish. All invertebrate phyla
present; first
chordates appear.
N/A 630 First soft-bodied
invertebrates evolve.
N/A 1,000 Protists diversify.
N/A 2,100 First eukaryotic cells
evolve.
N/A 2,700 O2 accumulates in
atmosphere.
N/A 3,500 First prokaryotic cells
evolve.
N/A 4,570 Earth forms.
Biogeographical Evidence 1

The first cells evolved in water.
Organisms are composed of 70% to 90%
water.
Water is a polar molecule.
Water molecules form hydrogen bonds,
which cause them to cling to one another.
Water is liquid at temperatures typical of the
Earth’s surface due to hydrogen bonding.
Biogeographical Evidence 2

Continental Drift.
The positions of continents and oceans have shifted through time.
The distribution of fossils and existing species provides evidence of
former positions of continents.
Mass Extinctions 1

Extinction—death of every member of a species.
Large numbers of species become extinct in a short
period of time in a mass extinction.
The remaining species may spread out and fill habitats left
vacant.
Five major extinctions have occurred.
They occurred at the end of Ordovician, Devonian, Permian,
Triassic, and Cretaceous periods.
Earth may currently be experiencing a sixth mass extinction due
to human activities.
Mass Extinctions 2

Cretaceous mass extinction.
Likely due to large meteorite striking Earth.
Dust cloud blocked out sun, killing plants.
All dinosaurs went extinct.

Ordovician mass extinction.
Continental drift of Gondwana to South Pole contributed.
Devonian mass extinction.
End of 70% of marine invertebrates.
May have been due to movement of Gondwana back to
South Pole.
Anatomical Evidence 1

Common descent offers explanation for
anatomical similarities among organisms.
Homologous structures.
Anatomically similar because they are inherited from a
common ancestor.
Example: human arm and whale forelimb.
Vestigial structures.
Anatomical structures fully functional in one group and
reduced or nonfunctional in another.
Example: snakes have no use for hindlimbs, and yet some
have remnants of hindlimbs in pelvic girdle and leg.
Anatomical Evidence 2

Embryological development.
At some time in development, all vertebrates have a
tail and paired pharyngeal pouches.
Reflects common ancestry.
Exception: Analogous structures.
Serve the same function but not constructed similarly
and do not share a common ancestry.
Example: wing of bird and wing of an insect.
Anatomical Evidence 3
Similarities in
Vertebrate
Development
Biochemical Evidence
Almost all organisms use the same basic biochemical
molecules, including DNA, ATP, and many enzymes.
Organisms use the same DNA triplet code for the same 20 amino
acids in their proteins.
Humans share many genes with much simpler organisms.
The diversity of life is due to only a slight difference in many of the
same genes.
The more similar the DNA sequences, the more closely related the
organisms are.
Evolution is a theory, supported by a large number of
observations and experiments.
Significance of Biochemical Differences
Humans as Agents of Evolution 1

Humans can artificially modify desired traits in plants and
animals by selecting to breed individuals with preferred traits.
Artificial selection is a type of human-controlled breeding to
increase the frequency of desired traits.
Artificial selection, like natural selection, is possible because
the original population exhibits a variety of characteristics,
allowing humans to select preferred traits.
Humans as Agents of Evolution 2

Artificial selection has led to the existence of many dog
breeds.
All breeds are descendants of the wolf.
Darwin concluded that if humans could create such
variety of organisms by artificial selection, then natural
selection could also produce diversity.
In natural selection, the environment is the force selecting
for particular traits.
Humans as Agents of Evolution 3
Evolution in Natural Populations 1

The Galápagos finches have beaks adapted to the
food they eat, with different species of finches on
each island.
One study of finches from the island called Daphne
Major began in 1973.
Revealed that the beak depth of the medium ground
finch (Geospiza fortis) changed between wet and dry
years.
During wet years, finches eat small, tender seeds.
During dry years, they must eat larger, drier seeds that are more
difficult to crush.
Evolution in Natural Populations 2

During dry years, the majority of finches died
from starvation because their beaks were not
well-equipped to feed on harder seeds.
The finches with deeper beaks survived and
reproduced.
In the next generation of G. fortis birds, the average
beak was deeper than the previous generation.
Conclusion—evolutionary change can sometimes
be observed within the time frame of a human life
span.
Evolution in Natural Populations 3
27.3 Microevolution
Evolution is change in heritable traits, not change
in traits in an individual’s lifetime.
Darwin observed that populations evolve, not
individuals.
Could not explain how traits change over time.
Now known that genes interact with the environment to
determine traits.
Evolution is really about genetic change, because genes
and traits are linked.
Microevolution is the change in allele frequencies
in a population over time.
Allele Frequencies 1

Gene pool—the sum total of all alleles of all genes
in a population.
Sample study.
25 peppered moths collected from a population.
Some are dark and some are light.
A total of 50 alleles are present.
10 alleles are D and 40 alleles are d.
The frequency of the D and d alleles is
for D.
for d.
Allele frequency: the proportion of each allele in a population’s
gene pool.
Allele Frequencies 2

The frequencies of D and d add up to 1.
This relationship is true of the sum of allele
frequencies in a population for any gene of any
diploid organism.
The relationship is described by the expression:
p+q=1
p is the frequency of D.
q is the frequency of d.
In the moth study, the allele frequencies did not
change over three generations, implying no evolution.
Hardy-Weinberg Equilibrium 1

Genetic equilibrium describes a population in which allele
frequencies do not change over time (also referred to as
Hardy–Weinberg equilibrium)—a stable nonevolving
state.
Hardy and Weinberg used the equation: p2 + 2pq + q2 to
describe the genotype and allele frequencies in a
population.
p2 = frequency of DD genotype.
2pq = frequency of Dd genotype.
q2 = frequency of dd genotype.
Hardy-Weinberg Equilibrium 3

The Hardy–Weinberg principle.
Allele frequencies in a gene pool will remain at
equilibrium, thus constant, in each generation of
a large, sexually reproducing population as long
as the following five conditions are met:
No mutations.
No genetic drift.
No gene flow.
Random mating.
No selection.
Hardy-Weinberg Equilibrium 4

Although possible in theory, the Hardy–Weinberg
equilibrium is never achieved in wild populations.
All five conditions are never met in the real world.
Populations are constantly evolving.

The Hardy–Weinberg principle is an important tool
because the violation of one or more of the
conditions causes allele and genotype frequencies
to change in predictable ways.
Hardy-Weinberg Equilibrium 5

Hardy-Weinberg Proportions Can Be Used to Determine If Evolution Has
Occurred
Hardy-Weinberg Deviation from Effect of Deviation Expected Deviation Evolution
Condition Condition on Population from HWE Occurred?
Random mating Nonrandom mating Allelles do not Change in genotype No
assort randomly frequencies
No selection Selection Certain allelles are Change in allelle Yes
selected for or frequencies
against
No mutation Mutation Addition of new Change in allelle Yes
allelles frequencies
No migration Immigration or Individuals carry Change in allelle Yes
emigration allelles into, or out frequencies
of, the population
Large population Small population Loss of allelle Change in allelle Yes
(no genetic drift) (genetic drift) diversity; some frequencies
1. bottleneck effect allelles may
2. founder effect disappear
27.4 Processes of Evolution
Five Agents of Evolutionary Change.
There are five theoretical conditions for a
population to be in genetic equilibrium.
The opposite of these conditions can cause
evolutionary change.
They include mutations, genetic drift, gene flow,
nonrandom mating, and natural selection.
Mutations
New mutations can cause allele frequencies in a
population to change.
Mutations are genetic changes that are the only
source of new variation in a population.
Without mutations, there would be no new inheritable
genetic diversity.
Mutations are random events.
A mutation does not arise because the organism “needs” one.
Some are beneficial (provide a survival advantage), and
some are harmful.
Genetic Drift 1

Genetic drift is a change in allele
frequencies of a gene pool due to random
meeting of gametes in fertilization.
The random selection and assortment of
gametes in a population causes allele
frequencies to shift in each generation.
Genetic drift has greater effects in smaller
populations due to fewer gametes assorting.
Removal of gametes from a smaller
population can affect allele frequencies in
the next generation.
Example: the death of one individual in
a population of 10 could change the
frequency of an allele by 10% or cause
its loss altogether.
Genetic Drift 3

In nature, the bottleneck effect and
founder effect occur when populations are
drastically reduced in size.
The bottleneck effect occurs
following a natural disaster that kills a
large proportion of a population.
A severe reduction in the gene pool
that can affect allele frequencies.
The founder effect occurs when a few
individuals form a new colony and their
collective genes represent only a
fraction of the original gene pool.
Gene Flow
Gene flow is the movement of alleles
between populations.
Individuals or their gametes migrate from one
population to another and breed in the new
population.
Gene flow mixes genetic diversity.
Gene flow also keeps the gene pools of two
or more populations similar.
Nonrandom Mating
Nonrandom mating occurs when individuals are
selective about choosing a mate with a preferred
trait.
Random mating is never observed in natural
populations, because most sexually reproducing
organisms select mates based on some trait.
Inbreeding, mating between close relatives, is an
example of nonrandom mating.
Increases proportion of homozygotes.
Increases frequency of recessive abnormalities in
humans.
Natural Selection 1

Natural selection is a process that allows some
individuals with an advantage over others to produce
more offspring.
Charles Darwin explained evolution through natural
selection.
Evolution by natural selection requires the following:
Individual variation.
Inheritance.
Overproduction.
Differential reproductive success.
Natural Selection 2

Fitness is measured by the number of fertile
offspring produced by an individual throughout its
lifetime.
Variations that can contribute to fitness can arise from:
Mutation.
Crossing-over.
Independent assortment.
Random fertilization.

Most traits on which natural selection acts are
polygenic, controlled by more than one gene.
Range of phenotypes follows a bell-shaped curve.
Natural Selection 3

Three main types of natural selection.
Stabilizing selection.
Directional selection.
Disruptive selection.
Natural Selection 4

Stabilizing selection.
Extreme phenotypes are selected against.
Individuals near average phenotype are favored.
Stabilizing selection improves adaptation of the
population to aspects of the environment that
remain constant.
Example: Human infants born with an intermediate
birth weight (3 to 4 kilograms) have a better chance
of survival than those of either extreme.
Small babies do not have fully functional
systems.
Large babies experience difficult deliveries.
Natural Selection 5

Directional selection.
One extreme phenotype is favored.
The distribution curve shifts in that direction.
Directional selection can occur when the population is
adjusting to a changing environment.
Example: When bacteria are exposed to an antibiotic,
most are susceptible and die, but some are resistant and
survive to reproduce.
In subsequent generations, antibiotic-resistant bacteria continue
to reproduce, and the antibiotic resistance allele becomes more
prevalent.
Directional Selection
Natural Selection 6

Disruptive selection.
Two or more extreme phenotypes are favored.
Two different habitats could result in two different
phenotypes in the population.
British land snails with dark shells are more prevalent
in forested areas.
Snails with light, banded shells are more common in
areas of low-lying vegetation.
Disruptive Selection

(b) (left): ©NHPA/Superstock; (right): ©W. Layer/ Blickwinkel/age
27.5 Macroevolution and
Speciation1

Macroevolution—evolution on a large scale.
Macroevolution includes the history of life on Earth.
Macroevolution involves speciation (splitting of one
species into two or more).
Speciation is governed by the same microevolutionary agents
that are in play in populations.
Thus, microevolution and macroevolution are the results
of the same agents, differing only in scale.
Macroevolution is caused by the accumulation of
microevolutionary change that results in new species.
27.5 Macroevolution and
Speciation2

Species.
A species is defined as a group of organisms
capable of interbreeding and are isolated
reproductively from other species.
Under the biological species concept, if
organisms cannot mate and produce fertile
offspring in nature, they are defined as different
species.
Mechanisms exist to reproductively isolate
similar species.
27.5 Macroevolution and
Speciation3

Reproductive isolating mechanisms.
Prezygotic isolating mechanisms.
In place before fertilization.
No attempt at reproduction.
Postzygotic isolating mechanisms.
In place after fertilization.
Reproduction may take place, but no fertile offspring
produced.