OpenStax Biology 2e Chapter 18: Evolution and Origin of Species PDF

Summary

This PowerPoint presentation covers Chapter 18: Evolution and the Origin of Species from OpenStax Biology 2e. It discusses key concepts like natural selection, Darwin's observations, and evidence for evolution. Includes various diagrams and figures supporting the concepts.

Full Transcript

BIOLOGY 2E
Chapter 18 EVOLUTION AND THE ORIGIN OF SPECIES
PowerPoint Image Slideshow

This work is licensed under a
Creative Commons Attribution
-NonCommercial-ShareAlike
4.0 International License.
DARWIN AND NATURAL SELECTION
Charles Darwin and the H.M.S. Beagle
Natural selection
Darwin’s postulates:
Most characteristics are heritable, passed from
parent to offspring
More offspring are produced than can survive;
there is competition for resources
Characteristics of offspring vary, and these
variations are heritable.
Adaptation
DARWIN’S OBSERVATION

Darwin observed that beak shape varies among finch species. He
postulated that the beak of an ancestral species had adapted over
time to equip the finches to acquire different food sources.
 DARWIN AND WALLACE

Both Charles Darwin and Alfred Wallace wrote
scientific papers on natural selection that were
presented together before the Linnean Society in
1858.
OVERVIEW: EVIDENCE OF EVOLUTION

Divergent evolution vs convergent evolution
Fossil record
Homologous structures
Vestigial structures
Biogeography
Molecular Biology
NATURAL VERSUS ARTIFICIAL SELECTION

Our focus here is natural selection.
Artificial selection occurs as well.
a) Humans have been doing this for thousands of
years
a) Crops
b) Domesticated animals
b) We have chosen the phenotypes we want and breed
those individuals, as well as creating more ideal hybrids
and breeds – selective breeding
c) Notably, in Darwin’s Origin of Species, he first draws
attention to artificial selection (e.g. animal husbandry)
before going in depth into natural selection.
HOMOLOGOUS STRUCTURES

The similar construction of these appendages indicates
that these organisms share a common ancestor.
CONVERGENCE

The white winter coat of the arctic fox and the ptarmigan’s plumage are adaptations
to their environments. (credit a: modification of work by Keith Morehouse)
These similarities occur not because of common ancestry,
but because of similar selection pressures—the benefits of
predators not seeing them.
Independently, similar phenotypes will evolve in distantly
related species due to the same evolutionary pressures.
BIOGEOGRAPHY

Development and presence of species based
on location. For example:
Groups that evolved before Pangea broke up
are distributed worldwide (albeit in different
species)
Groups that developed after the breakup appear
only in certain regions/continents (e.g.
Australian marsupials and Madagascar lemurs)
Also evident (but usually less diverse) when
species are separated by mountain ranges,
large rivers, or other physical barriers.
MOLECULAR BIOLOGY

DNA analysis (a more recent discovery)
supports evolution
Closely related organisms have similar
DNA
Evolution of new functions for proteins
after mutations
MISCONCEPTIONS OF EVOLUTION

Evolution is just a theory
Individuals evolve
Evolution explains the origin of life
Organisms evolved on purpose
FORMATION OF NEW SPECIES

Species: a group of organisms that can
interbreed and produce viable, fertile offspring
Hybrid: a cross between two species
Gene pool: a collection of all the variants of
genes in a species
SPECIATION
Allopatric speciation – involves geographic isolation
Dispersal
Vicarience
Adaptive radiation
Sympatric speciation – occurs in the same geographical area
Chromosomal errors in cell division
Aneuploidy
Autopolyploidy
Allopolyploidy
Reproductive isolation
Prezygotic vs postzygotic barriers
Temporal Isolation
Habitat isolation
Behavioral isolation
SPECIATION

The only illustration in Darwin's On the Origin of Species: a diagram
showing speciation events leading to biological diversity. The diagram
shows similarities to phylogenetic charts that are drawn today to illustrate
the relationships of species.
Modern elephants evolved from the Palaeomastodon, a species that lived
in Egypt 35–50 million years ago.
ALLOPATRIC SPECIATION

The northern spotted owl and
the Mexican spotted owl inhabit
geographically separate
locations with different climates
and ecosystems.

The owl is an example of
incipient speciation. (credit
“northern spotted owl”:
modification of work by John and
Karen Hollingsworth; credit
“Mexican spotted owl”:
modification of work by Bill
Radke)
 ALLOPATRIC SPECIATION

Speciation can occur
a) When groups become isolated geographically for
long period of time
b) Changes (mutations) in each group over time lead
to the groups no longer being reproductively
compatible

Note: Sometimes gene flow reoccurs in an area when something that is
isolating 2 groups is removed.

Dispersal is when a few members of a species move to a
new geographical area,
Vicariance is when a natural situation arises to physically
divide organisms.
ADAPTIVE RADIATION

The honeycreeper birds
illustrate adaptive
radiation. From one
original species of bird,
multiple others evolved,
each with its own
distinctive
characteristics.
SYMPATRIC SPECIATION

Speciation within the same physical location and
conditions.
Arises from errors in chromosomes during cell
division.
Aneuploidy: Two few chromosomes
Autopolyploidy: Two or more complete sets of
chromosomes after division. Results from error in
meiosis.
Allopolyploid: Gametes from two different species
combine.
SYMPATRIC SPECIATION

Aneuploidy results when the gametes have too many or too few
chromosomes due to nondisjunction during meiosis. In the example
shown here, the resulting offspring will have 2n+1 or 2n-1 chromosomes
SYMPATRIC SPECIATION

Autopolyploidy results when mitosis is not followed by cytokinesis.
 SYMPATRIC SPECIATION

Alloploidy results when two species mate to produce viable offspring. In
the example shown, a normal gamete from one species fuses with a
polyploidy gamete from another. Two matings are necessary to produce
viable offspring.
 REPRODUCTIVE ISOLATION
Prezygotic:
Temporal isolation – species have different breeding
schedules
Habitat isolation – members of species move or are
otherwise separated.
Behaviorial isolation – certain actions or behaviors (or the
lack of them) impacts reproduction

Postzygotic
Hybrid inviability – an embryo is produced, but cannot
survive development
Hybrid sterility – different species can produce a viable
offspring, but that offspring cannot reproduce
TEMPORAL ISOLATION

These two related frog species exhibit temporal reproductive isolation.
(a) Rana aurora breeds earlier in the year than (b) Rana boylii.

(credit a: modification of work by Mark R. Jennings, USFWS; credit b: modification of work by
Alessandro Catenazzi)
HABITAT ISOLATION

Speciation can occur when two populations occupy different habitats. The habitats need
not be far apart. The cricket (a) Gryllus pennsylvanicus prefers sandy soil, and the
cricket (b) Gryllus firmus prefers loamy soil. The two species can live in close proximity,
but because of their different soil preferences, they became genetically isolated.
GAMETIC BARRIER

The shape of the male reproductive organ varies among male
damselfly species, and is only compatible with the female of that
species. Reproductive organ incompatibility keeps the species
reproductively isolated.
GAMETIC BARRIER

Some flowers have evolved to attract certain pollinators. The (a) wide foxglove flower is
adapted for pollination by bees, while the (b) long, tube-shaped trumpet creeper flower
is adapted for pollination by humming birds.
RECONNECTION

Hybrid zones: area where two closely related
species interact and interbreed
Reinforcement: process where hybrids are less
fit, and thus there is a nudge towards further
divergence between the two species
HYBRID ZONE

After speciation has occurred, the two separate but closely related
species may continue to produce offspring in an area called the
hybrid zone. Reinforcement, fusion, or stability may result, depending
on reproductive barriers and the relative fitness of the hybrids.
RATES OF SPECIATION

Gradual speciation: species diverge gradually through time with
small steps
Punctuated equilibrium: species exhibit a large change in a
relatively short period of time followed by long periods of stasis
RATES OF SPECIATION

In (a) gradual speciation, species diverge at a slow, steady pace as
traits change incrementally. In (b) punctuated equilibrium, species
diverge quickly and then remain unchanged for long periods of time.