Transcript Speciation - Hazlet.org

SPECIATION
How Populations Evolve
What is a Species?

A species is often defined as a group of individuals that
actually or potentially interbreed in nature. A species is
the biggest gene pool possible under natural conditions.

Scientists group organisms according to their similarities.

The most similar organisms belong to a species.

Members of the same species can mate and produce
fertile offspring.


Ex: Humans belong to the species Homo sapiens.
Subspecies- Populations of the same species differ
genetically from each other
How Do New Species Evolve?
 Speciation
is a lineage-splitting event that
produces two or more separate species.
 Since
being a member of one species is
defined by the ability to successfully
reproduce, speciation (the formation of a
different species) must involve an inability to
successfully reproduce.
How Do New Species Evolve?
A
new species may form when one
population of a species becomes
reproductively isolated from another
population of the same species.
 Over
time, evolutionary mechanisms occur
that alter the gene pool of the isolated
population so that it is no longer
reproductively compatible with the original
population.
Reproductive Isolation

How does reproductive isolation occur?
 Temporal
isolation: Species reproduce in
different seasons or at different times of the
day.
 Geographical
isolation: Physical barriers
(rivers, oceans, mountains) prevent the
mixing of populations.
 Behavioral
isolation: Species differ in their
mating rituals (e.g. differing bird songs,
mating colors, dances, pheromones).
Models of Evolution
•
There are two scientific theories regarding how
evolution occurs.
–
Punctuated equilibrium: This theory proposes that
throughout geological time, biological species go
through long periods of little change and then
have brief periods of rapid change.
–
Gradualism: This theory proposes that throughout
geological time, biological species gradually
undergo changes that leads to speciation.
Mechanisms of Microevolution
 There
are a few basic ways in which
microevolutionary change happens.




Mutation
Nonrandom mating
Genetic drift
Gene flow
 These
are all processes that can directly affect
gene frequencies in a population.
Mutation
 An
alteration in the genetic material (the
genome) of a cell of a living organism or of a
virus that is more or less permanent and that
can be transmitted to the cell’s or the virus’s
descendants

Mutations result either from accidents during
the normal chemical transactions of DNA,
often during replication, or from exposure to
high-energy electromagnetic radiation or to
highly reactive chemicals in the environment.
Mutation
 Because
mutations are random changes,
they are expected to be mostly harmful,
but some may be beneficial in certain
environments.
 In
general, mutation is the main source of
genetic variation, which is the raw
material for evolution by natural selection.
Nonrandom Mating
 Occurs
when the probability that two
individuals in a population will mate is not the
same for all possible pairs of individuals
 Nonrandom
mating can take two forms:

Inbreeding - Individuals are more likely to mate
with close relatives (e.g. their neighbors) than
with distant relatives.

Outbreeding - Individuals are more likely to mate
with distant relatives than with close relatives. This
is less common.
Gene Flow and Genetic Drift
 Gene

Flow
Flow of alleles
 Emigration
 Genetic
and immigration of individuals
Drift

Random change in allele frequencies over
generations brought about by chance

In the absence of other forces, drift leads to
loss of genetic diversity

Elephant seals, cheetahs