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Transcript
Random Events
There is a random element
involved in the frequency of
genes in one generation
when compared to the
previous generation.
Genetic Drift: a random change in the
genetic makeup of a population that may
arise when the population is restricted in
size.
“Drift” is directionless.
Compare to tossing a coin.
Research Randomizer: Instant Random
Sampling and Random Assignment
In Florida, the greenhouse
frog Eleutherodactylus
planirostris occurs in two
pigment patterns, mottled and
striped. Why?
The theory of genetic drift was
developed in the 1930s by Sewall
Wright, and is sometimes referred
to as the Sewall Wright effect.
Consider a mathematical example. If
two Aa frogs have only two offspring,
there is a 1/16 chance of the a gene (or
the A gene, for that matter) gene being
lost after the first generation.
Random sampling is more effective at creating
variations in small populations than in large ones.
Results from the Dobzhansky experiment with
Drosophila populations.
Founder effect:
unique gene
frequencies arising
in small groups of
individuals that
migrate away from
a large population.
The chance that a
founder population
will be homozygous
depends on the
number of founders
and the gene
frequencies.
One type of founder effect occurs
when a new population is
established by a very few
individuals. The most extreme case
would be that in which the “founder”
was a single pregnant female. Much
of the genetic diversity of the parent
population would be lost.
The ~300 inhabitants
of Tristan da Cunha
are descended from
20 or so 19th Century
immigrants.
Native Americans provide a possible example.
Most North American tribes lack the gene
governing type B blood. However, that gene is
widespread in Mongolia, their ancestral home.
The group that migrated across the Bering Strait
may have been small, and lacked this gene.
Native American
populations also show
a high incidence of
albinism. Can this
also be attributed to
founder effects?
Another type of founder effect occurs
when a large, established population is
reduced in size. The remaining
individuals may not be representative
of the genetic diversity that was
present in the original population. This
is referred to as a genetic bottleneck.
If a population passes through a “bottleneck”, the
amount of genetic diversity may be greatly
lowered.
The drift to
homozygosity.
Over time, the
population must
drift to become
made up of the
descendants of
only one gene
from an ancestral
population. Any
one gene has a
1/2N chance of
eventual fixation
by random drift.
In small populations, Hardy-Weinberg
equilibrium is not reached until they reach
homozygosity.
Homozygosity is the
result in any small
population without
mutation.
In human populations, religious
isolates offer one of the best
opportunities to witness genetic drift.
The Dunkers, of eastern Pennsylvania
are descended from Old German
Baptist Brethren who came to the U.S.
in the early 18th century. They have
remained genetically isolated by rigid
marriage customs.
Bentley Glass compared certain
genetic traits of the Dunkers to the
surrounding population, and to their
parent population in Germany.
His group looked at:
ABO blood groups
MN blood types
Rh Blood types
Four external features:
Ear lobes
Handedness
Mid-digital hair
Hitch-hikers thumb
The same
phenomenon can
be seen in the
Amish sects of
Pennsylvania and
Ohio.
Eight family names account for 80% of the
Amish families in Lancaster County, PA.
The high degree of consanguinuity has
led to a high frequency of recessive
genetic disorders. Among them are Ellisvan Creveld syndrome, pyruvate kinase
deficient hemolytic anemia, Hemophilia
B, and Troyer syndrome (a form of
muscular dystrophy).
Genetic drift is
responsible for the
introduction of Rh
disease into China. 70
years ago, all Chinese
women were Rh
positive (RR).
Intermarriage between
immigrant Americans
has introduced the Rhnegative (r) allele into
the population.
Since the beginning of the slave trade
some 250 years ago, there has been
roughly a 20% Caucasian contribution to
the African American gene pool.
A specific blood group gene known as
the Duffy factor is virtually absent from
West African populations from which
most of the original slaves were derived.
Its frequency in native West Africans,
African Americans, and American
Caucasians has been studied.
It appears that various
African American
populations derive
between 4% and 26%
of their genes from
Caucasian ancestry,
introduced since
~1700.