14 - Genetic Variation in Individuals and Populations II.pptx.pdf

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Dr. Akhobadze Madona

Genetic Variation in
Individuals and
Populations: Mutation and
Polymorphism (II)

2024
 Content: Inherited Variation And Polymorphism In Proteins, Genotypes And
Phenotypes In Populations, The Hardy-Weinberg Law, Factors That Disturb
Hardy-Weinberg Equilibrium, Ethnic Differences In The Frequency Of Various
Genetic Diseases

Reading: Ch. 9 - Thompson & Thompson Genetics in Medicine, Robert L.
Nussbaum, Roderick R. McInnes, 9th Edition
Ch. 8 - Emery’s elements of medical genetics, 14th edition
INHERITED VARIATION AND POLYMORPHISM IN
PROTEINS

any one individual is likely Population genetics is the quantitative study of
to be heterozygous for the distribution of genetic variation in populations
alleles determining and of how the frequencies of genes and genotypes
structurally different are maintained
polypeptides at or change over time both within and between
approximately 20% of all populations.
loci

when individuals from
different ethnic groups are
compared, an even greater
fraction of proteins has
been found to exhibit
detectable polymorphism
BIOCHEMICAL INDIVIDUALITY

striking degree of biochemical
individuality exists within the
human species in its makeup of
enzymes and other gene products

each individual, regardless of his or
her state of health, has a unique,
genetically determined chemical
makeup and thus responds in a
unique manner to environmental,
dietary, and pharmacological
influences
GENOTYPES AND PHENOTYPES IN POPULATIONS

Population genetics is concerned
both with
genetic factors - as mutation and
reproduction
environmental and societal
factors - selection and migration
together determine the frequency
and distribution of alleles and
genotypes in families and
communities
GENETIC FACTORS IN HUMAN IMMUNODEFICIENCY VIRUS RESISTANCE
Gene CCR5, which encodes a cell
surface cytokine receptor that serves
as an entry point for certain strains of
the human immunodeficiency virus
(HIV) that causes the acquired
immunodeficiency syndrome (AIDS)
32– base pair deletion in this gene
results in an allele (DCCR5) that
encodes a nonfunctional protein due
to a frameshift and premature
termination
Individuals homozygous for the
DCCR5 allele do not express the
receptor on their cell surface and are
resistant to HIV infection
Loss of function of CCR5 appears to
be a benign trait
when we refer to the population frequency of an allele, we are
considering a hypothetical gene pool as a collection of all the alleles at
a particular locus for the entire population
 The Hardy-Weinberg Law
Geoffrey Hardy- English mathematician
Wilhelm Weinberg - German physician
- in 1908
calculating genotype frequencies from
allele frequencies
p is the frequency of allele A
q is the frequency of allele a in the
gene
The chance of AA genotype is p2
aa genotype is q2
Aa genotype is 2pq
The Hardy-Weinberg law rests on these assumptions:

The population is large and matings are
random with respect to the locus in question
Allele frequencies remain constant over time
because:
There is no appreciable rate of mutation.
Individuals with all genotypes are equally
capable of mating and passing on their
genes, that is, there is no selection against
any particular genotype
There has been no significant immigration of
individuals from a population with allele
frequencies very different from the
endogenous population
The Hardy-Weinberg Law
the frequency of the three genotypes AA, Aa, and aa is given by
the terms of the binomial expansion
(p + q)2 = p2 + 2pq + q2
population genotype frequencies from generation to generation
will remain constant, at equilibrium, if the allele frequencies p and
q remain constant
p2 : 2pq : q2
647 : 134 : 7
(p + q)n, p and q represent the frequencies of two alternative
alleles at a locus
p + q = 1 and n = 2
If a locus has three Alleles (p + q + r)2
Frequencies of Mating Types and Offspring for a
Population in Hardy-Weinberg Equilibrium with
Parental Genotypes in the Proportion p2 : 2pq : q2
THE HARDY-WEINBERG LAW IN AUTOSOMAL
RECESSIVE DISEASE
genetic counseling for autosomal recessive disorders such
as phenylketonuria (PKU)
Heterozygotes are asymptomatic silent carriers, and their
population incidence is impossible to measure directly from
the phenotype

the frequency of PKU is approximately 1/4500 in Ireland
Then the frequency of affected individuals = 1/4500 = q2
q = 0.015, and 2pq = 0.029 or approximately 3%
carrier frequency in the Irish population is 3%
The Hardy-Weinberg Law in X-Linked
Disease
there are only two possible male genotypes but three female
genotypes
red-green color blindness, caused by mutations in the series of red
and green visual pigment genes on the X chromosome
symbol cb for all the mutant colorblindness alleles and the symbol +
for the normal allele, with frequencies q and p
 FACTORS THAT DISTURB
HARD-YWEINBERG EQUILIBRIUM

1. population is large and mating is random - very small population
in which random events can radically alter an allele frequency may
not meet this assumption, also when the population contains
subgroups whose members choose to marry within their own
subgroup
2. allele frequencies are not changing over time, no migration
large deviations from the frequency of individuals homozygous for
an autosomal recessive condition
changes in allele frequency due to mutation, selection, or migration
usually cause more minor and subtle deviations from
Hardy-Weinberg equilibrium compared to nonrandom mating
Exception to Large Population with Random Mating

Stratification - population in
which there are a number of
subgroups that have remained
relatively genetically separate
during modern times (the U.S.)
African American population of
the United States and the mutant
allele at the β-globin locus
responsible for sickle cell
disease
has no effect on the frequency of
autosomal dominant disease,
only a minor effect on the
frequency of X-linked disease
Exception to Large
Population with Random
Mating

Assortative mating - choice
of a mate because the
mate possesses some
particular trait
achondroplasia -
autosomal dominant
disorder, homozygous
offspring will have a severe,
lethal form of dwarfism
Exception to Large Population with Random Mating

Consanguinity - increase in
the frequency of
autosomal recessive
disease
in genetic isolates, the
chance of mating with
another carrier is as high as
that observed in cousin
marriages, a phenomenon
known as inbreeding
(Tay-Sachs disease in
Ashkenazi Jews)
Exceptions to Constant Allele Frequencies

Genetic Drift in Small
Populations -
increased fertility or
survival of the carriers
of a mutation,
occurring for reasons
unrelated to carrying
the mutant allele,
allele frequencies can
fluctuate from
generation to
generation by chance
Exceptions to Constant Allele
Frequencies

Mutation and Selection - new
mutation would have little effect in
the short term on allele frequencies.
Whether an allele is transmitted to
the succeeding generation depends
on its fitness (f), which is a measure
of the number of offspring of
affected persons who survive to
reproductive age.
Fitness is the outcome of the joint
effects of survival and fertility
Coefficient of selection (s),
which is a measure of the
loss of fitness and is defined
as 1 − f, that is, the
proportion of mutant alleles
that are not passed on and
are therefore lost as a result
of selection
When a genetic disorder
limits reproduction so
severely that the fitness is
zero (s = 1), it is referred to
as a genetic lethal
 Positive Selection for Heterozygotes
(Heterozygote Advantage)

heterozygotes for some diseases
have increased fitness not only over
homozygotes for the mutant allele
but also over homozygotes for the
normal allele
heterozygotes greatly outnumber
homozygotes in the population
situation in which selective forces
operate both to maintain a
deleterious allele and to remove it
from the gene pool is described as a
balanced polymorphism
MIGRATION AND GENE FLOW

Migration can change allele
frequency by the process of gene
flow, defined as the slow
diffusion of genes across a
barrier
term migrant is used here in the
broad sense of crossing a
reproductive barrier, which may
be racial, ethnic, or cultural and
not necessarily geographical and
requiring physical movement
from one region to another
A number of factors are thought to
allow differences in alleles and allele
frequencies among ethnic groups to
develop
Two such factors are genetic drift,
including nonrandom distribution of
alleles among the individuals who
founded particular subpopulations
(founder effect) and
heterozygote advantage under
environmental conditions that favor
the reproductive fitness of carriers of
deleterious mutations.
GENETIC DRIFT
explain a high frequency of a deleterious
disease allele in a population
When a new mutation occurs in a small
population, its frequency is represented by only
one copy among all the copies of that gene in
the population
GENETIC DRIFT
Random effects of environment
or other chance occurrences
that are independent of the
genotype and operating in a
small population can produce
significant changes in the
frequency of the disease allele
These changes are likely to
smooth out as the population
increases in size. In contrast to
gene flow, in which allele
frequencies change because of
admixture
FOUNDER EFFECT

When a small subpopulation
breaks off from a larger
population, the gene
frequencies in the small
population may be different
from those of the population
from which it originated
because the new group contains
a small, random sample of the
parent group and, by chance,
may not have the same gene
frequencies as the parent group
 The population of Finland
long isolated genetically by geography,
language, and culture, has expanded in
the past 300 years from 400,000 to about
5 million
Choroideremia - X-linked degenerative
eye disease, very rare worldwide; only
about 400 cases
Fully one third of the total number of
patients are from a small region in
Finland, populated by a large extended
family descended from a founding
couple born in the 1640s
Old Order Amish
religious isolate of European descent
that settled in Pennsylvania and
gave rise to a number of small,
genetically isolated subpopulations
throughout the United States and
Canada
have large families and a high
frequency of consanguineous
marriage
specific rare autosomal recessive
syndromes such as the Ellisvan
Creveld syndrome of short-limbed
dwarfism, polydactyly, abnormal
nails and teeth, and high incidence
of congenital heart defects
 The French-Canadian population of Canada

Hereditary type I tyrosinemia
autosomal recessive condition
causes hepatic failure and renal
tubular dysfunction due to deficiency
of fumarylacetoacetase, an enzyme
in the degradative pathway of
tyrosine
hyperornithinemia with gyrate atrophy of the choroid and
retina - autosomal recessive condition caused by
deficiency of ornithine aminotransferase and leading to
loss of vision in young adulthood
ETHNIC DIFFERENCES IN THE FREQUENCY OF
VARIOUS GENETIC DISEASES
The human species of more than 8 billion
members are separated into many
subpopulations, or ethnic groups,
distinguishable by appearance,
geographical origin, and history
ancestry informative markers (AIMs)
25,000 genes and their location and
order on the chromosomes are nearly
identical in all humans, extensive
polymorphism exists between individuals
in a population
Most variation is found in all human
populations, at similar frequencies
CHEMICAL INDIVIDUALITY

British physician - Archibald Garrod

ABO and Rh blood groups important in
determining compatibility for blood
transfusions
The major histocompatibility complex
(MHC) that plays an important role in
transplantation medicine
the variant protein products of various
polymorphic alleles are often what is
responsible for different phenotypes and
likely to dictate how genetic variation at
a locus affects the interaction between
an individual and the environment.
BLOOD GROUPS AND THEIR POLYMORPHISMS

The first instances of genetically
determined protein variation were
detected in antigens found in blood, the
so-called blood group antigens
Numerous polymorphisms are known
to exist in the components of human
blood, especially in the ABO and Rh
antigens of red blood cells.
the ABO and Rh systems are important
in blood transfusion, tissue and organ
transplantation, and hemolytic disease
of the newborn
THE ABO SYSTEM
Human blood can be
assigned to one of four
types according to the
presence on the surface of
red blood cells of two
antigens
A and B
the presence in the plasma
of the two corresponding
antibodies
anti-A and anti-B
THE ABO SYSTEM
four major phenotypes: O, A, B, and AB
Type A persons have antigen A on their red blood cells
type B persons have antigen B
type AB persons have both antigens A and B
type O persons have neither
THE ABO SYSTEM

reciprocal relationship, in an
individual, between the antigens
present on the red blood cells and
the antibodies in the serum
When the red blood cells lack
antigen A, the serum contains
anti-A
when the cells lack antigen B, the
serum contains anti-B
The reason is uncertain, but
formation of anti-A and anti-B is
believed to be a response to the
natural occurrence of A-like and
B-like antigens in the environment
THE ABO SYSTEM
determined by a locus on
chromosome 9
multiallelism in which three
alleles, two of which (A and B)
are inherited as a codominant
trait and the third of which
(O) is inherited as a recessive
trait, determine four
phenotypes.
The A and B antigens are
made by the action of the A
and B alleles on a red blood
cell surface glycoprotein
called H antigen
THE ABO SYSTEM
B allele codes for a glycosyltransferase
that preferentially recognizes the sugar
d-galactose and adds it to the end of an
oligosaccharide chain contained in the H
antigen - creating the B antigen
A allele preferentially recognizes
N-acetylgalactosamine instead of
d-galactose and adds
N-acetylgalactosamine to the precursor -
creating the A antigen
O codes for a mutant version of the
transferase that lacks transferase activity
and does not detectably affect H
substance at all
THE O ALLELE

has a single–base pair deletion in the
ABO gene coding region, which
causes a frameshift mutation that
eliminates the transferase activity in
type O individuals

ABO blood group typing is being
performed directly at the genotype
rather than at the phenotype level,
especially when there are technical
difficulties in serological analysis, as
is often the case in forensic
investigations or paternity testing
MEDICAL IMPORTANCE OF THE ABO

blood transfusion and tissue or organ
transplantation
compatible and incompatible combinations
Compatible combination - the red blood cells of a
donor do not carry an A or a B antigen that
corresponds to the antibodies in the recipient’s
serum.
theoretically there are universal donors (group O)
and universal recipients (group AB),
patient is given blood of his or her own ABO group,
except in emergencies
presence of anti-A and anti-B explains the failure of
many of the early attempts to transfuse blood
antibodies can cause immediate destruction of
ABO-incompatible cells
THE RH SYSTEM

hemolytic disease of the newborn and in
transfusion incompatibilities
comes from Rhesus monkeys that were used in
the experiments that led to the discovery of the
system
the population is separated into:
Rh-positive individuals - who express, on their
red blood cells, the antigen Rh D - polypeptide
encoded by a gene (RHD) on chromosome 1,
Rh-negative individuals - who do not express
this antigen
THE RH SYSTEM

The Rh-negative phenotype
usually originates from
homozygosity for a
nonfunctional allele of the
RH-D gene
frequency of Rh-negative
individuals varies enormously
in different ethnic groups
17% of whites and 7% of
African Americans are
Rh-negative, whereas the
frequency among Japanese is
0.5%
HEMOLYTIC DISEASE OF THE NEWBORN
Rh-negative persons can readily form
anti-Rh antibodies after exposure to
Rh-positive red blood cells
when an Rh-negative pregnant woman
is carrying an Rh-positive fetus
Normally during pregnancy, small
amounts of fetal blood cross the
placental barrier and reach the
maternal blood stream
If the mother is Rh-negative and the
fetus Rh-positive, the mother will form
antibodies that return to the fetal
circulation and damage the fetal red
blood cells, causing hemolytic disease of
the newborn
IN PREGNANT RH-NEGATIVE WOMEN

the risk of immunization by Rh-positive fetal red
blood cells can be minimized with an injection of
Rh immuneglobulin at 28 to 32 weeks of gestation
and again after pregnancy
Rh immunoglobulin serves to clear any
Rh-positive fetal cells from the mother’s
circulation before she is sensitized
Rh immune globulin is also given after
miscarriage, termination of pregnancy, or invasive
procedures such as chorionic villus sampling or
amniocentesis
preventive measure - routine practice in
obstetrical medicine
The Major Histocompatibility Complex
MHC is composed of a large cluster of genes
located on the short arm of chromosome 6
Three classes:
the class I and class II genes, correspond to the human
leukocyte antigen (HLA) genes
Discovered by virtue of their importance in tissue
transplantation between unrelated individuals
encode cell surface proteins that play a critical role in the
initiation of an immune response and specifically in the
“presentation” of antigen to lymphocytes
cannot recognize and respond to an antigen unless it is
complexed with an HLA molecule on the surface of an
antigen-presenting cell
The interaction between
MHC class I and class II
molecules, foreign
proteins, and T-cell
receptors.
The class I - HLA-A, HLA-B, and HLA-C

encode proteins that are an integral part of the plasma
membrane of all nucleated cells
consists of two polypeptide subunits, a variable heavy chain
encoded within the MHC
nonpolymorphic polypeptide, β2-microglobulin, that is
encoded by a gene outside the MHC, chromosome 15
Peptides derived from intracellular proteins are generated
by proteolytic degradation by a large multifunctional
protease
transported to the cell surface and held in a cleft formed in
the class I molecule to display the peptide antigen to
cytotoxic T cells
The class II - HLA-DP, HLA-DQ, and HLA-DR

encode integral membrane cell surface proteins
heterodimer, composed of α and β subunits, both of which are
encoded by the MHC
present peptides derived from extracellular proteins that had been
taken up into lysosomes and processed into peptides for
presentation to T cells
Other gene loci are functionally unrelated to the HLA class I and
class II genes and do not function to determine histocompatibility
or immune responsiveness.
Some are associated with diseases, such as congenital adrenal
hyperplasia caused by deficiency of 21-hydroxylase, and
hemochromatosis, a liver disease caused by iron overload
 HLA and
Disease Association
Ankylosing Spondylitis
chronic inflammatory disease of the
spine and sacroiliac joints
risk of developing ankylosing
spondylitis is at least 150 times
higher for people who have HLA-B27
than for those who do not
Less than 5% of B27-positive
individuals develop the disease,
20% of B27-positive individuals may
have subtle, subclinical
manifestations of the disease
without any symptoms or disability
BONE MARROW TRANSPLANTATION
not only can the host reject the graft, but also
the graft, which contains immunocompetent
lymphocytes, can attack the host in what is
known as graft-versus-host disease (GVHD)
Survival out to 8 years after bone marrow
transplantation for patients with chronic
myelogenous leukemia following chemotherapy
is 60% if graft
host mismatch at no more than one class I or
class II locus but falls to 25% when there are
both class I and class II mismatches
GVHD is also less frequent and severe the better
the class I match.
 HLA and Disease Association
Congenital adrenal hyperplasia
Autosomal recessive disorders
Due to 21-hydroxylase deficiency
Primary hemochromatosis
result from mutations in genes that
lie within the MHC

Affecting such critical processes
as immunity against infections
and self-tolerance to prevent
autoimmunity
HLA and Tissue
Transplantation
determinants of transplant
tolerance and graft rejection
monozygotic twins, can
provide a 100% transplantation
success rate without
immunosuppressive therapy
surviving after 10 years when
the recipient and the donor are
HLA-identical siblings is 72%
but falls to 56% when the donor
is a sibling who has only one
HLA haplotype in common with
the recipient
გმადლობთ, ყურადღებისთვის!!!