BCH I Patterns of Single Gene Inheritance Molecular and Biochemical Basis of Genetics Diseases PDF

Summary

This document presents an overview of single-gene disorders, including inheritance patterns and non-Mendelian mechanisms. It details how genes are inherited, types of genetic variations, and their impact on human diseases.

Full Transcript

Single-gene
disorders

Murad Odeh PhD
Associate Professor
Objectives
Describe how genes are inherited, the types and extent of genetic variation seen
in the human genome, and how these variations affect disease states and the
diversity of normal variation.
Obtain a family history and draw and interpret a pedigree.
Perform pedigree analysis and identify the inheritance patterns
Explain and identify non-Mendelian mechanisms: reduced penetrance, variable
expressivity, uniparental disomy, epigenetics, mosaicism, genomic imprinting, and
unstable repeat expansion.
SINGLE GENE DISORDERS
Single-Gene Inheritance (Mendelian Inheritance)
Refers to genetic disorders or traits controlled by mutations in a single gene
Follows inheritance patterns described by Gregor Mendel

Characteristic Patterns of Transmission
Each inheritance type has a specific pattern across generations
Knowledge of family history and inheritance type aids in identifying carriers and understanding risk

Mutation Variability:
Even though a single gene primarily causes these diseases, several different mutations can result in the same
disease but with varying degrees of severity and phenotype.

Key Genetic Concepts:
Penetrance: Likelihood that a gene mutation will result in disease expression.
Expressivity: Variation in severity of disease symptoms among individuals with the same gene mutation.
Genetic Testing: Methods like PCR and sequencing to confirm mutation presence and guide diagnosis.
SINGLE GENE DISORDERS
Individual mutant genes cause it. (monogenic)
Present in one chromosome or both.
Frequency as high as 1/500
Affect 0.2% of the population
Incidence in live births is 0.36%
Hospitalized children 6-8%
Includes mitochondrial disorders
PEDIGREE
is a family tree that tracks traits
or conditions through
generations using these symbols
and lines.
Average % DNA Shared
SINGLE GENE DISORDERS PATTERNS OF INHERITANCE
AUTOSOMAL RECESSIVE
Phenylketonuria
Sickle cell anemia
Cystic fibrosis
Bardet-Biedl Syndrome
Spondylothoracic Dysplasia

AUTOSOMAL DOMINANT
Neurofibromatosis type 1
Achondroplasia
Familial hypercholesterolemia
Marfan syndrome
Huntington Disease
X-LINKED
Muscular dystrophy (XLR)
Hemophilia A and B (XLR)
Urea cycle disorders (XLR)
Hypophosphatemic rickets (XLD)
Incontinentia Pigmenti (XLD)
Types of single-gene inheritance patterns, their characteristics, &
examples of disorders
Atypical Patterns
of Inheritance
Atypical Patterns of Inheritance

Pseudo-autosomal inheritance
Myotonic dystrophy 1.Myotonic dystrophy: A single gene disorder caused
Dyschondrosteosis by mutations in the DMPK gene.
Males are often more severely affected by 2.Dyschondrosteosis: A single gene disorder caused by
dyschondrosteosis than females due to
the X-linked inheritance pattern
mutations in the SHOX gene.
3.Fragile X: A single gene disorder caused by mutations
Genomic imprinting in the FMR1 gene.
Fragile X
4.Prader-Willi syndrome: A single gene disorder
Uniparental disomy caused by a lack of expression of paternal genes on
Prader-Willi syndrome chromosome 15.
Somatic mosaicism 5.Neurofibromatosis: A single gene disorder caused by
Neurofibromatosis mutations in the NF1 or NF2 gene.
Germline mosaicism 6.Osteogenesis imperfecta: A single gene disorder
Osteogenesis imperfecta caused by mutations in the COL1A1 or COL1A2 gene.

DMPK: Dystrophia Myotonic Protein Kinase gene
SHOX: Short Stature Homeobox-Containing gene
FMR1: Fragile X Mental Retardation 1 gene
NF1: Neurofibromin 1 gene
 Pseudo-Autosomal Regions (PARs)
PAR1
Located at the distal ends of the short
arms of the X and Y chromosomes
Involved in pairing and recombination
during meiosis
PAR2
Located at the tips of the long arms of
the X and Y chromosomes
Smaller than PAR1
Undergoes recombination during
meiosis
Contains fewer genes compared to PAR1
Recombination in PARs
Allows for exchange of genetic material
between X and Y chromosomes
Ensures proper segregation of
chromosomes during meiosis
Contributes to genetic diversity.
 Differences in Sex-linked Pedigrees
Patterns for Autosomal Dominant
Compared to Autosomal Pedigrees
Inheritance
Sex-linked pedigrees show the inheritance of sex-linked
Males and females are equally likely to have the trait.
traits.
There is male-to-male transmission.
These traits tend to appear more frequently in
Traits do not skip generations (generally).
males than females.
If the trait is displayed in offspring, at least one parent
If a mother has the trait, all her sons should also have it.
must show the trait.
There is no male-to-male transmission of the trait.
The son of a female carrier has a 50 percent chance of
inheriting the trait.
A compound heterozygote
is a person who has two different mutated alleles for a particular gene, one
from each parent, but each allele is a different mutation of the same gene.
Here’s a simple explanation:
Normally, we have two copies of each gene — one from our mother and
one from our father.
In a compound heterozygote, each copy of the gene has a different
mutation (a change in the genetic code) that causes a disorder.
Even though the mutations are different, they can still cause the same
disease because both mutations affect the gene’s ability to work properly.
Comparison of Regular Heterozygosity (Allelic Heterozygosity) and
Compound Heterozygosity in Genetic Inheritance

Allelic heterogeneity two different mutations within the same gene
(same chromosome) causing the same disease.

Loci heterogeneity mutations on two different genes (located on
different chromosomes) also lead to the same disease.
Phenylalanine hydroxylase (PAH)
PAH converts phenylalanine to tyrosine.
Individuals with PAH deficiency, as seen in PKU, have:
Accumulation of phenylalanine in the blood and tissues.
Various neurological symptoms & intellectual disabilities.
Tyrosinase and Albinism
Tyrosinase is involved in melanin production.
Disorders related to tyrosinase include a lack of melanin production characterizes albinism.
Homogentisic acid 1,2-dioxygenase
This enzyme is involved in the degradation of tyrosine and phenylalanine.
Mutations lead to alkaptonuria – Acid accumulation (Dark Urine, Dark connective tissues and joint
problem).
Branched-chain α-keto acid dehydrogenase and Maple Syrup Urine Disease (MSUD)
Involved in the catabolism of branched-chain amino acids (leu, Ile, Val)
Defects in this enzyme are associated with Maple Syrup Urine Disease (MSUD) – increased ketoacids
Neurological symptoms, developmental delays
Monoamine oxidase (MAO) and Neurotransmitter Metabolism
breaks down neurotransmitters such as serotonin, dopamine, and norepinephrine in the brain.
Deficiencies or inhibition can lead to alterations in neurotransmitter levels (psychiatric and
neurological disorders)
Molecular &
Biochemical
Basis of Genetic
Diseases I & II
Murad Odeh, PhD
Associate Professor
Objective

Understanding diseases'
genetic and biochemical
basis is essential to
predicting phenotypes and
their transmission and
designing treatment
strategies.
Diseases discussed
Cystic fibrosis
Sickle cell anemia
Thalassemia
Alpha
Beta
Hyperphenylnemia
Familial hypercholesterolemia
Muscular dystrophy
Osteogenesis imperfecta
Cystic Fibrosis (CF)
 A modifier gene
A gene that influences the expression or severity of a
disease caused by a primary gene mutation.
Does not directly cause the disease, but modifies its
impact.
In cystic fibrosis (CF), modifier genes affect:
Severity of disease symptoms
How intense the symptoms are.
Age of onset
When the symptoms first appear.
Response to treatment
How well the disease responds to medical
interventions.
Common Types of Mutations Causing Cystic Fibrosis
Class I: Protein production mutations
Class II: Protein processing mutations
Class III: Gating mutations
Influence of Modifier Genes on Cystic Fibrosis (CF)
Phenotypes
May modulate the phenotype by:
Acting on the fundamental molecular level.
Providing alternative chloride conductance
Regulating splicing and expression of the CFTR
gene.
LCR enhances the
expression of linked genes
Phenylalanine is an
essential amino
acid.
Relationship Between Apolipoproteins (Apo100
& ApoB-48) and Lipoproteins (LDL-C) in Lipid
Metabolism and Cardiovascular Health

Key Points:
ApoB exists in both ApoB-100 (found in LDL) and ApoB-48
(found in chylomicrons).

✓ ApoB-100 is crucial for LDL-C transport and a marker of
cardiovascular risk.

✓ ApoB-48 is involved in lipid absorption from the intestine
to the liver, and elevated levels can indicate issues with fat
metabolism.

LDL-C carries cholesterol to cells, but excess levels can cause
heart disease
Summary of Cholesterol Transport
and Apolipoproteins
Cholesterol is transported in the bloodstream
by lipoproteins: LDL, HDL, VLDL, and IDL. Each
type has a unique role in cholesterol and
triglyceride transport. Apolipoproteins (ApoB-
100 and ApoB-48) are critical for the structure
and function of these lipoproteins, facilitating
cholesterol metabolism and transport.
Key Processes
1.Absorption: Dietary lipids form chylomicrons
(ApoB-48) in the intestine.
2.Liver Role: Produces VLDL (ApoB-100), which
loses triglycerides to become IDL and LDL.
3.Cellular Uptake: LDL delivers cholesterol to
cells via LDL receptors.
4.Reverse Transport: HDL removes excess
cholesterol, returning it to the liver.
Clinical Implication: Managing LDL-C and
ApoB-100 levels is vital for reducing
cardiovascular risk.
Genetic Mutations Leading to Clearance Impairment and Elevated Cholesterol
Levels:

LDL Receptor Mutations (LDLR):
The LDL receptor removes low-density lipoprotein cholesterol (LDL-C) from the bloodstream.
Mutations in the LDLR gene decrease the ability of cells to clear LDL-C, leading to elevated levels.

Apolipoprotein B Mutations (APOB):
Apolipoprotein B is a component of LDL particles.
Mutations in the APOB gene affect the structure or function of apolipoprotein B, impairing LDL
clearance and raising cholesterol levels.

PCSK9 Mutations:
PCSK9 regulates LDL receptor levels.
Mutations in the PCSK9 gene increase LDL receptor degradation, reducing LDL clearance efficiency
and higher LDL-C levels.
not true muscle
hypertrophy. It is fatty
and connective tissue
infiltration within the
muscle, giving the
appearance of enlarged
or hypertrophied
muscles.
In a normal
collagen
molecule, there
are two α1 chains
and one α2 chain,
forming a triple
helix structure
(2α1 + 1α2).
OI Mutations:
Disrupt the
balance of α1 to
α2 chains.
Mutations in one or the other of these genes cause the body
to make either abnormally formed collagen or too little
collagen
Pterin carbinolamine-4 α-dehydratase (PCD)
This enzyme is involved in the biosynthesis of BH4. Mutations in PCD can lead to BH4 deficiency,
affecting PAH activity and causing an increase in phenylalanine levels.

Dihydropyridine reductase (DHPR)
DHPR is essential for the recycling of BH4. Mutations in DHPR can also result in BH4 deficiency and
impact PAH function.

6-pyruvate-tetrahydropterin synthase (PTPS)
PTPS is another enzyme involved in BH4 biosynthesis. Mutations in PTPS can lead to BH4
deficiency, affecting the activity of PAH and causing elevated phenylalanine levels.
 The effect M3 on the protein
A. Arg to Ser
The template strand (or noncoding strand or antisense B. Pro to Ser
strand) codes for anticodons C. Ser to Arg
The coding strand codes for codons D. Ser to Pro
Clinical case
Naseba is an 8-year-old living in a suburban Toronto, Canada
community. Her parents immigrated from Pakistan when she
was two years old. At age 3, she was in the 10th percentile
for height and weight, pale, and had 5.8 g/dL hemoglobin.
Molecular and Biochemical
Complex Traits III, IV

Murad Odeh, PhD
Associate Professor
Objectives Inheritance
Single-gene inheritance (monogenic)
Genetic modifier
Environmental modifier
Polygenic inheritance
Multifactorial inheritance
Complex trait
Genetic
Environmental
Measures of inheritance
Familial studies
Adoption studies
Twin studies
Disease examples
Vein thrombosis
Cystic fibrosis
Retinitis pigmentosa
Diabetes 1 & 2
Hirschsprung disease
Heritability
Heritability is the proportion of variance in a particular
trait, in a particular population, that is due to genetic
factors, as opposed to environmental influences
Definition:
Heritability is a measure that helps us understand how much of the differences in a
trait among individuals in a population are due to genetics rather than environmental
factors.
Interpretation:
If a trait has high heritability, genetics play a significant role.
Low heritability indicates that environmental influences have a more substantial
impact on the trait.
Purpose:
It's a way to quantify the genetic contribution to variations in traits within a specific
group of people.
Genetic Relatedness of Children of
Identical Twins:
Comparison with Cousins Born to Non-
Identical Twin Parents:
Genetically, the children of identical
twins would share a higher percentage
of their genetic material compared to
cousins born to non-identical twin
parents.
Similarity to Half-Siblings:
The genetic relatedness would be like
half-siblings but not identical because
they still inherit genes from different
parents.
Legal and Social Considerations:
Children of identical twins are legally and
socially considered cousins.
They would have a more significant
genetic relatedness than cousins born to
non-identical twin parents.
Effect of Oral Combined Oral Contraceptive (COC)
Use on Venous Thromboembolism (VTE) Risk:

Risk Increase:
COC use can increase the risk for VTE, including deep venous
thrombosis (DVT) and pulmonary embolism (PE), compared
with non-use.
Mechanism of Action:

Estrogen Influence on Gene Transcription:
Estrogen, like many lipophilic hormones, affects the gene
transcription of various proteins.

Increase in Clotting Factors:
Estrogen increase the production of clotting factors, such
as factor II (prothrombin), factor VII, factor X, and
fibrinogen, while also reducing the production of
antithrombin III, a natural anticoagulant. This imbalance
makes the blood more prone to clot formation.

Relationship to Dose:
Higher doses of estrogen appear to confer a greater risk
of venous thrombus formation.
Tunnel vision

Environmental factors such as light exposure, diet, general health, and toxins can
influence the severity and progression of RP. Protective measures, like UV filtering
lenses, antioxidant-rich diets, and careful management of overall health, may
help slow the disease progression in some individuals.
Percentage of
Genetic Similarities
% of Genetic Similarities
1.Full siblings: Approximately 50% genetic similarity
2.Half-siblings (same mother): Approximately 25% genetic similarity
3.Half-siblings (same father): Approximately 25% genetic similarity
4.Cousins: Approximately 12.5% genetic similarity (assuming their parents are siblings)
5.Cousins from identical twin mothers & fathers: Between 25% and 50% genetic
similarity (estimation; higher than regular cousins due to identical twin parentage)
6.Niece/nephew to aunt/uncle: Approximately 25% genetic similarity
7.Grandchild to grandparent: Approximately 25% genetic similarity
8.Parent to child: Approximately 50% genetic similarity
9.Identical twins: 100% genetic similarity
10.Fraternal twins: Approximately 50% genetic similarity (like regular siblings)
11.Aunt/uncle to niece/nephew: Approximately 25% genetic similarity
12.Second cousins: Approximately 3.125% genetic similarity (assuming their parents
are cousins)
(heritability)
represents the
proportion of
variation in a trait
that can be
attributed to genetic
factors in a
population.
End of Questions
 What is heritability and How Is It Measured?
Heritability is the proportion of phenotypic variation due to genetic variations among
individuals in a population. Heritability is estimated by comparing individual
phenotypic variation among related individuals in a population, by examining the
association between individual phenotype and genotype data

For example, as heritability ratio applies to individuals within populations, it
cannot be used to predict genetic differences between races or other
populations from phenotypic differences, whether they share the same
environment or not

If the relative risk
To study
Relative Risk is greater than 1,
heritability, Ione
then the event is
would use
more likely to
Adoption Studies
occur. If the
relative risk is less
than 1, then the
event is less likely
to occur
Heritability is the proportion of variance in a particular trait, in a particular population, that is due to
genetic factors, as opposed to environmental influences or stochastic variation.
That’s just a general definition to give you a feel for it. Actually we need to be more rigorous than
that. There are two definitions of heritability. A common simplification in all sorts of genetic studies and
models is to assume that all alleles and all genotypes act independently of each other – this is called an
‘additive model.’ So for instance, if one allele of a particular SNP gives you a 1 cm increase in height,
then being homozygous for that SNP should give you a 2 cm increase in height. Clearly, this model
doesn’t allow for dominant or recessive effects, even though we know these abound. It also doesn’t
allow for gene-gene interactions, where maybe that SNP only gives you a 1 cm increase in height if
paired with another SNP. For these reasons, the additive model is a huge simplification, but a useful
one. Now for the two definitions of heritability:
‘narrow sense heritability’ (h2) is defined as the proportion of trait variance that is due to additive genetic
factors
‘broad sense heritability’ (H2) is defined as the proportion of trait variance that is due to all genetic
factors including dominance and gene-gene interactions.
Both kinds of heritability are incredibly tricky to estimate and to interpret. In terms of estimation, a big
problem is that people who share parts of their genome tend to share parts of their environment
too. One simple way you might think to estimate heritability is to plot children’s traits against the
average of their parents, as shown in this example from Visscher 2008:
In the example above, the slope is taken to be the heritability. The problem with this is that
parent and child share a lot else besides half their genome.
One approach to calculating heritability which largely avoids the confounding of genotype with
shared environment is to compare the phenotypic concordance of monozygotic (MZ,
identical) twins versus dizygotic (DZ, fraternal) twins. Both types of twins are expected to
share virtually all environmental factors, including while in the womb, which is why this is a
better study design than just comparing MZ twins to siblings. Comparing MZ to DZ twins lets
you isolate the contribution of that marginal half shared genome to phenotypic concordance.
Visscher 2008, citing Deary 2006 (ft), discusses the example of IQ, where MZ twins have
concordance of.86 and DZ twins have concordance of.60. ”Concordance” in these studies
seems to refer to a Pearson’s correlation or similar, so something like an r or ρ. (Why r and
not slope, like in parent-offspring regression? See this post for further discussion).
At first glance it is not clear how to convert these numbers –.86 and.60 – into an estimate of
heritability. After all, both of these figures include both genetic and environmental
factors. The key observation is that sharing a marginal half genome with your twin explains
an additional.86-.60 = 26%, so in theory, sharing a full genome explains 2*26% = 52%.
This is called Falconer’s formula:
A limitation of heritability
estimates derived from
twin studies is the
potential for unmeasured
gene by environment
interactions to contribute
to phenotypic variance
In other words, a
heritability estimate cannot
be used to determine the
causes of differences
between populations, nor
can it be used to determine
the extent to which an
individual's phenotype is
determined by genes
versus environment.
Monozygotic (MZ) Twins:
Definition: Monozygotic twins, commonly known as identical twins, originate from a
single fertilized egg (zygote) that splits into two embryos.
Genetic Relatedness: MZ twins share 100% of their genetic material. They have nearly
identical genetic makeup, as they come from the same fertilized egg.
Concordance Rates: Comparing traits or conditions between MZ twins helps researchers
assess the genetic contribution. If MZ twins show higher concordance rates (similarity in
traits) compared to DZ twins, it suggests a genetic influence.
Dizygotic (DZ) Twins:
Definition: Dizygotic twins, also known as fraternal twins, result from the simultaneous
fertilization of two separate eggs by two different sperm.
Genetic Relatedness: DZ twins share, on average, 50% of their segregating genes, just
like non-twin siblings born in separate pregnancies.
Concordance Rates: Comparing traits between DZ twins provides information about the
genetic and environmental factors influencing those traits. Lower concordance rates in
DZ twins, compared to MZ twins, may suggest a genetic component.
A limitation of heritability estimates derived from twin studies
is the potential for unmeasured gene by environment interactions
to contribute to phenotypic variance

a heritability estimate cannot be used to
determine the causes of differences
between populations
determine the extent to which an
individual's phenotype is determined by
genes versus environment.