BIOL1XX8_2024_L24_Genetic disorders.pdf

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Genetic disorders
Lecture 24
BIOL1XX8/MEDS001 Human Biology

Dr. Hong Dao Nguyen
School of Life and Environmental Sciences
Learning objectives

Distinguish between autosomal dominant, autosomal recessive, X-linked recessive, X-linked
dominant and Y-linked modes of inheritance.
Predict the probability of an offspring’s genotype and phenotype for autosomal and sex-
linked traits and disorders
Determine the phenotype and genotype of individuals in a pedigree for autosomal and sex-
linked traits and disorders
Describe the role of sex chromosomes in human sex determination
Explain how X chromosome inactivation can lead to haemophilia manifestation in female
carriers

Key terms = blue
Terms for your own interest = pink
Sickle cell disease: an autosomal recessive disorder

Mutation in HBB gene resulting in abnormal haemoglobin beta
subunit
Heterozygotes exhibit the sickle cell trait and are carriers of the
abnormal allele
– Half of haemoglobin is normal
– Mixture of normal and sickle red blood cells (co-dominant phenotype)
– Lower blood oxygen levels (incomplete phenotype)

Images from Adobe Stock

Carrier: an individual who has a
heterozygous genotype and can pass on an
allele associated with a recessive trait or
disease.
- May have unaffected phenotypes or
Normal red blood cell
Sickle cell red blood cell exhibit disease symptoms of varying
severity
Images modified from http://www.publicdomainfiles.com
 Why does the sickle cell allele persist in human populations?

Sickle cell disease (recessive phenotype)
affects millions of people worldwide
– Major symptom is severe pain from
obstruction of blood flow

Heterozygous individuals (sickle cell trait
phenotype) have greater resistance to
malaria
– Malaria infected red blook cells tend to
sickle à removed by macrophages

Image from Piel et al. (2010) Nature Communications
https://doi.org/10.1038/ncomms1104
Pedigrees
A family tree indicating the presence of absence of a trait for each member

Conventions

Unaffected male Unaffected female

Affected male Affected female
Pedigree question
Q3. The son of Anne and Rob has sickle cell disease (recessive phenotype). What is the
genotype of Anne?

A. Homozygous dominant
B. Heterozygous Anne Rob
C. Homozygous recessive
D. Not sure

= affected male = affected female
= unaffected male = unaffected female
Huntington’s Disease: an autosomal dominant disorder

Healthy individuals are homozygous recessive
Affected individuals are homozygous dominant or heterozygous
Normal alleles of the HTT gene encodes for a normal HTT protein

Normal protein

…CAGCAGCAGCAGCAGCAG… 7-35 trinucleotide repeats

Mutant alleles characterised by additional CAG repeats in the sequence

Protein prone to misfolding

…CAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAG…

>40 trinucleotide repeats
How does the abnormal HTT allele persist in human populations?

Affected individual passes ~20 years after onset of
symptoms
Symptoms manifest between 30-45 years of age
– Patients may have had children before diagnosis
Rare cases of disease manifesting in children
Worldwide prevalence varies
– 5-7 people per 100,000 affected in Western countries
Highest incidence in Lake Maracaibo region, Venezuela
– 18, 000 individuals over 10 generations affected
Q4. Huntington’s Disease is an autosomal dominant disorder. If a child has a 50% chance of
inheriting Huntington’s Disease, what are the genotypes of the parents?

Let’s say:
h is the normal allele for the HTT gene
H is the abnormal allele for HTT gene
Genotype of Parent 1

A. HH and hh

Genotype of Parent 2
B. Both are hh
C. Both are Hh
D. Hh and hh
Autosomes and Sex chromosomes
Homologous chromosomes
Most of our cells are diploid
- 2 sets of chromosomes
Chromosomes 1-22 are autosomes
- don’t determine our sex
- Homologous
X and Y chromosomes are the sex chromosomes
- X and Y are not homologous

Key
Orange = inherited maternal chromosome
Blue = inherited paternal chromosome

23rd pair are the sex chromosomes

or

X/X
Image modified from Wikimedia
Sex determination
Sex in humans is determined by X and Y chromosomes
Sex determining region on the Y chromosome (SRY gene) is responsible for the initiation of
male sex determination

Orange = inherited maternal chromosome
Blue = inherited paternal chromosome

X/X X/Y

Female human Male human

Image modified from Wikimedia Commons https://www.nature.com/scitable/topicpage/genetic-mechanisms-of-sex-determination-314/
Sex linked disorders

X-linked dominant
– Let’s say the A represents the abnormal allele while a represents the normal allele
– Affected females can have a homozygous dominant (XAXA) or heterozygous genotype (XAXa)
– Affected males are hemizygous (XAY) i.e. one abnormal allele is sufficient to cause the disorder
– e.g Rett syndrome, hypophosphatemic rickets

X-linked recessive
– Let’s say a represents the abnormal allele while A represents the normal allele
– Affected females have a homozygous recessive genotype (XaXa)
– Affected males are hemizygous (XaY)
– Heterozygous females are carriers

Y-linked
– Abnormal allele exists on the Y chromosome and can only be passed from father to son
Red-green colour blindness: an X-linked recessive disorder
Insensitivity to green light resulting from mutations in the OPN1LW or OPN1MW gene
Abnormal opsin pigments in cone cells of retina
Affected individuals have trouble distinguishing between some shades of red, yellow, and
green.

Images from Wikimedia Commons
X-linked recessive questions

Q5: A man and his daughter both have red-green colour blindness, an X-linked recessive
disorder. The mother is not affected. What is the probability that their next child will be a son
with red-green colour blindness?
Let’s say:
XA is the allele for the normal pigment Genotype of the mother
Xa is the allele for the abnormal pigment

Genotype of the father
A. 0.25
B. 0.50
C. 0.75
D. 1.00
Haemophilia A and Haemophilia B: X-linked recessive disorders

Clotting deficiency
Abnormal alleles code for proteins that
cannot participate effectively in blood
clotting process

Haemophilia A
Most common type of haemophilia
Deficiency of clotting factor VIII

Haemophilia B (Christmas disease, Royal
disease)
Deficiency of clotting factor IX
Haemophilia manifestation in female carriers

Female carriers have a heterozygous genotype
– Generally have a healthy phenotype
– Some have mild symptoms of haemophilia
– Severe symptoms of haemophilia is rare but possible

One epigenetic mechanism that influences the diversity in phenotypes for female carriers is X
chromosome inactivation (lyonisation)
– One of the two X chromosomes in each diploid cell becomes inactivated during early development
– Selection is random
– Prevents females from having twice as many X chromosome gene products as males
– On average, 50% of maternal X chromosome and 50% of paternal X chromosome is inactivated
https://www.youtube.com/watch?v=veB31XmUQm8
Q6: Below is a pedigree for a sex-linked disorder. What is the mode of inheritance?

A. Y-linked
B. X-linked recessive
C. X-linked dominant
D. Not sure

Unaffected male Unaffected female

Affected male Affected female