ANIM 2503 Animal Breeding and Molecular Genetics Review for Quiz 1 - PDF

Summary

This document is a review lecture for a quiz on animal breeding and molecular genetics. Dr. Lee McMichael, from the University of Queensland, Gatton Campus School of Veterinary Science, presents an overview of Mendelian genetics, including dominant and recessive alleles, Punnett Squares, and different modes of inheritance.

Full Transcript

ANIM 2503
ANIMAL BREEDING AND MOLECULAR GENETICS

REVIEW LECTURE FOR QUIZ 1 PREPARATION
DR LEE MCMICHAEL
UNIVERSITY OF QUEENSLAND, GATTON CAMPUS

SCHOOL OF VETERINARY SCIENCE
[email protected]

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Mendelian Genetics

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Recap of terminology
Gene = length of DNA coding for functional protein

Locus = position of gene on chromosome
Allele = version of a gene that differ in their base sequences
Phenotype = observable characteristics of an individual based on the
expression of the gene and its specific protein product
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Mendel’s Universal Laws of Heredity
Explain a phenotype:
• A gene is the fundamental unit of inheritance
• There are alternative forms of genes called alleles
• For each characteristic, an organism inherits 2 alleles, one from
each parent
• Alleles can be dominant or recessive - gametes carry only one
allele for each inherited characteristic where gametes have equal
probability of having either allele
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Understanding dominant and recessive alleles
The dominant allele is usually denoted by a capital letter
In the following example, the shorthaired allele (L) is dominant to the
longhaired recessive allele (l)
In simple inheritance, dominant alleles mask effects of recessive
alleles
More complex systems exist (co-dominance, for example)
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Use “Punnett Squares” to predict the genotypes and
phenotypes of offspring from matings .. remember one

allele donated per gamete

x

B

B

b

Bb

Bb

b

Bb

Bb
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F1
generation

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Modes of Inheritance
Autosomal dominant: Allele for the gene variant is dominant and located on a non-sex

chromosome, thus the offspring only needs one copy to express the trait
Autosomal recessive: Allele for the gene variant is recessive and located on a non-sex

chromosome, thus the offspring needs two copies of that allele for the trait
X-linked dominant: Allele for the gene variant is dominant and located on the X chromosome,
thus the offspring needs only one copy to express the trait

X-linked recessive: Allele for the gene variant is recessive and located on the X chromosome,
thus female offspring need two copies to express the trait and males only one copy
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Question

Autosomal
dominant

Autosomal X-linked
recessive dominant

X-linked
recessive

Are males and females
equally affected?
If no,
1. Do all affected males
have affected
daughters?
2. Do all affected
females have
affected sons?

YES

YES

NO

NO

YES

NO

YES

NO

NO

YES

NO

YES

Do all affected
individuals have an
affected parent?

Remember to
work out on the
pedigree if your
mode of
inheritance is
correct … this is
one use of your
working
notepaper

Can the trait skip a
generation?
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How does the epistatic effect of the dilute gene occur?
•

The diluted colour phenotype is caused by a single base deletion in the melanophilin (MLPH)
gene which encodes a carrier protein.

•

Mutations in melanophilin cause the "dilute" coat color phenotype in dogs and cats (and

humans), altering the coat colour from black to grey, red to cream and chocolate to
lilac, and can be found in both purebred and random-bred cats.

-

Dilute colour mutation is an autosomal recessive condition

-

dd will result in the recessive trait and will dilute the colour expressed by the colour gene

-

D- will give normal colour (actual colour according to colour gene)
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Dosage compensation and tortoiseshell cats

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Mutations and Abnormalities

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The Genetic Translation Code
Set of three nucleotides code for a single amino acid, called a codon
Start and stop codons signal beginning and the end of the amino acid
sequence
DNA genetic code is made up of the nucleotides adenine, thymine, cytosine
and guanine (ATCG)
In mRNA, the thiamine (T) is replaced with uracil (U)
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Mutations are changes to DNA or RNA
•

Single base substitution. In coding regions these could be silent
(synonymous), missense (non-synonymous), nonsense (stop).

•

Indel: an insertion or deletion of one or a few nucleotides. Can
lead to “frameshifts” within coding regions. Can lead to new
function or lethal loss of function ie: the Start codon signals
where to start reading, if a nucleotide is added or deleted then
the sets of three nucleotides (the codons) are read differently.

•

A splice site mutation is a mutation that alters nucleotides at
splice control sequences, changing the patterns of RNA splicing
and changing the resulting length and structure of the mRNA.
Leads to subsequent changes in the length and structure of the
protein
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Muscular Dystrophy in Golden Retrievers

A splice site mutation in intron 6 causes:
• a complete deletion of exon 7 from mRNA and
• a frameshift in following exons
• a mutated protein … absence of dystrophin from muscle
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Defective chromosomal
recombination/segregation
Abnormalities can arise when chromosomes rearrange or fail to segregate properly. These
alterations can be of a structural or numerical nature:
Numerical anomalies result in aneuploidy, or addition or loss of individual chromosomes from
the normal set of 46 in the case of humans.
Structural abnormalities are rearrangements of genetic material within or between
chromosomes. These can be balanced or unbalanced.

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http://2.bp.blogspot.com/_9LmEKw8Ts54/SQZD5gcLs6I/AAAAAAAAAMU/0TMIUC7zBGw/s400/nondisjunction.jpg

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Sex chromosome aneuploidy
Female offspring:
XX, X0, XXX

https://www2.palomar.edu/users/warmstrong/biex4hnt.htm

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Loss or gain of a single chromosome
•

Normal = euploidy = having the normal number of chromosomes

•

Abnormal = aneuploidy = having fewer or more than the normal diploid

•

Most common forms of aneuploidy are monosomy (loss of one of a pair of chromosomes) and

trisomy (three chromosomes instead of a pair)
•

Effects of Aneuploidy of autosomes: Serious developmental problems, typically lethal =
embryo/foetal loss i.e not passed on. Tisomies of small chromosomes can lead to live animals

•

Effects of polyploidy in mammals: In mammals, polyploidy is lethal, usually at embryonic/foetal
stage, causes severe developmental abnormalities
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Abnormal chromosome structure
• Changes to the structure of one or more chromosomes is caused
by mistakes in meiotic recombination and DNA break repairs
Balanced changes: do not change overall DNA content of a cell
although the gene neighbourhood is affected and might alter gene
expression
Unbalanced changes: overall loss or gain of total amount of DNA

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Reduced fertility due to translocations
Complex arrangements of chromosomes during meiosis where homologous
regions of chromosomes align in order to be distributed correctly to gametes
* Translocations can be inherited through balanced gametes
When translocations occur at meiosis, this can lead to creation of balanced
but unbalanced zygotes
* Translocations can lead to reduced fertility
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Reciprocal Translocation – cause of low fertility
•

Individual has reciprocal translocation
during meiosis

•

Balanced individual = has full complement
of all chromosomal pieces

•

All gametes are functional, but some
gametes are unbalanced

•

Upon fertilization with normal gamete,
some zygotes are unbalanced and die

•

Seen as a reduction in fecundity

•

Changes are however inherited through
two gametes with balanced translocation
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Robertsonian translocation … same concept

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Abnormal chromosome structure

Genome rearrangement
(inversion and translocation).
Occurs during meiosis. Can
lead to new functions or to
lethal loss of function.
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Mutation and Repair

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Mutation heritability depends on mutation location
Somatic mutations:

• Occur in non-reproductive cells passed onto
daughter cells
• Creates a clone of mutant cells - More widespread
if occurring in embryo
• Many have no phenotypic effect
Germ-line mutations:
• Occur in cells that produce gametes passed to
future generations
• All cells in the offspring’s body carry the mutation
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Genetic Tests

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Sample Collection .. avoid contamination and store/ship appropriately

Extract DNA (stable)

Amplification of
segment of genetic
material

PCR

Extract RNA (unstable)

Real
Time
PCR

Reverse transcriptase
PCR

Agarose gel electrophoresis
RFLP, DNA sequencing
SNP and microsatellite genotyping
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1.

Denaturation: Heating the DNA to ~95 degrees C
separates the two strands

2. Annealing: The temperature is dropped to 50-60
degrees C for ~30 seconds and two short oligos
(=primers) bind to the target region of the DNA. The
oligos are ~20-25 bp long and match only one place in
the genome. These define the ‘target’ region

3. Extension: The temperature is increased to ~72
degrees C for 1-2 minutes and the enzyme Taq DNA
polymerase adds dNTPs (A, C, T and G nucleotides)
to the oligo to make a new strand that is
complementary to the strand to which it is bound

Steps 1-3 are repeated over ~30 times: Each time
the primers bind to the original DNA strand and also to
each of the newly created strands
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Agarose Gel Electrophoresis

A fluorescent dye that binds DNA eg ethidium bromide or SYBR
Safe is added to the gel.
It binds to the double stranded DNA and fluoresces when placed
under UV light.

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Real time quantitative PCR (qPCR)
As the number of PCR cycles increases, there is an increase in
fluorescence.
The reaction is variable at the start and end, there is an
exponential phase in the centre and plateau at the end.
CT value is the threshold cycle or the cycle number at which a
curve crosses a threshold level and enters the exponential phase.

Use for presence/absence (Syber or probes) or quantitative
(relative using control gene to normalise or absolute using a

standard curve).
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DNA Sequencing
Useful for single or multiple nucleotide substitutions and is “Gold standard” – details nucleotide change

and any additional changes.
• Sanger sequencing: PCR-like reaction with dNTPs and ddNTPs (non-extendable). Different
fluorescent colour on each ddNTP.
• Next generation sequencing: Massively parallel sequencing, produces millions of fragments of
sequenced DNA that must be aligned to a reference genome for interpretation.
• Nanopore sequencing: When a DNA molecule passes through the nanopore, a current is produced that
is decoded using base calling algorithms to determine the DNA sequence.

Sanger sequencing not useful for Indels (insertion or deletion) because sequence both alleles at same
time so heterozygotes have two off-set sequences (unreadable) … must use Next generation or
Nanopore sequencing technologies to investigate.

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Restriction Enzymes
and RFLP analysis
•

Restriction endonucleases are enzymes that cut
DNA at the “recognition sequence”

•

For genetic testing, use a restriction enzyme that
cuts either the mutated DNA or the ‘wild type’ DNA

•

PCR products are incubated with the restriction
endonuclease, run on electrophoresis to detect

length variants (cut versus not cut PCR products)
• Useful for single base changes or indels (insertion or
deletion)
• Remember, number of fragments = number of cuts
plus one
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Direct versus Indirect Markers
Genetic marker
eg microsatellite

Mutation
in gene

B
b*

• Direct tests detect mutations in the gene of interest
• Indirect tests rely on linkage between genes on the same chromosome
•

The genetic marker tested is not the cause of the disease but is linked to causative mutation

•

The marker is used to ‘predict’ which allele is present at the gene

•

Expect linkage between two polymorphisms to reduce with distance and correlates with recombination rate
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Genetic Markers for Indirect tests
• SNPs Single Nucleotide Polymorphism
-

- A variant at one nucleotide, present in a population at >1% Allele specific primers
Two forward primers that each match only one allele
PCR separately to see which allele(s) present.
Primer anneals one nucleotide prior to mutation and extended by one base
Detection by capillary electorphoresis with dye-labelled ddNTP, SNP chips

• Microsatellites
- Repetitive region with short repeat units, also called STR – short tandem repeats
• Example: a (CT)25 microsatellite locus
ACTTGCAGGTACTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCAT
GGGTCTTATGACTGCAATG
• Interspersed through the genome in introns and intergenic regions, rarely in coding regions
• 10,000s in the genome
• Repeats are short, usually 2-6 bp long.
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Caution with Genetic Tests
• Genetic heterogeneity: Different mutations can lead to the same or similar
phenotype
• Phenocopies: Phenotype due to a cause that is not genetic, but has the
same appearance as the genetic disease

•

Is this a multifactorial or polygenic disease/trait?

• Most diseases are the consequence of the combined effect of mutations in multiple
genes +/- environmental effects

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Multifactorial Traits

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Effect of many contributing genes
The more genes that combine to produce a
trait, the more possible phenotypes there are
With many loci, the number of possible
phenotype is best described as a distribution

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Characteristics of Multi-factorial Diseases
• Low heritability .. most affected progeny have unaffected parents
• Relationship by blood slightly increases the risk for an affected offspring
• Risk of affected relatives falls off very quickly with the degree of relationship

• Risk increases with the number of affected offspring in a family .. indicates
parents more likely to be closer to the threshold
• A more severely affected parent is more likely to produce an affected
offspring
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Threshold Model of Multifactorial Disease
•

With an increasing number of disease-susceptibility
alleles (cause or associated with disease) or disease
modifier alleles (expression influences phenotype of
independent mutation) that increase risk, an
individual’s liability increases.

•

Individuals with a liability over the threshold will show
the disease, while those below the threshold will not.

•

Each individual with the disease can have a different
combination of alleles
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Gene types in multifactorial disease
Disease susceptibility genes: Have gene sequence variants
associated with an increased risk of disease but may not cause the
disease on their own
Modifier genes: Are genes whose expression or function can influence
the phenotype resulting from mutation of another independent gene

These can show two types of changes:
• Mutations: Heritable detrimental sequence changes in a gene that are
commonly associated with disease
• Polymorphisms: Sequence variation (point mutation) among individuals that
are common in a population (>1%) and that are usually not associated with
disease
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Testing for Multifactorial Diseases/Traits
If all the contributing genes, their interactions and environmental effects are known … then
genetic testing could be undertaken as we do for Mendelian traits.
But, we usually don’t know all, or even all the major, contributing genes, causative or associated
gene variants
Therefore we measure risk of associated variants … Can use Odds Ratios
• OR>1 indicates that the condition or event is more likely in the first group than the general
population
• OR<1 indicates that the condition or event is less likely in the first group than the general
population
• The closer the OR is to 1, the smaller the difference in effect between the two groups
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Quantitative Trait Loci (QTLs)
•

These principles from multi-factorial disease are the same when we think about production
traits .. most traits show a continuum of quantitative variation … termed quantitative traits

•

Use the term QTL when identified chromosome region but not actual ‘causative’ mutation

•

A QTL can be represented by the actual mutation if it is known (direct test) or
SNP/microsatellite marker (indirect test)

•

These genetic tests each measure just a single QTL. Each QTL marker tests only for a

proportion of the genetic contribution to that trait. It represents only one mutation (gene)
out of many that contribute to the trait.
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Cancer Genetics

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Cancer is a multi-gene disorder
Cancer arises from the accumulation of mutations in multiple genes. A single mutation in a
single gene is not sufficient to cause cancer. Cancer is a multi-step process .. accumulation
of mutations:
• Initiation: a genetic event would give a somatic cell limitless replicative potential, or a
growth/survival advantage in comparison to normal cells
• Promotion: a further genetic event would add to that cell’s ability to outcompete other cells,
leading to expansion and recognizing a tumor mass
• Progression: another genetic event would allow for invasion, tissue destruction and
metastasis = malignancy and clinical disease

A genetic event is a series of mutations. It takes 5 or 6 mutations for a tumor to arise
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Cancer arises from a combination of mutations in oncogenes AND tumour suppressor
genes ACCUMULATED over time.
However, some mutations are more commonly associated with many types of cancer.
Common examples of mutations found in the tumor suppressor genes occur in the
genes: BRCA1, BRCA2, and p53 or TP53
Common examples of mutations found in oncongenes: HER2 and RAS family of
genes

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Steps of colon cancer progression can be
correlated with specific mutations
Tumourigenic progression
genetically
altered cell

spread

Normal

5q loss
APC

Hyperplasia:
enlargement of
tissue or organ

Dysplasia:
abnormal cell
types

12p mutation
DNA
hypomethylation
KRAS

Invasive

18q loss
?DCC

17p loss
TP53

Metastatic

Other
alterations
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A genetic
event occurs
at each step
which
enables the
cell to adopt
a growth
promoting
advantage
Different
tumours will
generally
contain a
different set
of genetic
lesions

One
example of
mutations

Two types of Tumour Suppressor Genes
Caretaker genes function to

•

Maintain genomic integrity

•

Inactivation of caretaker genes leads to an accumulation of DNA mutations and genomic
instability (for example DNA repair genes or genes involved in chromosome segregation)

•

Small amounts of damage the caretaker genes will repair

•

If too much damage, cells will move to cell death moderated by Gate Keeper genes

Gate keeper genes function to
•

Act to prevent growth of potential cancer cells and prevent accumulation of mutations

•

Induce cell death or stop cell replication of potentially tumorigenic cells (cells that have
accumulated mutations) for example cell cycle checkpoint genes
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Loss of a gatekeeper or caretaker gene does not
cause the cancer, but rather it allows the
accumulation of the mutations in other genes which
ultimately causes the disease
It allows
• Mutations that have arisen to not be repaired OR
• It allows cells to continue to replicate even though
they have mutations
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Effects of mutations
Activate oncogenes by:
•

Activating nucleotide mutations

•

Gene amplification resulting in greater expression of genes

•

Chromosomal translocations

Inactivation of tumor suppressor genes by:
•

Inactivating nucleotide mutations (point mutations, indels)

•

Small chromosomal deletions, loss of entire chromosomes resulting in loss of gene

•

Unbalanced translocations resulting in loss of tumor suppressor gene

•

Epigenetic mechanism such as promotor methylation which switch gene off
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Mechanisms that can result in oncogene activation …
switching on or increasing expression

(More efficient protein)

(chromosomal aberration
leading to duplication)

(due to chromosomal translocations)
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Knudson’s two hit hypothesis: a mutation of both alleles of a TSG
(Tumour Suppressor Gene) is needed to trigger tumour formation
ALL cells inherited the
first mutation. Only
need one mutation for
tumor development,
thus higher rate of
cancer.

Familial cancer

Germ-line mutation

Somatic mutation

Rarer event occurring
in only some cells

Sporadic cancer

Somatic mutation 1 Somatic mutation 2
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What distinguishes
a cancer cell from a
normal cell?

Defective
response to
DNA damage

Defective
telomeres
Uncontrolled
cell proliferation

Immortalization
Cancer

Defective
apoptosis
Induction of
angiogenesis

All share
features of
uncontrolled cell
growth and
proliferation

Increased
cell motility

Reduced
cell adhesion

Mitochondrial Disease

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Mitochondiral DNA
• Replicates separately from nuclear DNA

• Codes for metabolic proteins (ATP synthesis, fatty acid metabolism, citric acid
cycle) Mitochondria primary role to produce energy … thus mitochondria are
termed the POWERHOUSE of the cell
• Many essential genes for mitochondrial replication and function have been
transferred to the nucleus
• Nuclear genes are “protected” from mutagenic environment of mitochondria
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Protein
synthesis

Initiation of
mtDNA
replication

Protein
synthesis

12S & 16S
rRNAs

cytochrome b
Codes for proteins
involved in energy
production

D-loop/
Control Region

tRNAs

Energy

Human mtDNA Map

Overlap of ATPase 6 and 8

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(Taanman, 1999, Biochimica
et Biophysica Acta, 1410:103)

Maternal Inheritance of mitochondrial DNA

In most animals, there is uniparental (maternal) inheritance of mitochondria and hence mtDNA
Both sons and daughters inherit the mtDNA of their mother
Mitochondrial inheritance is thus “non-Mendelian” (ie not derived from both parents)

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Nuclear-encoded mitochondrial genes
• Many essential genes for mitochondrial replication and function have been
transferred to the nucleus
• Nuclear genes are “protected” from mutagenic environment of mitochondria
• Nuclear-encoded mitochondrial proteins synthesized in cytoplasm and imported into
mitochondria facilitated by a signal peptide (SP)

High mutation rate in mtDNA due to:
• Reactive oxygen species (ROS or free radicals) produced during oxidative phosphorylation that cause
mutations which may lead to mutant proteins, which in turn may lead to more damaging radicals
• Low efficiency proof reading capacity of the gamma DNA polymerase
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Mitochondrial disease
• Disease pathogenesis relates to oxidative phosphorylation … the process that produces energy
• Mitochondrial diseases show delayed onset and progressive decline .. cellular energy capacity declines
and eventually the cell or tissue fails to function normally as mutations accumulate:
 Inherited mutations: Mitochondrial genes or Nuclear-encoded mitochondrial genes
 Acquired mutations: Age-related changes to mitochondria or effects of drugs, infections or
environmental impacts

• Mitochondrial disease can lead to developmental delay, sight and hearing loss, stoke-like symptoms,
cardiovascular disease, muscle, kidney and liver failure; cancer due to somatic mtDNA mutations
(oxidative damage) have been identified in various tumours; associated with ageing; male infertility.

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Randomness of mitochondrial disease
• Random and quantitative nature of mitochondria
means that the expression of mutations and
disease progression are highly variable
• 103–104 copies of the mtDNA per cell
• A mutation can be present in all copies (homoplasy)
or in a fraction of the copies (heteroplasmy)

• Severity of mitochondrial disease depends on ratio
of normal:affected mitochondria
Homoplasmy

The proportion of ‘wild type’ to mutated mtDNA can
change in a cell as mtDNA replicates independently of
the cell cycle

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Heteroplasmy

Preparation for your Assessment Quiz
Review any concepts in this lecture that you are unsure of
Ask questions
Perform your practice Inspera Quizzes:
• Practice Quiz Week 1
• Practice Quiz Weeks 2 and 3
• Practice Quiz Week 4
Multiple choice questions in old end of semester exam papers are useful
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Example EOS exam question for Module 1 …
not for your Quiz! Just FYI
This 6 month old Labrador retriever comes into your clinic. The owners are concerned about the dogs
difficulty swallowing and breathing. Upon a physical examination you note that the dog is in poor body
condition and has generalized muscle atrophy. One thought you have is that the dog may be affected by
muscular dystrophy. The owner wants to continue to breed golden retrievers.

QUESTIONS: Please outline in two paragraphs or 10-15 dot points the following:
• How you would explain the potential genetic syndrome and its causes to the client?
• How would you confirm the diagnosis by genetic testing?
• What advice you would offer the client with respect to breeding, based on the family tree that the client
has provided?
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Suspected Genetic Disease:
•
Muscular dystrophy with signs of difficulty swallowing, breathing, muscle atrophy caused by an absence of dystrophin in skeletal muscle
•
X-linked recessive disorder caused by a splice site mutation in the dystrophin gene
•
The mutation at the splice site mutation results in the deletion of the coding region of exon 7 of the gene and subsequent frame shift.
•
These mutations result in an altered non-functional protein.
•
The absence of this protein leads to muscle necrosis, fibrosis and ultimately cardiac/respiratory failure.
Genetic Diagnostic Tests:
•
A number of genetic tests could be performed inclusive of a reverse transcriptase PCR, a probe based qPCR with splice site specific probe, RFLP analysis or
sequencing of the gene
•

If genomic analysis of the DNA were to be performed (probe based qPCR, RFLP analysis or gene sequencing), blood samples would suffice and can be stored
refrigerated.

•

If a muscle biopsy was taken to examine other signs of muscle damage you could also examine the mRNA by RT-qPCR, but as RNA is really labile, the sample
would need to be collected into a preservative agent of frozen rapidly after collection.

Breeding advice to owner:
•
Based on the provided family tree, the male grandparent of the dog in question was affected.
•
The mother of the dog in question would be a carrier of the mutation on one of her X chromosomes. Female 3 would also be a carrier.
•
Female 8 may or may not be a carrier so I would recommend genetic testing before breeding with her.
•
Breeding from any of the unaffected males is ok as they only carry one unaffected X chromosome.

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