Mutations associated with muscular dystrophies & ataxias

Question 1

List the patterns of inheritance

Answer 1

Autosomal dominant inheritance
autosomal recessive inheritance
x-linked dominant inheritance
x-linked recessive inheritance
y- linked inheritance
mitochondrial inheritance

NOTE: week 1 LO

Question 2

Give examples of mutation mechanisms

Answer 2

1. Frameshift mutation:
   - insertion or deletion of a number of bases- alters the reading of the frae
   - I.e. alters the codons that are translated into amino acid
   - affects every codon downstream to the insertion or deletion
2. Trinucleotide repeat expansion.
   - Mutation occurs in genes with repeats of 3 bases (trinucleotides).
   - Mutation causes an increase in number of repeats
   - a threshold number fo extra repeats need to occur before we can see the disease
   - Associated w/ ‘anticipation’- successive generations are affected more severely due to mutation increasing in size
   - E.g. Huntingdon’s, Fragile x-syndrome & autosomal dominant cerebellar ataxias

NOTE: view diagram on notes!

Question 3

What is Muscular Dystrophy?

Answer 3

A group of diseases that cause progressive weakness & loss of muscle mass.

Patients have normal muscle function at birth

Mutations in genes interfere w/ production of proteins to form healthy muscle

Question 4

Examples of diseases that cause Muscular Dystrophy.

Answer 4

Duchenne Muscular Dystrophy

Becker Muscular Dystrophy

Facioscapulohumeral dystrophy

Myotonic Muscular Dystrophy

Question 5

Epidemiology of Duchenne Muscular Dystrophy (DMD)

Answer 5

Onset= 3-5 yr

Most common form of muscular dystrophy

In UK, 100 boys are born w/ DMD each year

Rare

Question 6

Inheritance & Pathophysiology of DMD

Answer 6

X-linked recessive inheritance

Frameshift mutation in DMD gene caused by deletion.

Gene codes for Dystrophin- protein that connects muscle membrane (sarcolemma) to actin & myosin filaments

Function of Dystrophin:
- Stabilises the membrane during contraction & relaxation
- Links the intracellular cytoskeleton w/ the extracellular matrix
- Allows muscle fibres to differentiate into fast twitch
- Organises the postsynaptic membrane & acetylcholine receptors

In DMD, mutated DMD gene faults to produce functional Dystrophin
-Muscle cells that lack dystrophin are mechanically fragile & fail after a few years = progressive muscle weakness.
- Muscles are vulnerable to tears during contraction- leads to Ca 2+ influx = disrupts intracellular signalling

Question 7

Clinical features of DMD

Answer 7

Delay in walking & falls

Muscle weakness- usually proximal muscles affected (if distal are affected, its more likely to be neuropathy).
- Symmetrical& persistent.

Muscle wasting- calf muscle atrophy.
- Weakness is more common than wasting. (Lots of wasting suggests neuropathy).

Muscle psuedohypertrophy - where the muscle looks like it is enlarging.
- caused by muscle being replaced by collagen & scar tissue
- Early finding.

Scoliosis

Contractures - tightening of the muscles.

Gait problems - including persistent toe-walking & flat-footedness
- Can lead to waddling gait.

Dilated cardiomyopathy- where the ventricle stretches and thins so it can’t pump blood as effectively.

Respiratory muscles - become impaired later on in the disease.

Positive Gower’s sign- patient that has to use their hands & arms to “walk” up their own body to stand due to a lack of hip and thigh muscle strength.

NOTE: view images in notes

Question 8

Investigations for DMD

Answer 8

Serum creatine kinase (CK) - usually elevated 10 - 20 times.

Electromyography- a measure of muscle response or electrical activity in response to a nerve’s stimulation of a muscle

DNA test to look for mutations in Dystrophin gene

Muscle biopsy
- absent dystrophin around muscle fibres

NOTE: view image on notes

Antibody testing:
- Connective tissue disorders - ANA, anti-ds DNA, anti-Ro, anti-La, anti Scl-70 & RF.
- Polymyositis - anti-Jo-1
- Dermatomyositis - anti-Mi-2

Question 9

Prognosis of DMD

Answer 9

• Most can expect to survive until at least their early 20.
• Premature death common btw 15 - 25 due to respiratory or cardiac failure.

Question 10

Epidemiology of Becker Muscular Dystrophy (BMD)

Answer 10

Very rare

Onset > 7 years (mean age is 11) = slower onset.

Slowly progressively - slower than Duchenne.

Question 11

Inheritance and pathophysiology of BMD?

Answer 11

X-linked recessive inheritance.

In frame DMD gene mutation.

Dystrophin is partially functional = protects the muscles from degenerating as badly or as quickly as in Duchenne.

Question 12

Clinical features of BMD?

Answer 12

Has the same clinical features as DMD but w/ a later onset & slower progression of the disease.

Patients can be in their teens or early 20s before diagnosis.

Muscle Biopsy shows reduced dystrophin staining UNLIKE DMD (absent)

Question 13

Inheritance and pathophysiology of Facioscapulohumeral dystrophy

Answer 13

Autosomal dominant inheritance

Genetic changes involve the long arm (q) of chromosome 4

Disease caused when a region of chromosome, D4Z4, doesn’t have enough methyl groups added (hypomethylated)
- This stops the DUX4 gene being silenced.

Unknown what DUX4 does to cause muscle damage

Question 14

Clinical presentation of Facioscapulohumeral dystrophy

Answer 14

Muscle weakness:
- Face = ptosis (droopy eye lids) & can’t whistle.
- Upper extremities
- Scapular = winging
- Humeral = biceps weakness
- Peroneal muscles = foot drop

Other features:
- Cardiac
- Hearing
- Epilepsy

Question 15

Epidemiology of Myotonic Muscular Dystrophy (MMD)

Answer 15

Rare

Commonest form of adult muscular dystrophy

2 types:
- DM1- Steinert’s disease
- DM 2- Proximal myotonic myopathy

Question 16

Clinical presentation of MMD

Answer 16

Myotonia- where muscles are unable to relax after they contract. - Prolonged spasms or stiffening of muscles.

Gait abnormalities - due to weakness of foot dorsiflexors.

Muscle wasting or weakness - weakness of intrinsic muscles of hand, wrist extensors, atrophy of the facial muscles & ptosis.

Cardiomyopathy

Frontal balding

Diabetes

Cataracts

Question 17

Inheritance & pathophysiology of DM1

Answer 17

Autosomal Dominant

Nucleotide repeat expansion

Mutations in DMPK gene on chromosome 19, that encodes for Dystrophia myotonica protein kinase.
- Normally, gene has 5 to 37 CTG repeats
- In affected individuals, it is 50 to several thousand.
- The longer the repeats, the more severe the disease & earlier the age of onset.

Exhibits anticipation

Congenital & adulthood onset forms

Question 18

Inheritance & pathophysiology of DM2

Answer 18

Milder than DM 1

Mutations in gene coding for CNBP (cellular nucleic acid binding protein) on chromosome 3.
- Expansion of the CCTG repeat.
- Typically 75 - 11,000 repeats

Shows minimal or no anticipation.

Question 19

What are ataxias?

Answer 19

a group of disorders that affect co-ordination, balance and speech.

Have difficulties w/:
- Balance and walking
- Speaking
- Swallowing
- Tasks that require a high degree of control, such as writing and eating.
- Vision

Question 20

What are the two types of ataxias?

Answer 20

1. Cerebellar - has a wide-based gait with associated intention tremor.
2. Sensory - has an unsteady high-stepping gait that gets worse in the dark.

Question 21

Inheritance & pathophysiology of Friedrich Ataxia

Answer 21

Autosomal recessive inheritance

Expansion of GAA trinucleotide repeat in FXN gene.
- GAA is normally repeated 5 to 33 times w/in FXN gene.
- In the disease, it is repeated 66 to 1,000 times.

FNX gene codes for the protein frataxin- important in mitochondria.
- Certain nerve & muscle cells cannot function properly w/out frataxin.

No anticipation

Question 22

Inheritance & pathophysiology of Autosomal Dominant Cerebellar Ataxias (ACDAs)

Answer 22

Autosomal dominant inheritance

Caused by mutation in DNMT1 gene which causes CAG repeat expansion in the coding regions.

gene provide instructions for making enzyme called DNA methyltransferase 1.
- This enzyme is involved in DNA methylation & important for neurone maturation, differentiation & migration.

CAG codes for glutamine - polyglutamine has a toxic effect on cells.

May show anticipation.