Inborn Errors of Metabolism

Question 1

Why are inborn metabolic diseases so clinically relevant?

Answer 1

Whilst they are individually rare, collectively they are a significant health problem

Question 2

Approximately how many live births are affected by a rare metabolic disorder?

Answer 2

1 in 1,000-2,000 live births

Question 3

Why are inborn metabolic disorders often missed?

Answer 3

They are often the last thing that doctors consider during diagnosis as they are so rare Often the symptoms will overlap with more common disorders

Question 4

When do inborn metabolic disorders typically present?

Answer 4

Most (but not all of them) present during childhood

Question 5

What are the most common type of metabolic disorders?

Answer 5

enzyme defects this affects biochemical reactions occurring within cells

Question 6

What happens if a mutation occurs in the structural genes?

Answer 6

this affects how the protein is made the protein may fall apart and not be functional or it may only be affected slightly meaning enzyme reactions still occur, but more slowly

Question 7

What happens if a mutation occurs in the regulatory regions of a gene?

Answer 7

This affects the amount of protein that is being produced There is either an overproduction or underproduction of protein

Question 8

What is the main aim of the urea cycle?

Answer 8

ammonia is converted to non-toxic urea which can be excreted

there are many steps involved, which require many different enzymes

Question 9

How can the urea cycle be affected by mutations?

Answer 9

a mutation could affect any stage in the process

Question 10

Why do not all mutations produce a disorder in the urea cycle?

Answer 10

some genes are essential and a mutation within that gene is not compatible with life

Question 11

What would happen if there was a genetic defect in enzyme c?

Answer 11

there would be a deficiency in the end product D

everything prior to the site of the block starts to accumulate

there is a larger accumulation of the intermediates that are close to the site of the block

Question 12

If there is a mutation in enzyme c, how may clinical disease arise?

Answer 12

it may be due to not enough product being produced at the end

it could be due to accumulation of an intermediate going above a threshold value and becoming toxic

Question 13

What may happen if molecules begin to accumulate prior to the block?

Answer 13

They may start forming new compounds (E&F)

These new products may be toxic, but act at useful biomarkers to identify a disease/condition

Question 14

What is a cofactor?

How does it affect enzyme function?

Answer 14

Enzymes need cofactors to work properly

This is a vitamin or micronutrient that needs to be bound to the enzyme in order for it to function properly

Question 15

What treatment may sometimes be given when an enzyme is not working properly, but this can be reversed?

Answer 15

a vitamin deficiency can often affect enzyme function, as vitamins act as cofactors

the cofactors can be given in high concentrations as a treatment to stimulate enzyme activity

Question 16

What are the 3 mechanisms of disease resulting from an inborn error of metabolism?

Answer 16

1. accumulation of a toxin
2. energy deficiency
3. deficient production of an essential metabolite/structural component

Question 17

What is an ammonia accumulation?

What patients does it occur in and how urgent is it?

Answer 17

hyperammonaemia

it occurs in patients with urea cycle defects

it is a medical emergency and must be treated immediately

Question 18

If a newborn child has a defect in the urea cycle, when will this present?

Answer 18

a few days after birth

it takes time for the metabolic pathways to kick in and accumulate enough metabolites to cause a clinical effect

Question 19

If a patient has had hyperammonaemia, what major lifestyle factor is changed after treatment?

Answer 19

Diet - they need to have restricted amounts of protein in the diet to reduce the level of ammonia in the blood

Question 20

What are the clinical effects of acute hyperammonaemia toxicity?

Answer 20

1. lethargy
2. poor feeding
3. vomiting
4. tachypnoea
5. convulsions
6. coma
7. death

Question 21

What are the key components in the urea cycle?

Answer 21

Question 22

What condition does a reduction in the synthesis of haem l

Answer 22

Porphyrias

This is due to an accumulation of porphyrins

Question 23

What compounds are involved in the pathway that leads to the synthesis of haem?

Answer 23

Question 24

Why could there not be a complete block in the haem synthesis pathway?

Answer 24

This would lead to death as oxygen could not be carried in the blood

There are only partial defects in the enzymes, meaning that some haem is produced

Question 25

In someone who has a partial defect in an enzyme involved in haem synthesis, when do they tend to present with symptoms?

Answer 25

When the pathway is put under stress, there is accumulation of porphyrins

There is usually a trigger - e.g. hormonal changes

Question 26

What are the 2 different presentations of porphyrin accumulation?

What is the difference between the causes?

Answer 26

acute porphyria:

due to accumulation of ALA and PBG

photosensitive porphyria:

this is due to a block further down in the pathway

Question 27

What are the possible signs of acute porphyria?

Answer 27

1. severe abdominal pain
2. palpitations
3. pain in the chest, back or legs
4. constipation or diarrhoea
5. vomiting
6. insomnia
7. high blood pressure
8. anxiety or restlessness
9. seizures
10. mental changes]
11. breathing problems
12. muscle pain/tingling/weakness/paralysis
13. red or brown urine

Question 28

Why is there excessive hair growth in photosensitive porphria?

Answer 28

the porphyrins generate heat when exposed to light

this leads to painful damaging skin lesions

excessive hair growth is a response to try and protect the skin from light damage

Question 29

What are the possible signs of photosensitive porphyria?

Answer 29

1. sensitivity to the sun/artificial light
2. sudden painful erythema and oedema
3. blisters that take weeks to heal
4. itching
5. fragile skin
6. increased hair growth
7. red or brown urine3

Question 30

What are the 3 main sugars that are used for energy production and their component parts?

Answer 30

glucose - directly enters the glycolysis pathway (monosaccharide)

sucrose - made up from glucose and fructose

lactose - made up from galactose and glucose

Question 31

How is energy stored in the body?

When is this required?

Answer 31

Energy is stored in the form of lipids (triglycerides)

When there is no glucose available, the triglycerides are broken down and used for energy generation

Question 32

What is involved in fatty acid oxidation?

Answer 32

Fatty acids must be removed from glycerol and then transported into the mitochondria

the fatty acids are broken down to release ketons and acetyl CoA

ketones are used for energy in the brain and acetyl CoA enters the TCA cycle to produce energy

Question 33

When will a defect of fatty acid oxidation become apparent?

Answer 33

during times of energy deficiency when there is insufficient glucose available

e.g. during fasting or infection

Question 34

What happens if fatty acid oxidation is compromised?

Answer 34

the patient becomes hypoketotic and may enter a hypoglycaemic coma

this can lead to hepatic failure

Question 35

What would a person with androgen insensitivity syndrome look like?

Answer 35

They would have a healthy female phenotype with normal breast development but absent pubic hair

They are genetically male

Question 36

What is the background behind androgen insensitivity syndrome?

Answer 36

there is a mutation affecting a gene which codes for an androgen receptor

the patient produces testosterone, but it is unable to bind to the receptor and elicit an action in the cell

Question 37

How do patients often initally present with androgen insensitivity syndrome?

Answer 37

1. primary amenorrhoea
2. infertility

Question 38

What is meant by clinical heterogeneity?

Answer 38

there is often a poor genotype-phenotype correlation

many patients with the same condition present differently due to most disorders being multi-allelic

there may also be environmental involvement

Question 39

By which 2 methods are inborn errors of metabolism diagnosed?

Answer 39

1. pre-symptomatic screening
2. investigation of symptomatic individuals

Question 40

What is involved in pre-symptomatic screening?

Answer 40

You either look at whole populations or selected groups where a certain disorder is likely to be more common

A test is needed to determine whether a patient is healthy or has a disorder

Question 41

In pre-symptomatic screening, why are there often false positives or negatives?

Answer 41

there is usually an overlap between affected and unaffected individuals and the symptoms that they present with

Question 42

What are the 4 methods involved in investigation of symptomatic individuals?

Answer 42

1. test body fluids for abnormal metabolites
2. measure enzyme activities
3. histochemical/immunochemical staining
4. DNA analysis

Question 43

What is the route that tends to be followed when investigating symptomatic patients?

Answer 43

1. metabolite testing
2. more complicated metabolite testing
3. enzyme analysis/functional studies
4. mutation/gene analysis

Question 44

When investigating symptomatic patients, why are genes not analysed first even though the disorders are genetic?

Answer 44

1. the significance of the mutation is not always known as there is often a poor genotype/phenotype relationship
2. it is difficult to exclude disorders as not all mutations may be covered

Question 45

What are the 6 things that are tested for in the basic urine metabolic screen?

Answer 45

1. spot tests
2. organic acids
3. amino acids
4. sugar chromatography
5. oligosaccharides/sialic acids
6. mucopolysaccharides

Question 46

Why is an organic acid test usually performed?

Answer 46

small molecular weight organic acids are intermediates in most metabolic pathways

this allows many different disorders to be detected with just one test

Question 47

What are the 3 classic organic acidaemias?

What causes them?

Answer 47

1. propionic
2. isovaleric
3. methyl malonic

They are defects in branched chain amino acid catabolism

Question 48

Why are organic acidaemias not detected by measuring amino acid levels?

Answer 48

the amino acids themselves are not always increased when there is a deficient catabolic enzyme

the further away the block is from the parent amino acid, the less likely it will be to accumulate

Question 49

What are the 3 benefits to diagnosis of a inborn error of metabolism?

Answer 49

1. treatment improves prognosis
2. identify cause of clinical problem
3. genetic counselling