Autosomal Dominant Disorders

Question 1

Know the characteristic features of autosomal dominant inheritance.

Answer 1

• Disorder is expressed in heterozygote
• Only a single mutant gene is necessary to produce the disorder
• Offspring have a 50% chance of inheriting the disorder
• The disorder appears in every generation –> vertical pedigree
• occurrence and transmission are not gender specific
• Typically late onset disorders
• Less lethal than autosomal recessive disorders
• Often involve structural protein defects
• Show wide variations in phenotypes (even within families) due to interactions between the affected gene and both the rest of the genome and the environment

Question 2

Lethal autosomal dominant disorders would _______ the fitness of those affected and as a result, _______ be passed onto future generations. In contrast, lethal autosomal recessive disorders _______ in which fitness is not affected.

Answer 2

decrease
would not
can be passed onto future generations through heterozygotic carriers

Question 3

Structural proteins are often _______ and produce a _______ when only one allele is defective

Answer 3

nonfunctional

mutant phenotype

Question 4

Autosomal dominant disorders demonstrate variability in phenotype due to

Answer 4

unknown interactions between the mutant allele and the genome and environment even when the genotype of individuals is the same. Both the penetrance and expressivity vary from person to person, even among the same family.

Question 5

With incomplete dominant inheritance, the severity of disease increases in _______ versus _______An example of this is _______.

Answer 5

homozygotes (AA)
heterozygotes Aa
achrondroplasia (Heterozygotes for the disorder can lead relatively normal, healthy lives, while a homozygote genotype is often incompatible with life early on)

Question 6

Diagnosing autosomal dominant disorders on the basis of clinical presentation and pedigree presents several complications:

Answer 6

1. new mutation rates for autosomal dominant disorders are high
2. the phenotypic expression of the disorder may be mild and difficult to detect clinically
3. Phenocopies may exist
4. genocopies may exist
5. differences in penetrance and expressivity
6. germline mosaicism

Question 7

Phenocopies

Answer 7

individuals with environmentally-influenced, non-hereditary disorders have phenotypes that mimic the phenotype of the genetic disorder

Question 8

genocopies may exist

Answer 8

expression of similar phenotypes resulting from mutation at a different locus

Question 9

Germline mosaicism

Answer 9

some or all of the cells of a parent’s germline carry the diseased mutation but their somatic cells do not
(a random mutation occurs in the parent’s germline and can be passed onto offspring. Because the mutation does not exist in the parent’s normal somatic cells, there is no increased recurrence risk for passing the mutation onto future offspring (beyond that of random mutation). The offspring, however, now have the mutated gene as part of the genome and can pass it onto subsequent generations.)

Question 10

Achondroplasia: Molecular basis

Answer 10

• Substitution of a guanine at position 1138 in the FGFR3 gene resulting in the substitution of an arginine residue for glycine
o 80% of cases are de novo in the paternal germline
ofrequency of de novo cases increase with paternal age
• FGFR3 function
o transmembrane tyrosine kinase receptor that binds fibroblast growth factors
o normally activated to inhibit chondrocyte proliferation to coordinate differentiation
• Effects of position 1138 mutation on FGFR3
o Gain-of-function mutation
o Ligand-independent activation of FGFR3 inhibits chondrocyte proliferation and leads to abnormal differentiation and shortening of bones

Question 11

Achondroplasia: Phenotype

Answer 11

Dwarfism, hypoplasia, normal intelligence, delayed motor development, hydrocephalus, brainstem compression and death in 3-7% of patients

Question 12

Achondroplasia: Other details

Answer 12

• Increased likelihood of individuals homozygous for Achondroplasia due to increased mating between individuals with the disorder
• Homozygous genotype is incompatible with life

Question 13

Marfan Syndrome: Molecular basis

Answer 13

Result of two common genotypes

1) Mutation of FBNI gene on chromosome 15 coding for fibrillin 1
- –Mutation leads to defective synthesis of microfibrils, inhibition of normal microfibril synthesis, and/or proteolysis of extracellular microfibrils
2) Mutations in TGF-beta R2
- –Leads to decrease in fibrillin and elastin deposition
- –Patients lack ocular defects, but have increased cardio abnormalities

Question 14

Marfan Syndrome: Phenotype

Answer 14

• Multisystem disorder
• Musculoskeletal defects: tall stature and abnormally long extremities
• Ocular abnormalities: flat corneas, increased globe length, etc.
• Cardiovascular abnormalities: mitral valve prolapse, aortic regurgitation, dilation of the ascending aorta
• Major cause of death in patients with the disorder is heart failure from regurgitation or aortic rupture (improved with surgical intervention)
• Pulmonary defects: pneumothorax
• Skin abnormalities
• Expressivity and penetrance in patients with Marfan syndrome vary and many of the symptoms develop with age.

Question 15

Neurofibromatosis-I: Molecular Basis

Answer 15

• Mutations in neurofibromin gene (NF1)
• –commonly deletion within gene
• –more than 500 mutations identified
• 50% are de novo mutations and 80% of those are paternal in origin
• neurofibromin is a protein that activates GTPase activating protein, thus regulating cellular proliferation as a tumor suppressor
• mutation results in loss of function of the gene

Question 16

Neurofibromatosis-I: Phenotype

Answer 16

• Extreme clinical variability and pleiotropy
• Multisystem disorder
• Café au lait spots
• Cutaneous and peripheral neurofibromas
• Ocular abnormalities

Question 17

Huntington Disease: Molecular basis

Answer 17

• Mutations in the HD gene usually resulting from expansion of CAG repeat sequences on chromosome 4p
• Average number of repeats: 9-35 (average=19)
• Huntington Disease number of repeats: 40+ repeats (average=46)
• Function of HD gene product, huntington, is unknown
• 97% of cases are inherited
• Mutant inherited gene reaches full mutation through further CAG-repeat expansion during meiosis in the paternal germline
• Novel property mutation, meaning the mutation results in a gain of function without altering the normal function of the affected protein

Question 18

Huntington Disease: Phenotype

Answer 18

• Late onset
• Age of onset is inversely proportional with number of CAG repeats
• Further CAG expansion in paternal germ line leads to anticipation–progressively early ages of onset with each generation
• Psychiatric, cognitive and movement disturbances
• –Chorea, characterized by involuntary jerks, are common and result from neuronal atrophy in basal ganglia

Question 19

Alzheimer Disease: Molecular Basis

Answer 19

• 10% of early-onset cases exhibit autosomal dominant inheritance
• Early onset mutations: beta-amyloid precursor gene (APP) on chromosome 21, presenilin gene 1 (PSEN1) on chromosome 14, or presenilin gene 2 (PSEN2) on chromosome 1
• Sporadic (late-onset) mutations: ApoE allele e4 on chromosome 19q
• Mutations lead to increased A-beta42 production

Question 20

Alzheimer Disease: Phenotype

Answer 20

• Beta-amyloid plaques
• Neurofibrillary tangles
• Dementia

Question 21

What is the paternal age effect?

Answer 21

Paternal age effect refers to a correlation between increased frequency of disorders and paternal age. Some autosomal dominant disorders have a 2-3 fold increase in frequency with fathers over the age of 39. Examples include achondropalsia, Apert and Marfan syndromes.

Question 22

What problems do late-onset disorders create for genetic counseling?

Answer 22

Late-onset disorders, like Huntington’s disease, create problems for genetic counseling, because the disorders may not manifest themselves until after a male reaches reproductive age. Thus, the disorder and the risk of passing the disorder onto offspring may be unknown until after reproductive years have passed. The likelihood of passing on a mutation that an individual showed no symptoms for is much greater.