Session 3: Molecular Genetics

Question 1

Name 2 X-Linked Recessive disorders

Answer 1

• Duchenne/Becker Muscular Dystrophy (DMD/BMD)
• Spinal and Bulbar Muscular Atrophy (SBMA)
• Androgen Insensitivity Syndrome (AIS)

Question 2

Name 2 X-Linked Dominant disorders

Answer 2

X-linked hypophosphatemia
X-linked Alport Syndrome
Rett Syndrome

Question 3

Name three clinical features associated with CF

Answer 3

Chronic coughing and wheezing
Failure to thrive
Pancreatic insufficiency

Question 4

Name the most common CF mutation

Answer 4

p.Phe508del - 75%

Question 5

Describe the function of CFTR (7q31.2)

Answer 5

Cyclic AMP-activated chloride channel located in the plasma membrane of secretory eithelial cells

Question 6

How many types of SMA are there?

Answer 6

6 - Prenatal, type 1, Type 2, Type 3, Type 4 and atypical SMA

Question 7

Describe 3 characteristic features of SMA

Answer 7

Progressive proximal symmetrical limb and trunk muscle weakness,
Intercostal muscle weakness,
Fine tremor
Facial weakness

Carrier freq 1:40-60 depending population

Question 8

What is the most common type of SMA? Describe clin features

Answer 8

Type 1 - profound hypotonia, symmetrical flaccid paralysis, progressive, death at early age

Question 9

Give me some molecular facts about SMA

Answer 9

SMN1 and pseudogene SMN2
4% population have 2 copies of SMN1 on one chrm (range 0-5)
95-98% SMA homozygous for deletion of at least exon 7
2-5% are compound heterozygotes for del and pathogenic inactivating mutation

Question 10

How do we interpret SMA carrier testing?

Answer 10

Bayes calculation

Question 11

Briefly describe CRISPR-Cas9

Answer 11

Gene editing - Cas9 protein complex containing specific sequence of RNA - once complimentary sequence is identified the DNA is cut and released into the cell. Cellular DNA repair mechanisms repair the break - but this is prone to error. By introducing templates of ‘corrected’ DNA - these specific sequences can be incorporated to replace mutant alleles

Question 12

What is the clinical significance of 36-39 CAG repeats in Huntington Disease?

Answer 12

Reduced penetrance - may or may not be affected

Question 13

Above what number of CAG repeats would you see fully penetrant development of Huntington Disease?

Answer 13

40 CAG repeats

Question 14

What is the significance of 27-35 CAG repeats in Huntington Disease?

Answer 14

Intermediate allele - will not cause disease but may expand to cause disease if paternally transmitted

Question 15

Name 3 disorders associated with FMR1

Answer 15

1. Fragile X,
2. FXTAS,
3. POI

Question 16

How is Fragile X caused?

Answer 16

Expansion of unstable 5’ UTR CGG repeat to >200 repeats, causing gene silencing

Question 17

Give 3 clinical features of Fragile X in males

Answer 17

moderate/severe intellectual and social impairment, characteristic facial features, joint laxity, macro-orchidism

Question 18

Give the clinical presentation of Fragile X in females

Answer 18

Variable phenotype - apparently normal approx 50%) through to mild/moderate mental and social impairment

Question 19

What is the significance of repeat size of 55-200 in FMR1?

Answer 19

Premutation - may expand in maternal line to cause FraX in future generations. Patients may develop FXTAS or POI

Question 20

What is the proposed disease mechanism for FXTAS/POI

Answer 20

NOT the same as FraX - ?toxic gain of function?

Question 21

What is the location of FMR1?

Answer 21

Xq27.3

Question 22

What is the role of FMRP protein?

Answer 22

RNA binding protein, present in many tissues including brain, ovaries and testes - thought to act as a shuttle within cells by transporting mRNA from nucleus to areas of cell where proteins assembled. Also helps to control when the instructions in these mRNA molecules are used to build proteins.

Question 23

Name 2 NGS platforms

Answer 23

Agilent Sure Select,
ThermoFisher Ion Torrent,
Illumina HiSeq/MiSeq SBS seq by synthesis

Question 24

What are the mutation ranges for SBMA?
Spinal and Bulbar Muscular Atrophy

Answer 24

Normal - 34 CAG repeats or less
Questionable - 35 CAG repeats
Reduced penetrance - 36-37 CAG repeats
Affected fully penetrant - 38 CAG repeats or greater
Sequence any 35-37 repeats

Question 25

Name 3 CAG expansion disorders

Answer 25

1. Huntingtons
2. Spinal and Bulbar Muscular Atrophy (SBMA)
3. SCAs - 7 of them

Question 26

Name 2 CGG expansion disorders

Answer 26

Fragile X
FXTAS

Question 27

Name 3 CTG expansion disorders

Answer 27

Myotonic Dystrophy 1
Huntington Like Disease 2
SCA 8

Question 28

Name a GAA expansion disorder

Answer 28

Friedreich Ataxia

Question 29

Name a CCTG expansion disorder

Answer 29

Myotonic Dystrophy 2

Question 30

What additional features might you see in a juvenile HD patient with a large expansion?

Answer 30

Bradykinesia -slowness of movement
Dystonia

Question 31

What factors can contribute to pathogenic mechanism of repeat expansion diseases

Answer 31

1. Sequence of repeat
2. Size of repeat
3. Location of repeat within gene
4. Whether repeat encodes RNA or protein
5. Function of repeat-containing gene
6. Extent of meiosis and somatic instability

Question 32

What causes Myotonic Dystrophy 1?

Answer 32

CCTG repeat in intron 1 of the CNBP gene

Question 33

What are some clinical features of DM1?

Answer 33

Progressive weakness and myotonia
Cataracts
Cardiac arrhythmias
Endocrinopathy
Cognitive impairment

Question 34

Name 7 methods for detecting UPD

Answer 34

MS-PCR
MS-Melt Curve Analysis
MS-MLPA
MS-Pyrosequencing
Microsatellite analysis
SNP Arrays
WGS/WES - trios especially powerful

Question 35

Name 3 methods of detecting UPD that rely on bisulphite conversion

Answer 35

MS-PCR
MS-Melt Curve Analysis
MS-Pyrosequencing

Question 36

What are the pros and cons of using microsatellite analysis for UPD detection?

Answer 36

Pros: Will distinguish whole/partial UPD and Hetero/Isodisomy, relatively cheap, no prior conversion step, reliable method

Cons: Need parental samples and informative markers

Question 37

Describe MS-MLPA

Answer 37

2 tubes, 1 for CNV, 1 for methylation specific enzyme digest. Methylated DNA won’t digest, and then will amplify during MLPA.
Semi quantitative,
no parental bloods needed,
can distinguish UPD from deletion from a small amount of DNA
can’t distinguish UPD and mutation in imprinting centre

Question 38

How can you use WGS/WES for detection of UPD?

Answer 38

Trio analysis - bioinformatic pipelines will check for identity by looking for biparental inheritance
Can detect mosaics and can distinguish full range of del/UPD/IC defect
Expensive and time consuming, requires parental samples

Question 39

What are the pros and cons of using bisulphite conversion for UPD testing?

Answer 39

Pros: Allows for analysis without parental samples,
bisulphite conversion kits readily available,
cheap and effective

Cons: Won’t distinguish segmental/whole UPD, or del from UPD (MS-PCR)

Question 40

Describe Class 1 CFTR mutations

Answer 40

Nonsense, most frameshift mutns and large del’s create premature stop codons causing defective protein synthesis and no CFTR protein expressed. Severe phenotype, W128X, R553X, G542X.
Treatments - readthrough drugs - Ataluren phase 3 trials

Question 41

Describe Class 2 CFTR mutations

Answer 41

Some missense mutns and in frame del’s disrupt CFTR protein folding and trafficking to the surface. F506del, N1303K.
Treatments: correctors to promote folding - Lumacafter

Question 42

Describe Class 3 CFTR mutations

Answer 42

Some missense mutns result in substitution of aa’s, disrupting regulation of CFTR channel, which no longer opens in response to channel agonists. G551D, G551S, G1349D.
Treatment Ivacafter being trialled

Question 43

Describe Class 4 CFTR mutations

Answer 43

Some missense mutations result in changes to CFTR protein structure that forms the pore of the channel which can restrict the movement of Cl- ions through the channel - conductance defect. Eg R117H, R334W, R347P.
Ivacafter being trialled.

Question 44

Describe Class 5 CFTR mutations

Answer 44

Some missense mutations result in alternative splicing that disrupts mRNA processing - extremely reduced amounts of normal CFTR protein are synthesised, less protein at cell surface. 2789+5G>A, A455E. Treatments are focussed on compounds that enhance CFTR retention/anchoring

Question 45

Describe Class 6 CFTR mutations

Answer 45

Different types of mutations increase the turnover of CFTR protein at the cell surface, quickly removed and degraded by cell machinery. Egs include Rescued F508del, 120del23, N287Y, 4326delTC, 4279insA

Question 46

How many classes of CFTR mutations are there?

Answer 46

6

Question 47

Curry-Jones syndrome

Answer 47

7q32.1
Mosaisms
Recurrent somatic variant SMO p.L412F
Patchy skin lesions, polysyndactyly, cerebral malform, craniosynostosis, iris colobimas, microphthalmia

Question 48

Potential treatment for CF

Answer 48

Gene therapy - introducing a normal copy of CFTR

CFTR modulators:
1. Read through -Ataluren
2. Corrector therapy - corrects mts that cause misfolding and degradation eg F508del - Lumacaftor
3. Potentatior therapy - improves CFTR channel function by correction mts thatvreduce gating efficiency eg G551D - Ivacafor

Question 49

NBS - CF variants

Answer 49

4 variants:

p.Phe508del
p.Gly542X
p.Gly551Asp
c.489+1G>T

Question 50

CF intron 9 poly T & polyTG tract - significance

Answer 50

Poly T
5T - 90% cases exon 10 skipped

PolyTG
Longer TG associated with disease phenotype
Common TG lenght = 11, 13 and 13
Most common TG11

Increased skipping of ex10 caused by TG12, TG13 and 5T

TG12/T5 assoc. with CBAVD
TG13/T5 assoc. with atypical CF

5 T also modifies expression of p.Arg117His ( variable phenotype)

9T in exclusively seen in cis with p.Phe508del

Question 51

What is the UK carrier frequency of SMA?

Answer 51

1/50

Question 52

What are the main clinical features of SMA?

Answer 52

Weakness and paralysis of the voluntary muscles, due to spinal cord and motor neuron degeneration. Muscular atrophy.
Progressive proximal weakness
Intercostal muscle weakness, leading to breathing difficulty.
Fine tremor
Fasciculations in the tongue make feeding difficult

Question 53

Describe the 5 types of SMA

Answer 53

Prenatal - Arthrogryposis multiplex congenita and congenital axonal neuropathy. Death within 1 month. SMN2 copies: 1

Type I: Acute infant - diagnosed <6 months old. Floppy baby, weak intercostal muscles lead to respiratory failure. 60% of SMA. Death at early age (<2yrs old). Lack of motor development, tongue fasciculation. SMN2 copies: 2

Type II: Chronic infant - diagnosed 6-12months. 27% of SMA, hypotonia, 70% reach adulthood, sit unaided, no walking without support. Progressive muscle weakness. SMN2 copies 3-4

Type III: Juvenile - IIIa diagnosed at <3 years; IIIb diagnosed at >3 years. 12% of SMA. Some ambulation retained. Proximal muscle weakness develops, legs more severely affected than arms. SMN2 copies: 3-4

Type IV: adult - ~1% of patients, onset of muscle weakness in 2nd-3rd decade, legs more affected than arms. Normal life expectancy. SMN2 copies 4-8

Question 54

How many individuals are thought to carry two copies of SMN1 on a single chromosome

Answer 54

4%

Question 55

Describe the basic gene structure of SMN1/2

Answer 55

SMN1 and SMN2 (pseudogene). Arranged in tandem.
SMN1 is functional, SMN2 is largely unfunctional and lacks exon 7 in most transcripts. Increased copies of SMN2 can compensate for loss of SMN1 in some cases.
SMN1 - >90% of transcripts are full length; SMN2 90% of transcripts are missing exon 7, due to the c.840C>T silent variant present in an ESE.

Question 56

How many bases so SMN1 and SMN2 differ by? What are the common variants that allow the two genes to be distinguished?

Answer 56

5.
c.840C>T and c.859G>C in SMN2

Question 57

What is the SMN protein?

Answer 57

A ubiquitously expressed protein present in abundance in the motor neurons and spinal cord.
It functions to chaperone the assembly of the snRNAs used for splicing. Lack of the protein thought to disrupt mRNA processing in neuromuscular junctions.

Question 58

What is the common mutation found in 95-98% of all SMA individuals?

Answer 58

A deletion encompassing at least exon 7 of SMN1 - deletion can occur by homozygous deletion, or by gene conversion to SMN2 exon 7 (contains the c.840G>C resulting in exon skipping)

Question 59

What is the mutational spectrum of SMA?

Answer 59

95-98% deletion of exon 7
2-5% deletion + SNP
<1% homozygous SNP - majority located in exons 3 and 6. Some can be deep intronic

Question 60

What is the rate of new mutation?

Answer 60

2% de novo.

Question 61

Describe the genotype/phenotype correlations found in SMA

Answer 61

Type I: homozygous deletion of exon 7
Type II: SMN1 > SMN2 gene conversion plus a hemizygous gene deletion of the other allele.
Type III: 2 gene conversion event.

Question 62

How can SMN2 copy number compensate, in part, for lack of SMN1?

Answer 62

Disease is caused by low levels of protein, rather than complete lack of protein.
SMA I: 9% normal active protein
SMA II: 14%
SMA III: 18%
Full length SMN levels of 23% are needed for normal function.
The presence of 3+ SMN2 copies can make the phenotype milder.
The c.859G>C variant creates an new ESE in exon 7 of SMN2, to enhance exon 7 inclusion.

Question 63

List some modifier genes involved in the phenotypic severity of SMA

Answer 63

NAIP
SERF1
Plastin 3
ZPR1
PTEN

Question 64

Describe the diagnostic workflow for SMA mutation detection

Answer 64

Copy number analysis using specific probes for SMN2 c.840G>C and SMN1 WT sequences. (QPCR, RT-PCR, MLPA)
Sequencing using LR-PCR or cDNA analysis to ID point mutations on the second allele.

Question 65

What project is ongoing and looks to introduce an NIPD test for SMA?

Answer 65

NIPSIGEN

Question 66

Why is interpreting SMA carrier tests tricky?

Answer 66

6% of parents of a simplex case will have normal SMN1 dosage:
- 4% have two copies of SMN1 on a single chromosome.
- 2% of patients have a de novo deletion of exon 7 - only 1 parent is a carrier

Question 67

What therapies are currently being trialled to treat SMA?

Answer 67

1. increase expression of SMN proteins by correcting SMN2 splicing using antisense oligos - ISIS-SMNrx is currently in phase 3 clinical trials - enhances inclusion of exon 7.
2. Gene conversion from SMN2 to SMN1
3. Use stem cell therapy to compensate for lack of SMN protein - AveXis is currently in phase 1 clinical trials.

Question 68

What is the locus of Cri-du-chat?

Answer 68

5p15.3-p15.2

Question 69

What is the locus of Sotos?

Answer 69

5q35

Question 70

What is NSD1 associated with?

Answer 70

Sotos

Question 71

What is the locus of Cornelia de Lange?

Answer 71

5p13.2

Question 72

What is NIPBL associated with?

Answer 72

Cornelia de Lange

Question 73

What is the locus of WAGR?

Answer 73

11p13

Question 74

What is the PWS/AS locus?

Answer 74

15q11-q13

Question 75

What is the locus of Rubinstein-Taybi?

Answer 75

16p13.3

Question 76

What is CREBBP associated with?

Answer 76

Rubinstein Taybi

Question 77

What is the locus of Smith Magenis?

Answer 77

17p11.2

Question 78

What is RAI1 associated with?

Answer 78

Smith Magenis/Potocki Lupski

Question 79

What is the locus of Potocki-Lupski?

Answer 79

17p11.2

Question 80

What is the locus of HNPP?

Answer 80

17p12

Question 81

What is the locus of CMT1A?

Answer 81

17p12

Question 82

What is PMP22 associated with?

Answer 82

HNPP/CMT1A

Question 83

What is the location of NF1?

Answer 83

17q11.2

Question 84

What is the location of SRY?

Answer 84

Yp11.31

Question 85

What is the location of SHOX?

Answer 85

Xp22.33

Question 86

What is the locus of Bloom Syndrome?

Answer 86

15q26.1

Question 87

What is the locus of Ataxia Telangietasia?

Answer 87

11q22.3

Question 88

What is BLM associated with?

Answer 88

Bloom Syndrome

Question 89

What is ATM associated with?

Answer 89

Ataxia Telangiectasia

Question 90

What is the locus of Nijmegan BS?

Answer 90

8q21.3

Question 91

What is the location of FMR1?

Answer 91

Xq27.3

Question 92

What is the location of XIST?

Answer 92

Xq13

Question 93

3 X-linked recessive disorders

Answer 93

DMD, BMD, SBMA, Androgen Insensitivity Syndrome

Question 94

3 X-linked dominant disorders

Answer 94

X-linked Alport Syndrome, Intercontinentia Pigmentia, Rett Syndrome

Question 95

Expansion size for Fragile X - full

Answer 95

> 200 rpts

Question 96

Premutation expansion for Fragile X

Answer 96

55-200 rpts

Question 97

Normal allele size for Huntingtons

Answer 97

Less than 27 rpts

Question 98

Intermediate expansion size for Huntingtons

Answer 98

27-35 rpts

Question 99

Incomplete penetrance expansion for Huntingtons

Answer 99

36-39 rpts

Question 100

Fully penetrant expansion for Huntingtons

Answer 100

40+rpts

Question 101

Expansions for juvenile onset Huntingtons

Answer 101

60+rpts