Introduction, basics & techniques

Question 1

Reasons for genetic referral

Answer 1

For diagnosis/investigation
Family history
Fetal loss
Recurrent miscarriage
Strong family history of cancer

Question 2

Broad types of testing

Answer 2

Prenatal
Carrier
Predictive
Diagnostic

Question 3

How to make a genetic diagnosis

Answer 3

Family tree
Physical examination
Genetic tests: chromosomes (karyotype), genes (DNA testing)

Question 4

Diagnostic genetic test categories

Answer 4

Non-genetic or genetic

Question 5

Examples of non-genetic tests

Answer 5

Bloods - enzyme assay, haematology

X-rays - skeletal dysplasia (achondroplasia)

Question 6

Examples of genetic tests

Answer 6

Genomic architecture - cytogenetics, array based techniques

Gene faults - sequencing, OLA assays, MLPA tests

Question 7

Pharmacogenomics definition

Answer 7

Analysing entire genomes, across groups of individuals, to identify the genetic factors influencing responses to a drug

Question 8

Pharmacogenetics

Answer 8

Studying an individual’s genetic make up in order to predict responses to a drug and guide prescription

Question 9

Drug treatments targeted at genetic faults

Answer 9

Somatic e.g. Gleevec

Germline e.g. RP65

Question 10

Achondroplasia

Answer 10

Affects height - single gene but different heights

Question 11

Single gene modes of inheritance

Answer 11

AD
AR
XL
Mito

Question 12

AD Inheritance affects:

Answer 12

Structural proteins, receptors, transcription factors

Question 13

AD Inheritance applies to:

Answer 13

Myotonic dystrophy
Marfan syndrome
Huntington Syndrome
Chromosome deletion&duplication e.g. 22q11 deletion syndrome

Question 14

Penetrance definition

Answer 14

The frequency with which a specific genotype is expressed by those individuals that posses it, usually given as percentage e.g. 100% Huntington by 80 y.o. but 80% with BRCA1

Question 15

Expressivity definition

Answer 15

Variation in expression - the extent to which a heritable trait is manifested by an individual e.g. Marfans differences or BRCA1 good cause ovarian or breast

Question 16

Anticipation definition

Answer 16

The symptoms of a genetic condition become apparent at an earlier age from one generation to the next - myotonic dystrophy, Huntington’s

Question 17

New dominant / de novo

Answer 17

A new mutation that has occurred during gametogenesis or early embryonic

Question 18

AR diseases e.g.s

Answer 18

CF
Many metabolic
Haemachromatosis
Sickle cell disease

Question 19

XL

Answer 19

Males affected; maybe female from mild to fully
DMD
Fragile X
Red/green colour-blindness
Haemophilia
No male-male transmission

Question 20

Influences to XL expression of phenotype

Answer 20

X inactivation

XL dominant vs XL recessive

Question 21

Lyonisation

Answer 21

Random X-inactivation in cells with more than one X chromosome which compensates for the presence of the double X gene dose - makes a Barr body

Question 22

X-inactivation

Answer 22

Common if two or more X chromosomes
Early in embryogenesis
Random X silenced
Remains inactive forever

Question 23

Types of X-inactivation

Answer 23

50% of cells express the normal gene
Skewed X-inactivation
Tissue variability

Question 24

Skewed X-inactivation

Answer 24

Random preference for normal X chromosome to be inactivated - significant phenotype

Question 25

Tissue variability

Answer 25

Random preference for the X chromosome with the mutation to be active in crucial tissue group e.g. DMD

Question 26

XL Dominant (rare)

Answer 26

Rett Syndrome - not compatible with life in males, phenotype only in females
Fragile X syndrome - females range from asymptomatic to fully symptomatic (due to X-inactivation)

Question 27

XL recessive

Answer 27

Red-green colour blindness
Haemophilia
DMD
Carrier girls usually unaffected but can be significantly because of X-inactivation

Question 28

Mitochondrial inheritance

Answer 28

Maternally inherited diabetes
Deafness
Rare
Equal in M+F
Passed on through mothers egg
Highly variable expressivity
All children of man unaffected

Question 29

Asymptomatic carrier sign

Answer 29

Filled in circle inside

Question 30

Double line

Answer 30

Consanguineous relationship

Question 31

Splits in two from one origin on tree

Answer 31

Twins

Identical twins have a connecting line making it a triangle

Question 32

Diamond in family tree

Answer 32

Unknown sex

Question 33

Consanguinity

Answer 33

Couples who are blood relatives
Share recessive gene mutations
Risk of congenital birth defect (5-6%) vs (2-3%)
Seen in all ethnic groups

Question 34

Genetic testing for a mutation we already know of

Answer 34

Simple and cheap analytical methods can be used

Question 35

Genetic testing for a mutation we do not know identity of

Answer 35

Discovery methods (e.g. Sanger DNA sequencing)
Clonal sequencing

Question 36

Polymerase chain reaction (PCR)

Answer 36

In vitro synthesis of large amounts of DNA by copying small starting quantaties

Question 37

Oligonucleotide definition and use in PCR

Answer 37

Small synthetic primers

Define the boundaries of synthesis

Question 38

Process of PCR

Answer 38

Heat denaturation (94 degrees)
Primer annealling (55 degrees - 3'->5')
Primer extension (72 degrees)
Heat denaturation (94 degrees)
Repeats itself

Question 39

How are PCR products seperated

Answer 39

Gel electrophoresis

Question 40

Analysis of PCR products

Answer 40

Determine presence/absence of product - allele-specific PCR

Determine product size by gel electrophoresis - oloigonucelotide ligation assay or direct sequencing

Question 41

Connexin 26 delta35G assay

Answer 41

Most common inherited cause of deafness

Question 42

Allele-specific mutation detection

Answer 42

Distinguishes between two alleles that may only differ by a single nucleotide
Designed so 3’ end base pairs with changed nucleotide but will not take place if they are not perfectly base-paired hence distinguishing between them

Question 43

CFTR mutations are identified via

Answer 43

Cystic fibrosis genotyping assay.
Genotypes a panel of mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene in genomic DNA isolated from blood

Question 44

Difficulties in mutation analysis

Answer 44

Gene too big for PCR
Hard to deal with repetitive sequencing
GC-rich regions are difficult to PCR

Solution: southern blotting

Question 45

DNA sequencing

Answer 45

Unknown mutations
Ultimate method
Complex and expensive
Determines exact position of mutation
Determines type of mutation
Uses specific PCR product as template

Question 46

Strand synthesis catalyst

Answer 46

DNA polymerase

Question 47

Deoxynucleotides required for DNA sequencing

Answer 47

dATP, dCTP, dGTP, dTTP

BUT also: dideoxynucleotides: ddATP, ddCTP etc

Question 48

What does it look like on sequencing gel

Answer 48

ddTTP, ddGTP lanes
Largest fragments at start (left)
Electric field goes from negative to positive
Exclude the end because of dye blobs - give messy sequence

Question 49

Types of DNA sequencing

Answer 49

Traditional - 16 or 96 capillary

Clonal - 3.5-7GB of reads

Question 50

What DNA is sequenced by clonal sequencing

Answer 50

PCR products
Long PCR product covering part or whole of a gene
Panels of selected genes known to be mutated for a particular phenotype
Very large ‘exome’ panels based on all coding genes

Question 51

Clonal sequencing of gene panels (difficult)

Answer 51

You have bait of cRNA and your genomic DNA
This is target capture
You then use Magbead capture to select the bound oligonucleotides
Wash out the excess stuff
Digest RNA leading to enriched target