S14) Chromosomal Mutations

Question 1

What is cytogenetics?

Answer 1

Cytogenetics is the study of the genetic constitution of cells through the visualisation and analysis of chromosomes

Question 2

What are the benefits of cytogenetic analysis?

Answer 2

• Accurate diagnosis/prognosis of clinical problems
• Better clinical management e.g. hormone treatment for Klinefelter syndrome
• Prenatal diagnosis
• Assess future reproductive risks

Question 3

In terms of constitutional abnormalities, identify some referral reasons for cytogenetic analysis

Answer 3

• Prenatal diagnosis
• Birth defects
• Abnormal sexual development
• Infertility
• Recurrent foetal loss

Question 4

In terms of acquired abnormalities, identify some referral reasons for cytogenetic analysis

Answer 4

• Leukaemia’s (acute/chronic diseases)
• Solid tumours
• Specific translocations/abnormalities

Question 5

Identify and describe two prenatal diagnostic methods

Answer 5

Question 6

Identify 4 birth defects

Answer 6

• Dysmorphism
• Congenital malformations
• Mental retardation
• Developmental delay

Question 7

Which three biochemical techniques are used in cytogenic analysis?

Answer 7

• Karyotyping
• Fluorescent in situ hybridisation (FISH)
• Microarray comparative genomic hybridisation (aCGH)

Question 8

Briefly describe the process of karyotyping (chromosome analysis)

Answer 8

Karyotyping is the systematic sorting of chromosomes:

⇒ Whole genome screen

⇒ Metaphase chromosomes stained, paired up, grouped together

⇒ Abnormalities described using standard nomenclature

Question 9

Outline the steps involved in chromosome analysis

Answer 9

⇒ Count the number of chromosomes

⇒ Identify each chromosome pair

⇒ Assess any missing/extra material

⇒ Recheck all chromosomes independently

Question 10

Provide examples of standard nomeclature for the following:

• Normal female
• Normale male
• Female with trisomy 21
• Male with chromosome 7 inversion

Answer 10

• Normal female – 46,XX
• Normal male – 46,XY
• Female with trisomy 21 – 47,XX,+21
• Male with chromosome 7 inversion – 46,XY,inv(7)(p11.2q11.23)

Question 11

Aneuploidy is a numerical cytogenetic abnormality.

Define it

Answer 11

Aneuploidy is the loss/ gain of whole chromosomes and arise due to errors at cell division in meiosis

Question 12

Identify some examples of aneuploidy where whole chromosomes are lost and identify their associated diseases

Answer 12

• Trisomies – Down syndrome +21, Patau syndrome +13 and Edwards syndrome +18
• Monosomies – Turner syndrome 45,X (X inactivation)

Question 13

What is polyploidy?

Answer 13

Polyploidy is the gain of a whole haploid set of chromosomes (an example of aneuploidy) eg. triploid 3n – 69, XXX

Question 14

What are the causes of polyploidy?

Answer 14

The most common cause of polyploidy is polyspermy i.e. fertilisation of an egg by more than one sperm

Question 15

Aneuploidy is due to non-disjunction during cell division.

Describe how this occurs

Answer 15

Question 16

What is anaphase lag?

Answer 16

• Anaphase lag is when chromosomes are ‘left behind’ at cell division because of defects in spindle function or attachment to chromosomes
• The lagging chromosomes may be lost entirely in mitosis or meiosis

Question 17

What is Down syndrome?

Answer 17

• Down Syndrome is a genetic condition arising due to trisomy 21 (third copy of chromosome 21)
• It manifests with characteristic facial features, intellectual disability, heart defects and increased prevalence of leukaemia

Question 18

What is Edwards syndrome?

Answer 18

• Edwards syndrome is a genetic condition arising due to trisomy 18 (third copy of chromosome 18) in maternal meiosis II
• Babies survive for 5-15 days and it manifests with a small lower jaw, prominent occiput, low-set ears, rocker bottom feet and overlapping fingers

Question 19

What is Patau syndrome?

Answer 19

• Patau syndrome is a genetic condition arising due to trisomy 13 (third copy of chromosome 13)
• Majority die in neonatal period and it manifests with holoprosencephaly, polydactyly and multiple other congenital abnormalities

Question 20

What is Turner’s Syndrome?

Answer 20

• Turner syndrome is a genetic condition occurring when one normal X chromosome is present in a female’s cells and the other sex chromosome is missing / structurally altered (X inactivation)
• It presents with puffy feet, short stature, heart defects, mild learning difficulties, neck webbing, infertility

Question 21

What is mosaicism?

Answer 21

• Mosaicism is the presence of 2/more cell lines in an individual, usually caused by mitotic non-disjunction
• Occurs throughout the body or tissue limited & degree of mosaicism depends on when the error occurred

Question 22

Identify 5 cytogenetic structural abnormalities

Answer 22

• Translocations
• Inversions
• Deletions
• Duplications
• Insertions

Question 23

What are recipocial translocations?

Answer 23

• Reciprocal translocations are usually an exchange of material between nonhomologous chromosomes wherein carriers produce balanced and unbalanced gametes
• If unbalanced offspring will have an abnormal phenotype dependant on regions of trisomy and monosomy

Question 24

What are robertsonian translocations?

Answer 24

- Robertsonian translocations are a rare form of chromosomal rearrangement wherein acrocentric chromosomes break at their centromeres and the long arms fuse to form a single, large chromosome with a single centromere.

• Ther is a chromosome count of 45 in balanced carriers and homologous carriers can’t have normal pregnancy

Question 25

Identify the types of segregation which occur in meiosis I

Answer 25

• Alternate
• Adjacent-1
• Adjacent-2

Question 26

Describe alternate segregation

Answer 26

Question 27

Describe adjacent-1 segregation

Answer 27

Question 28

Describe adjacent-2 segregation

Answer 28

Question 29

What is FISH?

Answer 29

Fluorescent in situ hybridisation is a molecular cytogenetic technique wherein probes are used for specific chromosomes or loci

Question 30

Outline 5 steps ocurring in FISH

Answer 30

⇒ Select target material

⇒ Specific DNA probe (fluorescent label)

⇒ Denaturation & hybridisation

⇒ Washing

⇒ Visualisation

Question 31

What are the different types of FISH probes?

Answer 31

Question 32

Describe the use of microarray comparative genomic hybridisation (aCGH)

Answer 32

• Examines the whole genome at high resolution
• Uses patient DNA not chromosomes
• Compares normal control DNA to patient DNA
• Can’t detect balanced rearrangements
• Not used for mutation detection

Question 33

What are the aCGH referral groups?

Answer 33

• Learning difficulties
• Developmental delay
• Multiple congenital abnormalities
• Normal karyotype
• Balanced / unbalanced karyotype

Question 34

What are the advantages and disadvantages of aCGH?

Answer 34

• Advantages: examines entire genome, detailed information on genes in del/dup region
• Disadvantages: more expensive than karyotyping, doesn’t detect balanced rearrangements, mosaicism may be missed