Cytogenetics DSR - Harris Fall 2024 PDF

Summary

This presentation, likely from William Carey University, covers cytogenetics and chromosome abnormalities. It includes learning objectives, details on chromosomal anatomy and terminology and types of abnormalities such as trisomies and deletions.

Full Transcript

Clinical Cytogenetics
(DSR)
(Reference: Medical Genetics, Chapter 6)

OMS 6111: MEDICAL GENETICS

DR. RANDALL HARRIS
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Chromosome Abnormalities

Important cause of morbidity and mortality
Occur in as many as 1 in 150 live births
Leading known cause of:
◦ Intellectual disability
◦ Pregnancy loss (spontaneous abortions)
◦ 50% in first trimester
◦ 20% in second trimester
Types of chromosome
abnormalities

Abnormalities in chromosome number
◦ Trisomies, Monosomies
◦ Cause: Nondisjunction events during
Anaphase I or II of meiosis

Abnormalities in chromosome structure
◦ Translocations, Deletions, Duplications
◦ Cause: Improper chromosome
recombination during Prophase I of
meiosis
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
Chromosome anatomy
 Chromosome terminology and
notation
Major regions and bands are systematically numbered,
starting at the centromere and moving towards the
telomeres (banding patterns are established by various
staining procedures)
Centromeres are designated as p10 and q10 by
convention
◦ Letter = short or long arm
◦ First number = region
◦ Second number = band

“14q32” = second band in the third region of the long
arm of chromosome 14
Sub-bands can be indicated by decimals (14q32.3)
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Methods of chromosome analysis

Karyotyping FISH CGH/microarrays
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Abnormalities in chromosome
number
Euploidy (“good set”)

◦ Chromosome number is a multiple of 23 (in humans)

◦ Haploid gametes and diploid somatic cells are both euploid
Polyploidy

◦ The individual has a complete extra set of chromosomes (can be any number of sets:
triploid, tetraploid, etc.)
◦ Results in seedless fruits in plants but spontaneous abortion in humans (generally)
Aneuploidy

◦ Total chromosome number is NOT a multiple of 23

◦ Monosomy: one of the chromosome pairs is present in only ONE copy

◦ Trisomy: one of the chromosome pairs is present in THREE copies
 Abnormalities in chromosome
number
Autosomal monosomies are almost always
incompatible with life
Autosomal trisomies are also problematic but can
be compatible with life
◦ MOST COMMON IN LIVE BIRTHS: 21, 18, 13
Basic rule of thumb: “The body can tolerate excess
genetic material more readily than it can tolerate a
deficit of genetic material.” (Medical Genetics)
Most common cause of aneuploidy is
nondisjunction during meiosis
 NORMAL disjunction
during Meiosis I and II

Important features of meiosis:
Synapsis during Prophase I

Anaphase I: Separation of homologous
chromosomes (paternal vs. maternal)

Anaphase II: Separation of sister chromatids
(splitting at the centromere)

Normal haploid gametes
produced
Compare the trisomic
offspring generated by a
nondisjunction in Meiosis I
with the trisomic offspring
generated by a
nondisjunction in Meiosis II: in
the first case, the offspring
has both a paternal and a
maternal copy of the
chromosome that is
duplicated (two DIFFERENT
chromosomes), whereas in
the second case, the
offspring has two of the SAME
chromosome (in this case,
two copies of the pink
chromosome).
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Trisomy 21 (Down
syndrome)
Karyotype: 47, XY, +21
(sex is irrelevant in this
karyotype)
Frequency: 1 in every 800
to 1000 live births (most
common autosomal
trisomy resulting in live
births)
5 A’s of Down
syndrome
◦ Advanced maternal age
◦ Atresia (duodenal)
◦ Atrioventricular septal
defect
◦ Alzheimer disease
(early onset)
◦ AML (5
 Trisomy 21

Accounts for about 10% of all cases of intellectual
disability in the U.S.
With interventional care (including surgical):
◦ 80% will survive to age 10
◦ 50% will survive to age 50
Males are usually sterile; females can reproduce but 40%
fail to ovulate
Females with Down syndrome have a 50% risk of
producing trisomic offspring (through production of n+1
gametes) BUT the risk of spontaneous abortion is the
same as in other females (so overall risk is lower)
◦ SO…Most cases of trisomy 21 are regarded as de
 Mechanism of Trisomy 21
95% of cases are caused by nondisjunction, usually in the mother and usually in
Meiosis I
Mosaicism is possible – the extra chromosome 21 can be lost from some cells
during mitosis in early embryogenesis (Often results in a milder phenotype)
Up to 40% of the genes on chromosome 21 currently have no known purpose
Candidate genes: Important region seems to be 21q21 to 21q22.3
◦ Looking for “dosage-sensitive genes” – causing problems when present in too
many copies
◦ DYRK1A: candidate gene for intellectual disability; causes learning and memory
problems in mice when it is overexpressed
◦ DSCR1 (Down syndrome critical region gene 1): overexpressed in the brains of
Down syndrome fetuses; plays a role in CNS development
◦ APP: amyloid beta precursor protein; associated with some cases of Alzheimer’s
disease
 Trisomy 18 (Edwards
syndrome)
Major clinical characteristics
◦ SGA (due to prenatal growth
deficiency)
◦ Characteristic facial features
◦ Distinctive hand abnormality
◦ Small ears and mouth
◦ Short sternum
◦ Congenital heart defects (especially
VSDs)
◦ Omphalocele
◦ Diaphragmatic hernia
More severe developmental difficulties
than children with Down syndrome,
including an inability to walk
independently
Second most common autosomal trisomy
resulting in live births
 Trisomy 13 (Patau syndrome)

Karyotype: 47, XY, +13
Extremely distinctive
characteristics
◦ Oral-facial clefts

◦ Microphthalmia

◦ Postaxial polydactyly

◦ CNS, heart, and renal
abnormalities

Third most common
autosomal trisomy
resulting in live births
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
When do most structural abnormalities
occur?

Unequal crossing over due
to improper synapsis
(random)
Toxic agent exposure that
causes increased breakage
and rejoining of
chromosomes
 Two major types of structural
abnormalities
Balanced: no gain or loss of genetic material in the chromosome
rearrangement
◦ Usually does not cause problems in the carrier of the
abnormality – but may be inherited by offspring and cause
serious problems
◦ Translocations, isochromosomes, inversions
Unbalanced: causes a gain or loss of genetic material
◦ Typically always problematic in the carrier of the abnormality AND
their offspring
◦ Deletions, ring chromosomes, subtelomeric rearrangements,
duplications
 Translocations
Exchange of genetic material between two non-
homologous chromosomes
Balanced translocations are among the most common
chromosomal abnormalities (as high as 1 in 500)
Reciprocal translocations
◦ Breaks occur in two different chromosomes and there
is a mutual exchange
◦ Leads to derivative (der) chromosomes

◦ The carrier of the translocation is usually
normal
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Robertsonian
translocations
The short arms of two
nonhomologous chromosomes
are lost, and the remaining long
arms fuse to form a single new
chromosome
Occurs only in the acrocentric
chromosomes (13, 14, 15, 21,
and 22)
A carrier who has this
translocation is normal, but the
karyotype will have only 45
chromosomes
 Familial Down syndrome
Accounts for up to 5% of all Down syndrome cases
Robertsonian translocation of 14q and 21q
No correlation with increased maternal age
The presence of a Robertsonian translocation in one parent
does correlate to the risk of Down syndrome in a Mendelian
fashion
Typical carrier karyotype:
– 45, XY, der(14;21) (q10,q10)
Mechanism of Familial Down
Syndrome
 Familial Down Syndrome
without a Robertsonian
translocation

isochromos
ome
 Learning objectives
1.Describe the anatomy of a chromosome with respect to landmarks and genetic
notation conventions.
2.Describe how karyotyping, FISH, and CGH are used in cytogenetic analysis.
3.Describe how nondisjunction during meiosis can lead to different forms of aneuploidy.
4.Recognize major elements of the phenotypes associated with trisomy 21, trisomy 18,
and trisomy 13.
5.Differentiate between balanced and unbalanced chromosomal structural
abnormalities.
6.Describe how Robertsonian translocations and isochromosomes occur, and their
potential role in familial Down syndrome.
7.Recognize major elements of the phenotypes associated with deletion syndromes
such as Cri du chat and WAGR syndrome.
 Deletions

Chromosome breaks with loss of genetic material
Terminal deletion: includes tip of chromosome
Interstitial deletion: two internal breaks that join with a
loss of material in between
Autosomal deletion syndromes are the most
common group of clinically significant
chromosome structural abnormalities
 Cri-du-chat syndrome

Also known as 5p deletion syndrome
Distinctive cry in infants – becomes less obvious
after 2 years of age
Deletion of the distal short arm of chromosome 5
– Length of the deletion can vary

Frequency is 1 in 50,000 live births
Phenotype: intellectual disability, microcephaly, and
characteristic facial appearance
– Some patients have milder mental effects depending
on the size of the deletion
 Cri-du-chat syndrome
In 80% of cases the chromosome with the deletion can be
traced back to the father
The deleted region can contain many genes
– CTNND2 (delta-catenin)
◦ Important protein in the process of neuronal migration
during embryogenesis
◦ Also important for proper functioning of synapses in the
developed brain
– TERT (telomerase reverse transcriptase)
◦ Involved in regulation and replacement of the ends of
chromosomes (telomeres)
 Microdeletion syndromes
Only detectable after the development of high-resolution banding, FISH,
and CGH

Example: 70% of Prader-Willi/Angelman patients have microdeletions in
15q
◦ Typically a consistent 4 Mb deletion
◦ Determined by low-copy repeat sequences at the boundaries of the
deletion which promote unequal crossing-over, leading to the deletion

Contiguous gene syndrome
◦ Syndrome resulting from deletion of adjacent genes on a chromosome,
each causing a different facet of the syndrome
◦ WAGR syndrome (11p deletions)
◦ Wilms’ tumor (tumor of the kidney)
◦ Aniridia
◦ Genitourinary abnormalities
◦ Intellectual disability (Mental Retardation)
 Generalizations of chromosomal structural
abnormalities
1. Most result in developmental delay or intellectual disability
– As many as 1/3 of all human genes play some role in CNS
development
2. Most involve alterations of facial morphogenesis that produce
characteristic facial features
3. Most produce growth delays
4. Most exhibit accompanying congenital malformations (pleiotropic
effects)