GU BMS141 Lecture 1 & 2 Fall 2024 PDF

Summary

This document is a lecture presentation about chromosomes and chromosomal aberrations. It covers chromosome structure, numbers, and abnormalities, such as trisomies and monosomies, and includes discussion of various diagnostic techniques, including cytogenetic analyses like CMA and FISH. Presented by Prof. Ola Khalifa at Galala University in Fall 2024.

Full Transcript

F A C U L T Y O F M E D I C I N E

F A L L 2 0 2 4
 BMS141 # Lecture 1 & 2 # Genetics
Chromosomes and chromosomal
Aberrations
Ola Ali Khalifa, MD, PhD
Professor and Consultant of Medical Genetics
Medical Biochemistry & Molecular Biology Section
Dept. of Basic Medical Sciences

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Intended Learning Outcomes
By the end of this Lecture, you should be able to:

▪ Define chromosome and describe its structure

▪ Differentiate between numerical and structural
chromosomal abnormalities

▪ Identify different techniques of studying
chromosomes
What are chromosomes?
Chromosomes are thread like structures located in the cell nucleus.
Chroma (=color) and soma (=body).

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 Chromosome Structure
The centromere divides the chromosomes into short and
long arms ,designated p and q.
Morphologically chromosomes are classified according to
the position of the centromere.

Metacentric submetacentric Acrocentric 5
 Chromosome Number
❑In humans, normal cell nucleus contains 46
chromosomes, made up of 22 pairs of autosomes
and a single pair of sex chromosomes (XX and
XY)

❑Human female have two X chromosomes (46, XX),
while males have on X and one Y chromosome
(46, XY)

❑One member of each of these pairs is derived
from each parents.
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Normal male
46, XY
 Normal
female
Normal female
46, XX
46, XX
Terminology CONT’D
Normal numbers of chromosomes in germ cells
(ova or sperm ) is 23= haploid = 1n

Normal numbers of chromosomes in somatic
cells is 46 (23 pairs= diploid= 2n)

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Terminology CONT’D
Polyploid:
Complete set (s) of extra chromosome
e.g {triploid (3n=69), tetraploid (4n=92)}

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Terminology CONT’D

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 Terminology CONT’D
Aneuploidy: loss/gain of single chromosome
Monosomy: Loss of one chromosome (45)
Trisomy: Gain of one chromosome (47)

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Chromosomal Aberrations
Chromosomal
Abnormalities of chromosomes may aberrations
be either numerical or structural and
may involve one or more autosomes,
sex chromosomes, or both

Numerical Structural

Deletion
Aneuploidy Polyploidy Duplication
Translocation

Monosomy Trisomy Triploiody Tetraploidy
(45) (47) (69) (92)
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 Aneuploidy
Most common and clinically significant type of
human chromosome disorders.

Most commonly due to meiotic
nondisjunction.

Most aneuploidy patients have either trisomy
or monosomy.

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Nondisjunction
 Trisomy
Gain of one chromosome

Whole chromosome trisomies are viable for
chromosomes 13, 18, 21, X, and Y.

The most common type of trisomy in live born
infants is trisomy 21 (47, XX or XY, +21)

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47, XX,+21 Down Syndrome

Diagnosed at birth or shortly thereafter by characteristic dysmorphic features 17
Genetic Causes of Down Syndrome
 Trisomies Examples
❖ The most common numerical chromosomal
anomalies found in humans

Trisomy 21 or Down Syndrome

Trisomy 18 or Edward syndrome

Trisomy 13 or Patau syndrome

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 Monosomy
The presence of only one member of a
chromosome pair.

All complete autosomal monosomies
appear to be lethal early in development

Sex chromosomal monosomy, however,
can be viable e.g. Turner syndrome (45, X)

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 Turner Syndrome 45,X

A girl with turner syndrome with characteristic short stature and neck
Chromosomal Aberrations Chromosomal
aberrations

Numerical Structural

Deletion
Aneuploidy Polyploidy Duplication
Translocation

Monosomy Trisomy Triploidy Tetraploidy
(45) (47) (69) (92)
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 Structural Chromosomal aberrations
Many different types of structural chromosomal anomalies
exist, including deletion, duplication, ring chromosome,
isochromosome and translocation.

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Deletion
A portion of the chromosome is missing
or deleted.
Known disorders in humans include
Wolf-Hirschhorn syndrome , and Cri du
Chat syndrome.
Duplication
A portion of the chromosome is duplicated,
resulting in an extra genetic material.
Known human disorders include
Charcot-Marie-Tooth disease
Ring
A portion of a chromosome has broken off
and formed a circle or ring.

This can happen with or without loss of
genetic material.
Isochromosome
Formed by the mirror image copy of a
chromosome segment including the
centromere.
 Translocation
A portion of one chromosome is transferred to another chromosome.

There are two main types of translocations.
Robertsonian Translocation
An entire chromosome has attached to another at
the centromere.

In humans these only occur with acrocentric
chromosomes 13, 14, 15, 21, and 22.
Reciprocal Translocation
Segments from two different chromosomes
have been exchanged
Cytogenetic Diagnostic
Techniques

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 Background
Clinical cytogenetics is the study of chromosomes, their
structure, and their inheritance, as applied to the
practice of medicine.
Today, chromosome analysis with increasing resolution
and precision at both the cytologic and genomic levels
is an important diagnostic procedure in numerous areas
of clinical medicine.
Current genome analyses, including chromosomal
microarrays and whole genome sequencing (WGS),
represent impressive improvements in capacity and
resolution.
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When do we ask for cytogenetic analysis?
Clinical indications for cytogenetic analysis:

Problems of early growth and
development.
Stillbirth and neonatal death.
Fertility problems.
Family history of chromosomal
abnormalities.
Pregnancy in women with advanced age.

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Conventional Karyotype
Photomicrograph of an individual chromosome
arranged in a standard manner.

Any tissue with living nucleated cells, which
undergo division can be used for studying
human chromosomes (circulating lymphocytes,
amniocytes, and bone marrow)

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 Karyotype
Photomicrograph of an individual chromosome arranged in a standard manner

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 Karyotype

Chromosome preparation

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Normal
male
46, XY
What abnormalities can be detected with conventional
karyotyping?

Whole
chromosome
aneuploidy
(trisomy)
Large structural
chromosome
anomalies

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 Conventional karyotyping CONT’D
-G banding at 400 to 550 band stage of resolution
-Arrest cell division during metaphase
-Detects large abnormalities of greater than 5-10MB anywhere in the genome.

Whole
chromosome
aneuploidy
(trisomy) Large structural
chromosome
anomalies
What about deletions smaller than what can be
detected by conventional karyotype??

High resolution banding technique
Division stopped at an early stage of mitosis (prophase or prometaphase).

The chromosomes are still in a relatively uncondensed state.

Detects subtle chromosomal abnormalities.

More detailed banding technique (up to 850 bands or even more in a
haploid set).
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What is the advantage of high-resolution banding?

Detects subtle chromosomal abnormalities that cannot be
detected by conventional karyotyping..

More detailed banding technique.

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Fluorescence In Situ Hybridization
(FISH)

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 What is FISH?
It is a targeted approach to
determine whether specific DNA
sequence as visualized with a
fluorescent probe, is present
within a specific chromosome
prepared on a microscope slide.

This confluence of genomic and
cytogenetic approach is called
molecular cytogenetics.

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 FISH: Background
In FISH, a DNA probe is stained with a special fluorescent stain
specific for either individual chromosome (paint) or very small or
minute chromosomal regions (microdeletions).

FISH analysis can be performed on metaphase cells or on
interphase nuclei.

Its use is limited to targeting a specific genomic region based on a
clinical diagnosis or suspicion.

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Advantages of FISH technique over conventional
karyotype analysis:
Conventional karyotype detects only large aneuploidies or
rearrangements while FISH technique can detect aneuploidies or
rearrangements of any size.

Results of FISH technique can be obtained in a short time
compared to conventional karyotyping.

FISH technology provides much higher resolution and specificity
than G-banded chromosome analysis.

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Fluorescence In Situ Hybridization (FISH)

Interphase FISH Metaphase FISH 49
Chromosomal Microarray
(CMA)

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 CMA: Introduction

CMA has replaced G-banded karyotype
as the frontline diagnostic test to detect
genome-wide copy number imbalances
at higher resolution extending the
concept of targeted FISH analysis to test
the entire genome.

CMA simultaneously queries the whole
genome on a glass slide containing
regularly spaced DNA probes that
represent loci across the entire genome.

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 CMA: Introduction CON'T
This technology detects relative copy number gains
and losses in a genome-wide manner by hybridizing
equal amounts of control and subject DNA to the
DNA probes and calculating the ratio of each DNA
sample hybridized to each probe.

Microarray probes showing equal ratio of subject
and control DNA indicate normal copy number at
the respective genomic loci.

An excess of subject DNA indicates copy number
gain, whereas underrepresentation of subject DNA
indicates copy number loss at the genomic loci
represented by the microarray probes

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 CMA: Advantage
Microarrays have been used successfully to identify
chromosome and genome abnormalities in children with
unexplained developmental delay, intellectual disability, or birth
defects, revealing a number of pathogenic genomic alterations
that were not detectable by conventional G-banding.

This technique has the potential to provide a much more
sensitive , high-resolution assessment of the genome.

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 CMA: Disadvantage
CMA measure only the relative copy number of DNA sequences
but not whether they have been translocated or rearranged from
their normal position(s) in the genome.

Further characterization of copy number variants (CNVs) by
karyotyping or FISH is important to determine the nature of an
abnormality and thus its risk for recurrence for other family
members.

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Chromosomal Microarray
Spectrum of resolution in chromosome and genome analysis
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