UNIT 6 and 7 Molecular Cytogenetics Techniques PDF

Summary

This document provides an outline of techniques in molecular cytogenetics, including Fluorescence In Situ Hybridization (FISH), Comparative Genomic Hybridization (CGH), and Spectral Karyotyping (SKY). It also details the steps for performing karyotyping.

Full Transcript

CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
Unit 6 and 7: Techniques in Molecular Cytogenetics

Outline: ◼ Karyotyping is a test to examine
1.1 Fluorescence In Situ Hybridization chromosomes in a sample of cells. This test
1.2 Comparative Genomic Hybridization can help identify genetic problems as the
1.3 Spectral Karyotyping cause of a disorder or disease

How To Do Karyotyping?
Molecular Cytogenetic Techniques

- FISH: a powerful tool for
identifying the presence of
specific genes or chromosomes
within the cell by attaching
fluorescent tags to DNA
sequences. This is also useful in
detecting abnormalities or gene
- We need to culture cell samples
rearrangements.
and add chemical agents to
- CGH: This method compares the
our culture medium to arrest the
DNA sample to normal control,
cells at their metaphase stage.
identifying variations in DNA
Then, we have to incubate our
copy number, like gains and
cultured medium. After
losses of chromosomal regions.
incubation, we need to harvest
- SKY: This technique allows
the cell sample, fix it on the
visualization of all chromosomes
slide, and stain it. After staining,
in different colors by using a full
we need to conduct
spectrum of fluorescence it
visualization and
helps identify complex
rearrangements of
chromosomal rearrangements
chromosomes.
such as translocations and
inversions.

Chromosomal Banding Techniques

KARYOTYPING

- Karyotyping and Chromosomal
Banding are classic
cytogenetics.
- Karyotyping is used to visualize
and analyze the complete set
of chromosomes.

◼ The chromosomes are depicted (by
rearranging a photomicrograph) in a
standard format known as
a karyogram or idiogram.

MARIANO | BSMLS – 2A 1
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
◼ (1991)-The first application of FISH to plant
FLUORESCENCE IN-SITU HYBRIDIZATION (FISH) cytogenetics was the work of Leitch et al.
(1991)
Fluorescence in-situ hybridization is a
molecular cytogenetic technique that tags Principles of Fluorescence in situ Hybridization
genetic material with fluorescent
molecules. It is a technique for mapping the The basic
location of genes onto chromosomes. elements of
FISH are a
DNA probe
and a target
sequence.
Before
hybridization,
the DNA
probe is
labelled by
various
means, such as nick translation, random
primed labelling, and PCR.
The labelled probe and the target DNA are
denatured.
- FISH can be used to detect
Combining the denatured probe and
small deletions and duplications
target.
that are not visible in
microscope analysis.
- HYBRIDIZATION: Fish relies on the
- Uses a very small chemical that principle of hybridization where
glows brightly when it detects
a single-stranded DNA probe
the specific region in a binds to its complementary
chromosome.
sequence in the target DNA.
- SPECIFICITY: The probe is
designed to bind only to its
History specific target sequence
ensuring high specificity in
The technique detecting the target DNA.
was first - FLUORESCENCE: The probe is
developed in
labeled with a fluorescent
1982. But its
molecule or we call it
use and
fluorophore allowing
application
came more visualization of the target
into play after sequence under a fluorescence
1990 because microscope.
by then easily accessed probe generation
and detection methods and many other
techniques were introduced. Indications for FISH

History and Development Diagnosis
1. Culture not successful
◼ (1969)- In situ
hybridization - For example, when the
technique was
traditional karyotyping fails.
developed by
Traditional karyotyping failure
Joseph G Gal
and Mary Lou requires growing cells in the
Pardue and culture so in the event that the
John et culture was not successful, we
al.(1969) could perform FISH.
◼ (1985)- The non isotopic in situ hybridization
using biotin labeled DNA probes was first
introduced in plant species by Rayburn and 2. Expected abnormality not
Gill seen

MARIANO | BSMLS – 2A 2
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
3. To confirm a suspected
abnormality
- The sequence of the probe is
4. To detect a cryptic
complementary to the
translocation
To monitor response to treatment sequence of interest in the
Engraftment in sex – mismatched BM target DNA, meaning the
transplant nucleotides of the probe will
pair up with the opposite bases
- In cases of bone marrow on the target sequence. Probe
transplant, FISH can be used to is like a search tool that
monitor the engraftment of attaches to a matching DNA
donor cells especially in sex- sequence in a sample allowing
mismatched transplants where Y scientists to detect or study the
chromosome specific probes part of your DNA.
can be used. - The length of the probe
depends on the sequences that
were going to be detected.
Sample Type - If we are going to detect smaller
sequences, we use shorter
◼ 1. Frozen sections probes.
- If we are going to detect larger
- Tissues that have been cryo- chromosomal regions, we use
preserved. longer probes.
- Probes can be labeled in
different ways to allow
◼ 2. Paraffin-embedded sections detection. Labelling is a crucial
step coz it helps in detecting
- Commonly used in physiological DNA sequences when target
or pathology laboratories where samples are hybridized.
tissues are preserved in a - Primary methods for probe
paraffin wax. Special critic main labeling;
steps are required to remove Indirect: incorporation
the paraffin and digest the of hapten (fluorescent
tissue to allow probe tag but they are
penetration. essential for increasing
sensitivity and
amplifying the
◼ 3. Cells in suspension detection signal (e.g.
biotin and digoxigenin)
- Examples are blood, bone to the DNA. It also
marrow, amnio-sites and salines. requires secondary
It requires specific processing detection using
steps to ensure proper cell fluorescent -labeled
morphology and chromosome antibody
spreading. (fluorochromes,
rhodamine, Texas Red,
fluorescein)
What are Probes?
Direct: do not require
◼ Probe is a synthesized fragment of DNA or secondary detection
RNA of variable length which can be because the
radioactively labeled fluorochrome directly
◼ The size maybe varies from 100-1000 bases attached to the probe
long. nucleotides. Since it is
◼ The probe thereby hybridizes to single- directly attached, there
stranded nucleic acid (DNA or RNA) whose is a direct visualization
base sequence allows probe-target base after the fluorescent
pairing due to complementarity between excitation.
the probe and target.

MARIANO | BSMLS – 2A 3
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
◼ the probe is tagged (or "labeled") with 2. Whole chromosome
a molecular marker of either radioactive or
fluorescent molecules.
- Cover the entire length of a
- Specific tags thar are commonly chromosome.
used with these probes - Used to visualize an entire
- TAGS w/c are also as markers or chromosome making it easy to
labels or molecules attached to detect large structural changes
the probes to help us where like translocations or complex
they bind. In both direct and rearrangements.
indirect, these tags are crucial - Example: a probe for the whole
for visualizing the probe’s chromosome, can help detect
hybridization to specific involvement in a translocation
sequences of DNA. with another chromosome.
- Most commonly used tags for
FISH: (1) fluorescent molecule
(modern probes are labeled 3. Unique sequence
with fluorescent dyes). When
these probes hybridize with the
- Probes bind to specific genes or
target DNA, the bound probes
unique DNA sequences in the
emit light under a fluorescence
genome.
microscope allowing for
- Used to detect specific genes or
visualization. (either direct and
unique chromosomal loci.
indirect) (2) Haptens which we
- Example: detection of BCR-
use in indirect labeling. (Biotin -
ABLG fusion in the chronic
detected using streptavidin
myeloid leukemia.
which binds tightly to biotin and
is linked to a fluorescent dye or
enzyme for signal detection.
Digoxigenin – detected using
anti-digoxigenin antibodies w/c Types of Probes
are attached to fluorescent
dye/fluorochrome/enzyme to - Refer to more specific
produce visible signals. classifications within each
category that is often based to
probe’s structure, design or
Categories of Probes application.
- Suit in particular experimental
- Refer to broad classification based on needs or analytical methods
the function or genomic target of the
probe. It describes the kind of
information the probe provides and
what part of the genome it is designed 1) Locus-specific probes – a type of unique
to bind. sequence probe; used to determine the
presence or absence of the
1. Repetitive sequence rearrangements of specific genes making
them highly useful in diagnosing genetic
disorders, and cancer and identifying
- Probes w/c target repetitive specific gene mutations.
DNA sequences that are found
throughout the genome. (ex: 2) Alphoid or centromeric repeat probes –
centromere and telomere a type of repetitive sequence probe;
contain highly repetitive DNA primarily used to detect aneuploidy by
identifying the presence and absence of
sequences.
specific chromosomes. A probe for the
- Use in chromosome
centromere of chromosome 21 can be used
enumeration and to identify to detect Trisomy 21.
specific chromosomal regions.
3) Telomere probes – a repetitive sequence
probe; used to study the integrity of

MARIANO | BSMLS – 2A 4
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
telomeres and to detect structural changes
involving the end of your chromosome like
translocation. (ex: telomere shortening in - Identify first the DNA sequence
diseases like Dyskeratosis Congenita) that we want to visualize and
then after that we prepare our
4) Whole chromosome probes – under whole samples by fixing 5%
chromosome probe/chromosome paraformaldehyde to preserve
libraries/chromosome paints; paint the their structure and DNA integrity.
entire chromosome making them useful for - DENATURATION: heating the
identifying structural abnormalities like double-stranded DNA in the
translocations, large deletions, and sample so that two strands will
duplications in chromosomes. separate becoming a single-
stranded DNA. It is crucial
for allowing the probe to bind to
its complementary DNA
sequence during hybridization.
- The sample is often heated in a
controlled environment which
disrupts the hydrogen bonds
between the DNA strands that’s
why it is converted to single-
stranded DNA.

◼ Step II – Hybridization
Types of FISH Application of
probe DNA to
slide &
overnight
incubation at
37°C
Binding of
probe DNA to
target DNA.

- The labeled single-stranded
DNA probe is applied to the
prepared sample often
containing cells or
chromosomes.
- Occurs moist-warmed
Process of Fluorescent In Situ Hybridization environment ensuring the probe
can be able to bind to its target
◼ Step I – Denaturation sequence.
Conversion of - Usually the cells are incubated
double- under specific conditions to
stranded DNA allow the probe to hybridize to
into single- its complementary target
stranded DNA. sequence in the DNA (usually
incubate at 37 degrees Celsius
and incubate overnight)

◼ Step III – Post-hybridization washing &
detection
Washing of unbound probe DNA.
Application of counter stain

MARIANO | BSMLS – 2A 5
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025

- Observing the hybridized
sample under a fluorescence
microscope. The fluorescent-
labeled probe will emit light
- The main goal is to remove the when exposed to appropriate
unbound or non-specifically wavelengths allowing scientists
bound probes. The cells are to see where the probe has
washed using a series of washes bound to the target DNA.
with increasing stringency. This is - Patterns of fluorescence will be
to ensure only probes bound to observed and then as well as
the target DNA remain. abnormalities will be analyzed
- After the washing technique, based on the signals emitted by
we can apply counter stain and the fluorescence probes.
after that detection na.

- Target sample: the biological
material such as our cells, tissue
◼ Step IV – counter stain
Application of sections, and body fluids from
counter stain. which we are studying or
analyzing the DNA. In short
words, the target sample
contains or source of the target
- DAPI (4’6 – diamidino – 2 – DNA.
phenylindole) will bind to the - Target DNA: refers to the specific
DNA and stains the entire sequence of DNA w/in the
chromosome providing of visual sample that a probe is designed
context for fluorescent signal to locate and bind to during a
from the probe. So, basically, molecular hybridization
the counter stain will make it experiment. It is the portion of
easier for us to visualize the DNA that we are interested to
overall structure of the study or identify. Target DNA is
chromosome under the present in the cell or tissue being
microscope. analyzed. Exist within target
- The stained DNA will appear sample.
blue under a fluorescence
microscope.

◼ Step V – Visualization
visualization
using
fluorescence
microscopy.

Interpretation of Results

MARIANO | BSMLS – 2A 6
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
Each fluorescently labeled probe that hybridizes to
a cell nucleus in the tissue of interest will appear as a
distinct fluorescent dot. - For Deletion Fusion Signal
patterns, if it is normal, there is a
✓ Diploid nuclei will have two dots mix of red and green signals
✓ If there is duplication in the region of interest, that are fused or overlapped
the gain will result in more than two dots indicating intact regions. If we
✓ If there is a loss in the region of interest, one compare it to normal break-
or zero dot will result apart signal patterns, there is a
✓ If a small deletion is present in the region yellow appearance while in
complementary to the probe, the probe will normal deletion fusion, there are
not hybridize two distinct signals (red and
✓ If a duplication is present, more of the probe
green) indicating the genes are
can hybridize.
not fused. There is no fusion.
- In Abberant Break-apart Signal
pattern, there are two
separated signals (1 red, 1
green), indicating there is
a chromosomal break-apart
whereas, in Abberant Deletion
Fusion, the green signals
combine which indicates that
genes have been joined
together.
- For 3 Color Break-apart Signal
- For deletion signal patterns, if Patterns, if it is normal, it involves
we compare to normal a combination of three different
deletion, there are two pairs of colors (red, green, blue or
signals, 1 green and 1 red, yellow) which are very close to
indicating there is no deletion. each other. In Aberrant, three
While in the Abberant Deletion, colors are separated which
only 1 set of red signal is indicates a break or
observed, there is a missing rearrangement involving
color which suggests a deletion multiple chromosomal regions.
in one copy of chromosome. - For Translocation Dual Fusion
- For Break-apart Signal patterns, Signal Patterns, if it is normal, 2
if it is normal, there are two sets pairs of green and red signals
of overlapping signals are are present indicating that no
present appearing yellow (red translocation has occurred. In
and green signals) due to the Aberrant, the separation of
close proximity of the two colors green and red signals indicates
thus indicating there is no a translocation event resulting in
chromosomal break apart. the fusion of chromosomal
While in Abberant Break-apart patterns.
signal patterns, the green and
red signals are separated thus
indicating there is
a chromosomal break. Stringency Conditions and Controls
- For Amplification Signal Patterns,
2 pairs of red and green signals Stringency Conditions: temperature, salt
are present representing normal concentration, and other factors that affect
unaltered chromosome radios. the stability of the hybridization reaction
But for Abberant Amplification Controls:
patterns, multiple red signals are - Positive controls, such as
present which indicate probes known to hybridize to
amplification or increase in the specific regions
number of copies of the target
DNA sequence.

MARIANO | BSMLS – 2A 7
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
- Negative controls, such as 3. Due to Failure to detect signal FISH is higher
probes should not hybridize to sensitive for trisomy but less sensitive foe
the target. detecting chromosome loss or deletion.
4. Cytogenetic data can be obtained only for
the target chromosomes thus FISH is not a
good screening tool for cytogenetically
heterogeneous disease.
5. Requires fluorescence Microscopy and an
image analysis system.

Hybridizer

Applications of FISH

Diagnostic:
◼ The identification of specific chromosome Fluorescent Microscope
abnormalities.
◼ The characterization of marker
chromosomes.
◼ Interphase FISH for specific abnormalities in
cases of failed cytogenetics.
◼ Monitoring disease progression
◼ Monitoring the success of bone marrow
transplantation.
Research:
◼ The identification of new non-random
abnormalities (by M-FISH or SKY).
◼ Gene mapping COMPARATIVE GENOMIC HYBRIDIZATION (CGH)
◼ Identification of regions of amplification or
deletion by CGH. is a molecular cytogenetic method for
◼ The identification of translocation analyzing copy number variations with the
breakpoints help of hybridization technique.
◼ The study of 3D chromosome organization in
interphase nuclei.
- Used for the analysis of gains or
losses in the DNA content of test
Advantages of FISH
samples
- First described in 1993 by
✓ Rapid technique and large number of cells
can be scored in a short period. Kallioniemi and colleagues.
✓ Efficiency of Hybridization and deletion is
high. Sensitivity and specificity are high.
✓ Cytogenetic data can be obtained from
non-dividing or terminally differentiated Principle of CGH
cells.
✓ Cytogenetic data can be obtained from ◼ CGH is based on the principle
poor samples that contain too few cells for of competitive fluorescence in situ
routine cytogenetic analysis. hybridization (FISH). In this technique, DNA
from the test and reference samples are
Limitations of FISH labeled with different fluorescent dyes,
typically red and green, respectively. These
1. Restricted to those abnormalities that can
labeled DNA fragments are then denatured
be detected with a currently available
and allowed to hybridize to a metaphase
probe.
2. Only one or a few abnormalities can be spread of chromosomes from a normal
assessed simultaneously. individual.

MARIANO | BSMLS – 2A 8
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025

- Based on co-hybridization of
different legal tests and
reference DNA onto metaphase
spreads.
- The signal intensity ratios of the
two fluorescent labels along the
chromosome then reflect DNA
copy number changes in test
DNA relative to the reference
DNA.
- Basically, this principle explains
how deletion and duplications
are identified. Detecting Copy Number Variations
- Deletion: using a red probe for
Reference DNA; and a green ◼ CGH is particularly useful for
probe for test DNA; the intensity detecting CNVs, which are variations in the
of the red probe which targets number of copies of specific DNA segments.
the deleted region will be These variations can range from small
lowered in the test DNA bcoz deletions or duplications of a few genes to
there is less target DNA in which large-scale gains or losses of entire
the red probe will bind to. chromosomes.
- Duplication: Since there is an
extra copy of chromosome,
there are many regions where in - These are alterations of the DNA
red probe will bind to so the of a genome that results in the
signal intensity will reflect cell having an abnormal copy
an increase in red signal of cells of one or more sections
compared to green signal. of DNA.

The intensity of the fluorescent signals along
each chromosome is then analyzed. If the
test sample contains more copies of a ◼ Deletions: A deletion occurs when a
particular DNA segment than the reference segment of DNA is missing from the test
sample, the red signal will be stronger in that sample compared to the reference. This will
region. result in a stronger green signal in the
corresponding region of the chromosome.
Conversely, if the test sample has fewer
copies, the green signal will be stronger.
Regions with equal copy numbers in both Why red signal is stronger?
samples will show a yellow signal, indicating - If a segment of your DNA is
a balanced hybridization. present in multiple copies in the
test sample, there will be more
of the target sequence of red
Fluorescence Signal Interpretation probes to bind to. So, more
binding sites for red probes
1. Equal signals (indicates balanced that’s why the red signal is
hybridization; there are no copy variations stronger.
on the regions of DNA.)
2. Increased green signal (indicates deletion)
3. Increased red signal (indicates duplication)

MARIANO | BSMLS – 2A 9
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025

After labeling, these two labeled DNA
Why green signal is stronger?
are combined with the presence of
- If a segment of DNA is missing unlabeled Cot-1 DNA (placental DNA
from the sample, there will be that is enriched for repetitive DNA
less target sequence for the red sequence; used for blocking or
probe to bind to. This means suppressing repetitive sequences which
that there are more green are commonly detected in telomere
probes will remain anode and centromere region). After
resulting to a stronger green combining, the next process is
denaturation. The reason why DNA
signal in that region.
needs to undergo denaturation, it’s
because it prepares the DNA sample for
hybridization. During denaturation,
double-stranded DNA is separated into
◼ Duplications: A duplication occurs when a
single strands by breaking the hydrogen
segment of DNA is present in multiple copies
bonds between complementary bases.
in the test sample compared to the
This will allow labeled test and reference
reference. This will result in a stronger red
DNAs to hybridize with their
signal in the corresponding region of the
complementary sequences on the
chromosome.
target DNA.

Procedures of CGH The next step is hybridization, incubating
the slide containing the test and
reference DNA in a moist chamber for
48 - 72 hours. After hybridization, wash
slide and apply counter stain which is
DAPI (4’6 – diamidino – 2 –
phenylindole). After counterstaining,
next is the visualization. Observe slide
under fluorescent microscope equipped
with probe cct camera with specific
optical filter sets (consist of triple-band
past beams splitter, triple-band past
emission filter, single-band excitations
filter)

WORKFLOW
CGH begins with the isolation of
genomic tumor DNA or test DNA and
normal genomic DNA or reference DNA.
After isolating the two DNAs, these two
are labeled with two different
fluorochrome. For genomic tumor
DNA/test DNA, this will be labeled using
green fluorochrome in which is the
commonly used is Fluorescein
Isothiocyanate (FITC). For reference
DNA, we use red fluorochrome which is
the tetramethyl rhodamine
isothiocyanate (TRITC) to label them.

MARIANO | BSMLS – 2A 10
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
Applications of CGH Array CGH: A High-Resolution
Alternative/Chromosomal Microarray Analysis or
◼ This technology was first developed as a Microarray-Based Comparative Genomic
research tool for the investigation of Hybridization
genomic alterations in cancer.
◼ Array CGH (aCGH) is a more advanced
◼ It allows for a high-resolution evaluation of version of CGH that uses DNA
DNA copy number alterations associated microarrays instead of metaphase
with chromosome abnormalities. chromosomes. Microarrays contain
thousands or millions of DNA probes that are
◼ It provides clinicians with a powerful tool to designed to target specific regions of the
use in their increasingly sophisticated genome. This allows for a much higher
diagnostic capabilities. resolution, typically in the range of 100
kilobases or less.
◼ The use of CGH is considered EXPERIMENTAL ◼ aCGH has become the gold standard for
AND/OR INVESTIGATIONAL when performed detecting CNVs in clinical and research
in the absence of symptoms or high-risk settings. It offers several advantages over
factors for a genetic disease or when traditional CGH, including:
knowledge of genetic status will not affect Higher resolution: aCGH can detect
treatment decisions or screening for the smaller CNVs and those located closer
disease. together.
Increased sensitivity: aCGH is more
◼ Screening for prenatal gene mutations in sensitive than traditional CGH, meaning
fetuses without structural abnormalities or it can detect CNVs that may be missed
testing products of conception after AI. by traditional methods.
(Artificial Insimination) – the focus is slightly Automation: aCGH is highly
on rare genetic testing via methods like non- automated, which reduces the risk of
invasive prenatal testing to detect human error and allows for faster
mutations processing of samples.

◼ Diagnosis of melanoma.

◼ It helps in the detection of balanced
rearrangements of chromosomes and for
the comparison of normal and suspected
DNA samples.

Limitations of CGH

◼ While CGH is a powerful tool for detecting
CNVs, it has some limitations:

Resolution: Traditional CGH has a relatively low
resolution, typically in the range of 5-10 megabases.
This means that it may not be able to detect small - The test and reference DNA are
CNVs or those located close together.
labeled with fluorescent dyes
- CGH cannot detect
and applied to the microarray.
translocations and inversions.
Then, these 2 DNAs are
Balanced rearrangements: CGH cannot detect
balanced chromosomal rearrangements, such as hybridized to your microarray.
translocations or inversions, because these do not Then, the microarray scanner
alter the copy number of DNA segments. measures fluorescent signals
and the computer software
Technical challenges: CGH requires specialized analyzes the data and
equipment and expertise, and the interpretation of generates a plot.
results can be complex. - In aCGH, we don’t need to
undergo denaturation.

MARIANO | BSMLS – 2A 11
CYTOGENETICS
College of Allied Health Sciences
Bachelor of Science in Medical Laboratory Science
1st Semester | A.Y. 2024-2025
Spectral Karyotyping (SKY)

◼ Spectral karyotyping is cytogenetical
technique used to simultaneously visualize
all the pairs of chromosomes in an organism
in different colors.
◼ The sky technique is useful for identifying
chromosomal abnormalities.
◼ We can arrange the chromosomes
according to their number just by
visualization of different colours aquire by
the chromosomes.

Application of SKY

◼ This technology allows the isolation of
structural chromosome abnormalities
◼ which then allows determination of the
precise molecular address of chromosome
breakpoints associated with deletions
translocations and insertion.
◼ SKY can discern the aberrations that can’t
be detected very well by conventional
banding technique and Fluorescent in
situ hybridization (FISH).
◼ It allows visualization of all chromosomes in
different colours on same platform which is
very easy to detect chromosomal
abnormalities.

CONCLUSION
◼ Chromosomal genetic abnormalities are
the hidden cause for the huge economic
losses.
◼ Molecular cytogenetic techniques like FISH,
CGH and SKY are the available advanced
diagnostic tools to detect such
chromosomal abnormalities and to prevent
the spread in the population which
indirectly avoid the economic
consequences.

MARIANO | BSMLS – 2A 12