A genetic disorder or a hereditary disease is caused by mutations in the gene or genome of an
individual. It can be passed down through the generations, putting the offspring and family at risk.
In diseases like these, genetics plays a crucial role. The disease process is aided by variations in
our DNA and changes in the functioning of DNA, either alone or in combination, as well as the
environment.
Drug therapy is usually not the first line of treatment for genetic disorders and no prescription
exists to cure them. While no genetic medication has been licensed for use in the treatment or cure
of any inherited human disease, research is still ongoing to develop these drugs. Medications can
be limited to symptomatic relief only. These illnesses are treated rather than healed because they
are permanent. Gene therapy, bone marrow stem cell transplantation, gene transfer, somatic stem
cell therapy, RNA alteration, and, in the near future, embryonic stem cell therapy are all possible
treatments.
Karyotyping is a crucial technique for detecting any abnormalities in the chromosomes of the fetus
or the newborn. Chromosomal banding has been used to identify chromosome anomalies on a
regular basis. Since not all chromosomal aberrations can be detected, researchers have developed
newer methods and techniques such as FISH, M-FISH, and SKY.
Nature's guide to the genetic origin of many mysterious human diseases is chromosomal
anomalies. As a result, cytogenetic methods will undoubtedly remain invaluable resources for
diagnosing genetic disorders and indicating potential care and management options.
Cultivation of KODO MILLET . made by Ghanshyam pptx
Genetic disorders & its detection using Karyotyping
1. Department of Pharmaceutical Sciences and Technology
Birla Institute of Technology Mesra, Ranchi – 835215 (Jharkhand) 2021
GENETIC DISORDERS AND ITS DETECTION USING KARYOTYPING
A project report submitted in partial fulfilment of the requirement for the award of degree Of
BACHELOR OF PHARMACY
BY
Kareena Sinha (BPH/10028/2017)
3. AIMS & OBJECTIVES
The primary goal of this project is to understand the mechanism behind how a
genetic disorder occurs, how it is passed down from parents to their off springs
and what suitable methods are available for the treatment and detection of
genetic disorders.
4. A genetic disorder is a health problem caused by one or
more abnormalities in the genome.
Source: https://phescreening.blog.gov.uk/wp-content/uploads/sites/152/2015/09/inheritance-diagram-620x544.jpg
Fig I - Genetic Disorder Inheritance
5. Hereditary Genes
• Disturbances in storage transmission and production of genetic
information cause genetic disorders.
• Chromosomal and gene mutation in parents is passed down to
offspring. These conditions tend to run in families for generations.
• E.g. Sickle Cell Anemia
Radiation & Other Environmental Factors
• The environment one lives in impacts the body and chromosomal
changes can often also be a result from a combination of
environmental & genetic factors.
• Long term exposure to toxic materials, such as radiation or cigarette
smoke, can often contribute to genetic disorders.
6. • Autosomal dominant
• Autosomal recessive
• X-linked dominant
• X-linked recessive
• Y-linked
• Mitochondrial
Single Gene
Disorder
• Complex or
multifactorial disorders
are conditions that are
caused by a number of
contributing factors.
Multifactorial
Disorders
• Abnormality in number
of chromosomes
• Abnormality in structure
of chromosomes
• Abnormality in sex
chromosomes
Chromosomal
Disorders
TYPES OF GENETIC DISORDERS
7. An overview on a chromosomal genetic disorder
Down syndrome or trisomy is a condition named after a British doctor, John Langdon
Down, in which a child is born with an extra copy of the 21st chromosome. This causes
physical and mental developmental delays and disabilities. Many of the disabilities are
lifelong, and they can also shorten life expectancy.
DOWN SYNDROME
Down syndrome continues to be the most common
chromosomal disorder. Each year, about 6,000 babies are
born with Down syndrome, which is about 1 in every 700
babies born.
<- Graph showing Down Syndrome Children prevalence by
Mother’s age.
Statistic & Graph Source : National Center on Birth Defects & Developmental
Disabilities, Centers for Disease Control and Prevention
8. Source :https://www.physio-pedia.com/images/d/de/DS_features.jpg
Fig II – Down Syndrome Symptoms
Every year on March
21, World Down
Syndrome
Day is observed to
create awareness about d
own syndrome. Official website-www.worlddownsyndromeday.org
Fig III – Down Syndrome Day Logo
Trisomy 21
Mosaic Down syndrome (Mosaicism)
Translocation
CAUSES
OF DOWN
SYNDROME
1
2
3
When a baby’s cell divides and develops, each cell receives 46
chromosomes – 23 from the mother and 23 from the father.
However, in a child affected with Down syndrome, one chromosome
does not separate properly due to which the baby ends up having 3
copies or an extra partial copy of the 21st chromosome. The parents
of the affected individual are genetically normal.
There is lot of stigma and misconception
associated with Down Syndrome which
affects the child as well as guardians.
They need acceptance, friendship and
opportunities like every other human
being.
Source : https://www. downsyndrome.nih.gov
10. 1.Physical therapy includes activities and exercises that help build motor skills, increase muscle strength, and improve
posture and balance. This therapy is important in the child’s early life.
1.Speech-language therapy can help children with Down syndrome improve their communication skills and use language
more effectively. A speech-language therapist can help them develop the early skills necessary for communication.
Occupational therapy includes self-care skills such as eating, getting dressed, writing, and using a computer. An
occupational therapist might offer special tools that can help improve everyday functioning.
1.Emotional and behavioral therapies - Children with Down syndrome may have difficulty in communicating, may suffer
from compulsive behavior or ADHD and other mental health issues. Therapists try to create strategies to avoiding
uncertain situations from occurring, and teach better and positive ways to respond to situations.
TREATMENT
11. KARYOTYPING Karyotype refers to an individual’s collection of chromosomes being examined.
A laboratory technique that entails analyzing a series of chromosomes and creating a picture of the chromosomes that
have been examined. The karyotyping of chromosomes aids in the detection of any mutations or structural defects with
the chromosome.
Fig IV – Preparing Karyotype
Source - https://www.researchgate.net
Fig V – Human Karyotypes
Source - https://media.sciencephoto.com
12. TYPES OF KARYOTYPING
1. Conventional Karyotyping
I. Q Banding (Quinacrine)
II. G Banding (Giemsa)
III. C Banding (Centromere)
IV. R Banding (Reverse)
2. Fluorescence In Situ Hybridization (FISH)
3. Spectral Karyotyping (SKY)
4. Comparative Genomic Hybridization (CGH)
13. • Fluorescent dye ‘Quinacrine’ is used which quenches DNA by
alkylating it.
• It is used to dye chromosomes, which are then analyzed under UV
light.
• Used to investigate chromosomal translocations, especially those
involving the Y chromosome.
• Disadvantage – fluorescence intensity fades quickly.
• Chromosomes in the metaphase stage are treated with trypsin
which digests & degrades the proteins.
• They are then stained with Giemsa dye.
• AT-rich DNA found in heterochromatic areas, which are gene-poor
stain more darkly.
• GC-rich DNA in Euchromatin are transcriptionally active & stain less
Q-BANDING (Quinacrine)
G-BANDING (Giemsa)
CONVENTIONAL KARYOTYPING
https://www.mun.ca/biology/scarr/Fig17_05a.gif
https://upload.wikimedia.org/wikipedia/
Fig VI – Q-BANDING
Fig VII – G-BANDING
14. • Constitutive heterochromatin, or genetically inactive DNA, is stained
with C-banding.
• Specifically used for identifying heterochromatin by denaturing
chromosomes in a saturated alkaline solution followed by Giemsa
staining.
• It's no longer commonly used for medical purposes.
• R-banding produces the reverse of the G-band stain on chromosomes.
• It is obtained by incubating the slides in hot phosphate buffer, then a
subsequent treatment of Giemsa dye.
• Darkly colored R bands are GC rich, and AT rich regions are more readily
denatured by heat.
C-BANDING (Constitutive)
R-BANDING (Reverse)
CONVENTIONAL KARYOTYPING
https://www.researchgate.net/
https://www.researchgate.net/
Fig VIII – C-BANDING
Fig IX – R-BANDING
15. 15
FLUORESCENCE IN SITU HYBRIDIZATION
• Fluorescence in situ hybridization (FISH) is a laboratory
technique for detecting and locating a specific DNA
sequence on a chromosome.
• Chromosomes are exposed to a small DNA sequence or a
probe that has a fluorescent molecule attached to it.
• The probe sequence binds to its corresponding sequence
on the chromosome.
• By looking at the chromosomes under a microscope, a
researcher can find the region where the DNA is bound
because of the fluorescent dye attached to it.
• This information reveals the location of that piece of DNA
in the starting genome.
Fig X – FISH
https://www.genome.gov/
16. 16
SPECTRAL KARYOTYPING
• Spectral karyotype (SKY) involves homologous pairs of
chromosomes having distinctive colors.
• SKY gives each chromosome a different color.
• It makes it easy to determine the chromosome based on its
number.
• The SKY technique also makes it easier for scientists to
detect chromosomal abnormalities, as compared with a
conventional karyotype.
Fig XI – SKY
https://ars.els-cdn.com/content/image/3-s2.0-B9780128028230000134-f13-15-9780128028230.jpg
17. 17
COMPARATIVE GENOMIC HYBRIDIZATION
• Comparative genomic hybridization (CGH) permits the
detection of chromosomal copy number changes without
the need for cell culturing.
• DNA is isolated from two sources to be compared, they are
labelled with fluorophores, denatured so that DNA
becomes single stranded and then the resultant samples
are hybridized together.
• In addition to a fluorescence microscope, the technique
requires a computer with dedicated image analysis
software to perform the analysis.
Fig XII – CGH
https://upload.wikimedia.org/wikipedia/en/thumb/3/32/CGH_schema.jpg/220px-CGH_schema.jpg
18. CONCLUSION
Genetics is a branch of biology that studies the transfer of inherited traits from one
generation to the next. It is a field of science that has the ability to lead to several
new studies that will aid in the treatment, cure, and prevention of genetic
disorders. Genetic testing is an effective method for detecting mutations in a
person's genes. In the field of molecular cytogenetics, new diagnostic methods are
constantly being developed. As these new technologies are implemented in the
clinic, we should expect cytogeneticists to be able to make the leap from
karyotype to gene with increasing efficiency. My conclusion from this reserach is
that genetic disorders may not be curable but early detection and awareness of
the disease can help us in the long run in fighting it.
19. REFERENCE
1. O'Connor, Timothy P., and Ronald G. Crystal. "Genetic medicines: treatment strategies for hereditary disorders."
Nature Reviews Genetics 7.4 (2006): 261-276.
2. O'Connor, C. (2008) Karyotyping for chromosomal abnormalities. Nature Education 1(1):27
3. Trask, B .J. Human cytogenetics: 46 chromosomes, 46 years and counting. Nature Reviews Genetics 3, 769–778 (2002)
4. Down Syndrome: Prenatal Risk Assessment and Diagnosis - DAVID S. NEWBERGER, M.D., State University of New York
at Buffalo, Buffalo, New York Am Fam Physician. 2000 Aug 15;62(4):825-832.
5. National Human Genome Research Institute - https://www.genome.gov/GeneticDisorders/Down-Syndrome
6. Webmd.com – Understanding down syndrome
7. Britannica, The Editors of Encyclopedia. "Genetic testing". Encyclopedia Britannica, 29 Nov. 2018.
8. Caspersson, T., Zech, L., & Johansson, J. Differential banding of alkylating fluorochromes in human chromosomes.
Experimental Cell Research 60, 315–319 (1970) doi:10.1016/0014-4827(70)90523-9