pcr pcr applications

Polymerase Chain Reaction Polymerase Chain Reaction (PCR) and Its Applications(PCR) and Its Applications

by RAHUL GAUTAM

What is PCR?What is PCR?

It was invented in 1983 by Dr. Kary Mullis, for which he received the Nobel Prize in Chemistry in 1993.

PCR is an exponentially progressing synthesis of the defined target DNA sequences in vitro.

What is PCR? : What is PCR? : Why “Polymerase”?Why “Polymerase”?

It is called “polymerase” because the only enzyme used in this reaction is DNA polymerase.

What is PCR? : What is PCR? : Why “Chain”?Why “Chain”?

It is called “chain” because the products of the first reaction become substrates of the following one, and so on.

What is PCR? : What is PCR? : The “Reaction” ComponentsThe “Reaction” Components

1) Target DNA - contains the sequence to be amplified.

2) Pair of Primers - oligonucleotides that define the sequence to be amplified.

3) dNTPs - deoxynucleotidetriphosphates: DNA building blocks.

4) Thermostable DNA Polymerase - enzyme that catalyzes the reaction

5) Mg++ ions - cofactor of the enzyme

6) Buffer solution – maintains pH and ionic strength of the reaction solution suitable for the activity of the enzyme

The ReactionThe Reaction

THERMOCYCLERPCR tube

DNA copies vs Cycle number

0

500000

1000000

1500000

2000000

2500000

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23

Cycle number

DN

A co

pies

Applications of PCRApplications of PCR• Classification of organisms

• Genotyping• Molecular archaeology

• Mutagenesis• Mutation detection• Sequencing• Cancer research

• Detection of pathogens

• DNA fingerprinting

• Drug discovery• Genetic matching• Genetic engineering

• Pre-natal diagnosis

Applications of PCR

Basic Research Applied Research• Genetic matching• Detection of pathogens• Pre-natal diagnosis• DNA fingerprinting• Gene therapy

• Mutation screening• Drug discovery• Classification of organisms• Genotyping• Molecular Archaeology• Molecular Epidemiology• Molecular Ecology

• Bioinformatics

• Genomic cloning

• Site-directed mutagenesis

• Gene expression studies

Applications of PCR

Molecular Identification Sequencing Genetic Engineering• Molecular Archaeology• Molecular Epidemiology• Molecular Ecology• DNA fingerprinting• Classification of organisms• Genotyping• Pre-natal diagnosis• Mutation screening• Drug discovery• Genetic matching• Detection of pathogens

• Bioinformatics

• Genomic cloning

• Human Genome Project

• Site-directed mutagenesis

• Gene expression studies

APPLICATIONS OF REAL-TIME PCR

MMOLECULAROLECULAR IIDENTIFICATION:DENTIFICATION:

Detection of Unknown MutationsDetection of Unknown MutationsMolecular Identification:

Classification of OrganismsClassification of Organisms

1) Relating to each other

2) Similarities

3) Differences

* Fossils

* Trace amounts

* Small organisms

! DNA !

Molecular Identification:

Insufficient data

Detection Of PathogensDetection Of Pathogens

Molecular Identification:

SSEQUENCINGEQUENCING

Nucleotides (dNTP) are modified (dideoxynucleotides = ddNTP)

NO polymerisation after a dideoxynucleotide!

Fragments of DNA differing only by one nucleotide are generated

Nucleotides are either or

SummarySummary

blood, chorionic villus, amniotic fluid, semen, hair root, saliva

68,719,476,736 copies Gel Analysis, Restriction Digestion, Sequencing

ConclusionConclusionThe speedspeed and easeease of use, sensitivitysensitivity, specificityspecificity and

robustnessrobustness of PCR has revolutionised molecular biology

and made PCR the most widely used and powerful

technique with great spectrum of research and

diagnostic applications.