Recombinant DNA - Report

Summary

This report provides a general overview of recombinant DNA technology. It describes the concept of recombinant DNA, the steps involved, and its applications, highlighting the use of restriction enzymes, vectors, and gene cloning. It also includes information on techniques like alkaline lysis for isolating DNA.

Full Transcript

RECOMBINAN
T DNA
 Introduction
Definition
Steps
Applications
 INTRODUCTION
Recombinant DNA (rDNA): DNA molecules
formed by laboratory methods of
genetic recombination (such as
molecular cloning) to bring together genetic
material from multiple sources, creating
sequences that would not otherwise be found
in the genome.
rDNA is possible because DNA molecules from
all organisms share the same chemical
structure. They differ only in the nucleotide
sequence within that identical overall
structure.
 rDNA is the general name for a piece
of DNA that has been created by the
combination of at least two strands.
rDNA molecules are sometimes
called chimeric DNA, because they
can be made of material from two
different species, like the mythical
chimera. R-DNA technology uses
palindromic sequences and leads to
the production of
 What is Recombinant DNA
This is DNA that has been formed
artificially by combining constituents
from different organisms.
 Recombinant DNA
Technology
Using Recombinant DNA technology,
we can isolate and clone single copy
of a gene or a DNA segment into an
indefinite number of copies, all
identical. These new combinations of
genetic material or Recombinant
DNA (rDNA) molecules are
introduced into the host cells, where
they propagate and multiply. The
technique or methodology is called
 Obtaining rDNA
Step 1: The DNA fragment containing
the gene sequence to be cloned (also
known as insert) is isolated.
Step 2: Cutting DNA.
Step 3: Joining DNA
Step 4: Insertion of these DNA
fragments into host cell using a
“vector” (carries DNA molecule).
 Conti…
Step 5: The rDNA molecules are generated
when the vector self replicates in the host
cell.
Step 6: Transfer of the rDNA molecules into
an appropriate host cell.
Step 7: Selection of the host cells carring
the rDNA molecule using a marker.
Step 8: Replication of the cells carrying
rDNA molecules to get a genetically
identical cells or clone.
 Isolation
The first step in making recombinant
DNA is to isolate donar and vector
DNA. The procedure used for
obtaining vector DNA depends on the
nature of the vector. Bacterial
plasmids are commonly used
vectors, and these plasmids must be
purified away from the bacterial
genomics DNA.
 Ultracentrifugation
A protocol for extracting plasmids DNA can
be achieved by ultracentrifugation
Plasmids DNA forms a distinct band after
ultracentrifugation in a cesium chloride
density gradient containing ethidium
bromide. The plasmid band is collected by
punching a hole in the plastic centrifuge
tube.
https://
www.youtube.com/watch?v=n-lVxNjfeio
 Alkaline Lysis
Another protocol relies on the
observation that, at a specific
alkaline pH, bacterial genomic DNA
denatures but plasmids do not.
Subsequent neutralization
precipitates the genomic DNA, but
plasmids stay in solution. Phages can
also be used as vectors for cloning
DNA in bacterial systems. Phage DNA
is isolated from a pure suspension of
 Cutting DNA
The restriction enzymes EcoRi cuts a
circular DNA molecule bearing one
target sequence, resulting in a linear
molecule with single stranded sticky
ends.
 Insertion
Choosing a gene Cloning Vector
A vector is any DNA molecule which is
capable of multiplying inside the host to
which our gene of interest is integrated for
cloning. In this process restriction enzyme
function as scissors for cutting the DNA
molecule. Ligase enzyme is the joining
enzyme that join the vector DNA with the
gene of interest this will produce the
recombinant DNA.
 Introducing Vector DNA into Host
Cell
Plasmid Vector
The vector is added to a flask containing a
culture of E.coli.
Calcium ions usually in the form of calcium
chloride are added to the flask followed by a
brief heat shock.
This allows holes to briefly appear in the cell
surface membrane of the E.coli making it
permeable to DNA and allowing the
plasmids to enter.
 Phage Vectors
Introduced by infection of bacterial
lawn growing on an agar plate.
The culture or growth of viruses is
made more difficult than the culture
of bacteria or fungi by the fact that
viruses will only grow.
 Placing the Gene in the
vector.
Plasmid DNA
DNA molecule are small and can be
easily separated based on the size.
Bacterial cells are broken open and
chromosomal DNA is centrifuged down.
This leaves the plasmid DNA in the
liquid above the pellet.
The plasmid are purified before cutting
with a restriction enzyme.
 Conti…
Restriction fragments from donar
DNA are mixed with plasmid DNA and
joined by their sticky ends, the initial
attraction is due to the hydrogen
bonds, but the sugar phosphate
backbone is then joined using and
enzyme called DNA ligase.
 Example of use of Recombinant
DNA Technology
Insulin Production
The DNA for insulin is first isolated
A plasmid made of DNA is removed
from a bacterial cell
A restriction enzyme cuts the
plasmid DNA open, leaving sticky
ends.
The insulin gene, with
complementary sticky ends is added.
 Examples of Use of Recombinant
DNA Technology
DNA ligase enzyme splices (joins) together
the plasmid DNA and the insulin DNA.
The plasmid (now genetically modified) is
inserted back into the bacterium.
The bacterium host cell, divides and
produces copies of the plasmid.
The Bacterium makes human insulin using
the gene in the plasmid.
The insulin is extracted from the bacterial
culture.
Joining
DNA
Production of an
Insulin
 Applications
Preparation of gene maps.
In revealing details of various infections, diseases such
as "inborn errors of metabolism."
Finding out the complete nucleotide sequence of
genome of an organism and identification of genes.
Detecting cytogenetic abnormalities e.g. Down's
syndrome, multifactorial disorders, atherosclerosis,
coronary artery disease etc.
Preventing various genetic disorders e.g. inherited
haemoglobin disorders, phenylketonuria,
retinoblastoma etc.
Understand a molecular event is biological processes
like growth, differentiation, ageing etc.
 Conti…
Replacement or correction of deleterious mutation by
transfer of clone gene in a patient.
Production of genetically modified organisms
(GMOs) or transgenic organisms for providing
particular product and nutrient.
Gene Therapy: Removal and replacement of defective
genes with normal healthy functional genes is known
as gene therapy e.g. Sickle cell anaemia, Severe
Combined Immuno-Deficiency (SCID). SCID is due
to a defect in the gene for the enzyme adenosine
deaminase (ADA) in 25 per cent of the cases.
 It has several negative features as
well: extensive erosion and genetic
destruction of plant Germplasm;
ecological imbalance; production of
monsters; production of dangerous
toxic chemicals, production of highly
lethal microbes and their use in
microbiological warfare to kill
humans, animals and plants.