Recombinant DNA Technology in Medicine PDF

Summary

This document provides an overview of recombinant DNA technology and its applications in medicine. It discusses various techniques, including gene cloning, PCR, and hybridization, as well as their use in diagnostics and therapies.

Full Transcript

Gene Cloning and Recombinant
DNA Technology in Medicine
Prof. Bart Dzudzor
 Recombinant DNA Technology
Objectives:
Involves techniques in manipulating DNA:-
Molecular Cloning.
DNA sequencing.
Polymerase Chain Reaction (PCR).
Nucleic acid blotting and hybridization.
(Southern, Northern analysis).
Production of proteins.
Creation of Knock-out, Knock-in and Transgenic mice.
Nucleic acid Microarray (simultaneous monitoring of
expression level of each gene in a cell.
 Restriction Endonucleases
Their discovery revolutionized recombinant DNA technology because they can cut
DNA double helix at specific sites defined by their local nucleotide sequence.
They are purified from bacteria.
These enzymes recognize short sequences of DNA usually 4-8bp long and cut both
strands.
These sequences, where they occur in the genome of the bacterium itself, are
protected from cleavage by methylation at an A or a C residue; the sequences in
foreign DNA are generally not methylated and so are cleaved by the restriction
enzymes.
The recognition sequences are usually palindromes-that is, the sequence is the same
if read from one direction on one strand and the opposite direction on the other
strand.
Some restriction enzymes produce staggered cuts ( leaving what are known as
“sticky ends” or “cohesive”) and others produce blunt cuts (leaving “blunt ends”).
The fragments of DNA produced by cleavage with a restriction enzyme are known as
restriction fragments.
In the case of an enzyme that produces sticky ends, the ends can transiently base-
pair. The base-paired ends can be covalently joined by the action of DNA ligase.
Restriction-recognition sites are short DNA sequences recognized and cleaved by
various restriction endonucleases.
Restriction Enzymes are used to digest (cut)
fragments of DNA for the purposes of:
fractionating genomic DNA by size
(Southern blot).
cloning a specific sequence (generate
library).
mapping a region of DNA (restriction site
map).
isolating a specific fragment of DNA (to
make a labeled probe).
 RESTRICTION FRAGMENT
Cut the DNA with RE
How often do they cut?
→ If the DNA sequence is completely random (it’s
not), the probability of a sequence occuring is:
6 bp recognition sequence : e.g. EcoRI (1/4)6 = 1/4096
~ 1 cut every 4 kb
8 bp “ “ (1/4)8 ~ 1 “ “ 65 kb
4 bp “ “ (1/4)4 ~ 1 “ “ 250 bases
Have isolated >3000 Type II RE with >200 sequence
specificities.
Isolate the desired DNA fragment.
Usually done by gel electrophoresis on agarose gels
(non-denaturing).
 Why do Medical Researchers Clone Genes and
how does that contribute to the field of Medicine?

A. To define inherited genetic mutations that
cause/predispose to disease making it possible
to:
i. develop diagnostic reagents.
ii. Develop pre-natal testing and counseling.
iii. Define the precise biochemical defect.
iv. Develop therapies that treat the disease
instead of the symptoms; a target therapy
repairs/overcomes the inherited defect.
 B. To isolate functional (“normal”) genes that can be
harnessed to produce therapeutic molecules

a. Proteins produced by recombinant DNA are made
outside the body and not contaminated with infectious
blood products such as Hepatitis, HIV, etc. For example
the clotting factor Factor VIII needed by hemophiliacs.
b. Proteins may be used not merely to replace a low
level or nonfunctional protein, but also generate a
desired effect in persons with a functional gene. For
example, certain blood cell growth factors are given to
allow harvest of bone marrow progenitor cells from
peripheral blood.
c. Genes can be isolated from infectious organism to
allow vaccine development. Eliminates the possibility of
reversion to a wild-type from an attenuated organism.
 C. Isolate genes which contain somatic mutations (not
inherited but acquired in a specific cell population)

a. Develop a diagnostic for certain rearrangements or
mutations in tumors that leads to the selection of a
specific type of therapy.
b. Use as a marker to measure response to therapy or
disease progression.
c. Target specific therapies to recognize the altered
gene.
i. antibodies against surface proteins
ii. Tyrosine kinase inhibitors
iii. Gene therapy
iv. Stimulate the immune system.
D. To obtain an enhanced understanding of biochemical pathways in
order to expand our knowledge base (signal transduction, immunity,
development, the cell cycle)

A. Integrate the discovery of a new gene
into the existing pathway to make
predictions about its function.
B. “knowledge is power” basic research
Clinical research New modalities of patient care.
 Molecular Cloning.
To study and manipulate a particular DNA sequence or gene, it is usually
necessary to amplify it.
The amplification process is called cloning (more precisely-molecular
cloning) since a single recombinant DNA molecule is replicated into million
of identical copies.
This is different from cloning organisms which is the process of taking a
single cell from an organism and using it to regenerate an identical copy of
the organism.
Molecular cloning involves joining a specific DNA fragment to a DNA
molecule that can replicate in a host cell-usually the bacterium E. coli.

The replicating DNA molecule is called a vector.
Since the vector can replicate in the bacterial cells, any heterologous
(foreign) DNA covalently joined to the vector will also be replicated.

Common vectors are Plasmids and bacterial viruses. In eukaryotic cells,
vectors can also be either plasmids or viruses (retroviruses).
 The important features to consider
when choosing a vector are:
should be small and easy to handle.
able to generate large amounts of DNA through
replication in an appropriate organism such as
bacteria.
if necessary can direct expression of a
recombinant protein in appropriate host cell.
can accommodate DNA of the required size.
has an appropriate selection marker (antibiotic
resistance)
PLASMID CLONING VECTOR

A plasmid is an
extrachromosomal double-
stranded DNA molecule that
replicates autonomously in
bacterial cells
General procedure for cloning a DNA fragment in a plasmid vector.

B
A

Isolation of DNA fragments from a mixture
The plasmid DNA can then be isolated
from cells in the colony and characterized or
by cloning in a plasmid vector.
otherwise manipulated.
 PLASMIDS

A plasmid is an extrachromosomal
double-stranded DNA molecule that
replicates autonomously in bacterial cells
 PLAMID VECTORS
Plasmids used for DNA cloning usually
have been engineered to contain:
a number of convenient restriction sites
a marker gene to select for its presence in the
host cell
Simple fusion of different DNA fragments

EcoRI EcoRI
pBR322, cut at
its single
Eco RI site

DNA
ligase
EcoRI foreign EcoRI
recombinant
DNA DNA

Sticky ends New Eco RI site
NNNGAATT CNNN NNNGAATTCNNN
NNNC TTAAGNNN NNNCTTAAGNNN

EcoRI end on insert EcoRI end on vector Fusion site
pUC19

Polylinker:
restriction
sites
lacZ+
gene

Origin
Ampicillin sequence
resistance
gene
Cloning of cDNA using
BamHI linkers

Alternative: use adapter

5’-GATCCAGAC-3’
GTCTG-5’
 BLUE/WHITE SELECTION

Blue-white selection is used to identify colonies
which have insert-containing plasmids – eliminates
those that have plasmids with no DNA insert
Use a pUC cloning vectors and host cells which
produce an incomplete (inactive) -galactosidase
protein
MCS in pUC vector is in the middle of the LacZ gene

The blue-white selection involves addition of IPTG
and X-gal to the medium
IPTG induces the LacZ operon
 BLUE/WHITE SELECTION

The LacZ operon results in expression of the -
galactosidase -peptide
The -galactosidase -peptide complements the
incomplete (inactive) -galactosidase protein in the
host E. coli cells and produces functional , active -
galactosidase
Functional -galactosidase cleaves the colourless X-gal
in the medium to give active colonies a blue colour.
IF a plasmid contains a DNA insert in the MCS (i.e. in
the middle of the LacZ gene), then a functional -
peptide cannot be generated, complementation does not
occur, and colonies cannot cleave X-gal. Therefore,
colonies with plasmids with inserts stay white.
 Some uses of cloning:
1. Isolate and characterize a specific gene
or mRNA from a complex mixture (the
genome or the total RNA in a cell).
2. Generate probes to detect homologous
sequences-useful in disease diagnosis.
3. Express large amounts of protein-useful
in producing therapeutic proteins.
4. Generate mutations to develop animal
models of particular diseases.
 DNA Libraries
Libraries are a complex collection of DNA fragments (for
example, the DNA fragments produced by cutting human
DNA with a restriction fragment) individually inserted into
a vector.

Genomic Libraries
Genomic libraries consist of DNA derived from the
genome of an organism.
Genomic libraries therefore contain all elements of the
genome-coding regions, intron, regulatory control
regions, regions between gene, etc.
 cDNA Libraries
cDNA libraries contain double-stranded copies of DNA
copied from mRNA.
cDNA library only contains the sequences that are
present in the mRNAs.
It also contains only those sequences that are
expressed-therefore two cDNA libraries made from two
cell types in an organism will have overlapping but
distinct sets of sequences.
cDNA is synthesized using reverse-transcriptase-an
enzyme that synthesizes a single strand DNA copy of an
mRNA. The single stranded DNA can then be converted
into a double-stranded molecule using a DNA
polymerase and then cloned into a vector.
Construction of a human Genomic
DNA library.
 Genomic library contains all of the genetic
information found in the genome of an organism.
In the case of human DNA introns, exons and noncoding
regions would all be included.
Reasons to construct and screen a genomic library
include:
1. to clone the whole gene including introns and 5’
regulatory sequences (promoter), for example to study
gene expression.
2. the gene will be cloned in the context of surrounding
DNA making it possible to move along a chromosome
and clone a new gene whose approximate chromosomal
location is known.
3. to make knock-out animal model by replacing the
functional gene with a nonfunctional copy.
The Synthesis of cDNA
When thinking about constructing or using a
cDNA library remember:
There are no upstream regulatory sequences
controlling gene expression because they are
not transcribed into the mRNA.
The cellular source of mRNA is critical! If the cell
does not express the gene , no mRNA, no cDNA
and it won’t be in the library.
Since there are no introns, cDNA clones can be
“translated” to find open reading frames and
predict protein sequence.
It is not possible to determine chromosomal
“context” or identify relationship to genes that
map nearby.
The differences between cDNA clones and genomic DNA clones derived from the
same region of DNA
 Nucleic Acid Hybridization
A common method to detect a specific
nucleotide sequence in a complex mixture such
as a library is hybridization.
Hybridization is based on the ability of a single-
stranded nucleic acid (probe) to specifically
anneal by base pairing to a complementary
sequence present among many copies of non-
complementary sequences.
To detect the hybridization product, the probe is
modified so that it can be detected-for example
with radioactive or fluorescent nucleotides.
Membrane hybridization assay
for detecting nucleic acids.

This assay can be used to detect
both DNA and RNA, and the
radiolabeled complementary probe
can be either DNA or RNA.
 Southern and Northern Blotting
These are procedures in which mixtures of nucleic acids are separated by
size and then probed by hybridization.
To perform a southern blot, the genomic DNA is first digested to completion
with one or more restriction endonucleases.
The size separation is carried out by gel electrophoresis in which DNA or
RNA is applied to a porous gel and then subjected to an electric field. The
negatively charged DNA or RNA migrates towards the positive electrode.
The smallest fragments migrate the fastest and therefore at the bottom of
the gel.
The molecules are then transferred to a solid support such as nitrocellulose
filter.
Before the transfer, the DNA gel is treated with an alkaline solution to
denature the DNA, this separates the two complementary strands making
them available for hybridization with the probe.
The blot is then hybridized to a labeled DNA probe (can be either
radioactive or non radioactive system) to detect the gene or RNA of interest.
Southern blot technique for detecting the presence of specific DNA sequences

In Northern blotting, the total cellular RNA is denatured by treatment with an agent
(e.g formaldehyde) that prevents H-bonding between base pairs, ensuring that all
the RNA molecules have unfolded, linear conformation.
 Southern Blot can be used to Detect:
large insertion or deletion (50 to 100bp) of chromosomal DNA into
the gene; the restriction fragments which hybridize to the probe will
be either larger or smaller than expected.
gross gene amplification, this means that rather than the normal
number of 2 copies per diploid cell there may be 5 to 20 or more
copies per cell. (such as the HER-2/neu gene which plays a
causative role in the development of a highly aggressive breast
cancer).
genomic rearrangements caused by chromosomal translocation.
This occurs when two chromosomes actually break and re-join with
the wrong chromosome (an example is the BCR-Abl translocation
that plays a causative role in the development of chronic myeloid
leukemia (CML)).
mutation of a single nucleotide can only be seen on a Southern blot
if it creates or destroys a restriction enzyme site (Hemophilia A and
sickle cell diseases are examples).
 A Southern Blot does not detect:
whether or not a gene is expressed
point mutations (other than restriction
fragment length polymorphism)
small deletions.
 A Northern Blot can detect:
expression of a specific gene which likely changes from
tissue to tissue (except for “housekeeping” genes).
the size of the RNA transcript. An aberrant sized mRNA
could arise as a result of deletion or insertion in the gene
or a chromosomal translocation.
the relative levels of expression in different samples.
Increased or decreased levels of mRNA are associated
with many diseases states
northern can detect deletions or insertions in genes as
well as splicing defects.
 Polymerase Chain Reaction
Procedure that can amplify a specific sequence without cloning into
a vector.
It is very useful in clinical and forensic settings where limited
amounts of DNA are available.
Use short, chemically-synthesized primers that flank region to be
amplified.
Use enzyme from bacteria that lives at high temperature such as
Thermus aquaticus.
Template is melted at high temperature and annealed to excess
amounts of primers at lower temperatures.
Copies are made by the polymerase using dNTPs.
The cycle is repeated about 20 to 40 cycles.
Since each round results in a replication cycle, if carry out 20 cycles
will get 220= 1,048,576 copies.
 PCR continued.
Because of the amplification properties of PCR it is a
very powerful technique to detect very low levels of DNA
or RNA. For example it is used as a very sensitive test
for HIV infection since PCR can be used to amplify
sequences from the RNA genome of the virus.
It is also sensitive enough to detect specific sequences
in small amounts of material available from crime
scenes. It is so sensitive that a fingerprint or saliva left
on the back of a stamp contains enough DNA for
analysis by PCR.
PCR is very fast compared to Southern or Northern
blotting so it has replaced these techniques in many
areas.
PCR technique
PCR
The Key Steps in the PCR reaction are:

1. denature the template DNA by heating
to 94o for 5 minutes.
2. anneal the specific primer by lowering
the temperature to around 50o.
3. extend the DNA strand using DNA
polymerase (Taq) for 5 minutes (72-75o).
4. heat 20 seconds to separate the newly
synthesized short strands.
5. go to step 2 and repeat 25 to 40 cycles.
 Uses of PCR
To look for mutations either inherited or acquired, by
doing a PCR reaction followed by DNA sequencing.
To detect Minimal Residual Disease in leukemia patients
using primers made to recognize DNA sequence on
either side of the chromosomal breakpoint. The
presence of a small number of leukemic cells in the
midst of a proportionally larger number of normal cells is
detected by the presence of a positive signal.
PCR may be used to determine the gender of embryonic
cells generated by in vitro fertilization in families carrying
X-linked mutations.
It can also be used for in vitro mutagenesis to test the
effect of a specific mutation on the function of the gene
product.
 Uses of PCR Cont’d
Gene cloning.
Carrier screening.
Clinical diagnosis/confirmation.
Newborn screening.
Presymptomatic diagnosis/predisposition screening.
Transplant engraftment-distinguishing donor from
recipient cells after bone marrow or organ transplant.
Parentage/paternity testing-excluding or not excluding an
alleged father (or mother).
Forensic identification-matching a suspect’s DNA to that
found in some crime evidence in order to solve cases of
murder, rape, mail fraud, etc.; identifying victims of mass
disasters (bombings, airline crashes, wars, genocides).
 PCR uses continued
Twin zygosity-distinguishing mono-from dizygotic twins
(since only monozygotic twins should match at all
polymorphic loci tested).
Early detection of HIV, the virus that causes AIDS.
Surgical specimen mix-ups-to match a mislabeled or
unlabeled biopsy specimen to the patient from which it
came.
DNA fingerprinting
Prenatal diagnosis-several sample types are possible,
depending on the clinical situation:
Amniocentesis
Chorionic villus samples (CVS)
Embryonic blastomeres for preimplantation diagnosis
Fetal cells circulating in maternal blood.
How PCR is used in Forensic Science

Three suspects A,B and C, producing
6 DNA bands for each person after PAGE.
The band pattern therefore save as a
“fingerprint” to identify an individual
nearly uniquely.
Use of PCR to obtain a Genomic or cDNA clone
 Types of DNA Polymorphism
RFLP=Restriction Fragment Length Polymorphism-restriction
endonuclease recognition sites that are present in some people but
not in others (can be detected by Southern blotting or PCR).
VNTR=Variable Number of Tandem Repeats-strings of nucleotide
sequences (usually of 16 or more nucleotides each), of different
repeat number in different people, existing between fixed restriction
endonuclease sites; also called minisatellites.
STR= Short Tandem Repeats-string of oligonucleotide sequences
that are shorter that VNTR (usually of 2,3,4 or 8 nucleotides each),
of different repeat number in different people, not necessarily lying
between restriction endonuclease sites; also called microsatellites or
Simple Sequence Repeats (SSR). The more highly related two
individuals are, the more likely it is that a given SSR will be present
in the same numbers. SSR variations can be detected by PCR,
using primers that lie outside of the repeat region followed by
accurate gel electrophoresis of the products. The size of the PCR
product then reflects the number of repeats.
 Polymorphism cont’d
SNP=single Nucleotide Polymorphism-single
nucleotide differences between individuals that
are not associated with restriction endonuclease
sites. Best studied by PCR followed by accurate
gel electrophoresis of the products.
HLA=the histocompatibility family of genes
located on chromosome 6p; although not “junk”
DNA, these genes are naturally so highly
polymorphic that they can be used for identity
studies at either the DNA level or using
antibodies to distinguish varieties in the encoded
proteins.
An example of SSR inheritance
 Sanger (Dideoxy) Sequencing Method.

Also called dideoxy sequencing because it involves use
of 2’,3’-dideoxynucleoside triphosphates (ddNTPs),
which lacks a 3’-hydroxy group.
In this method, the single-stranded DNA to be
sequenced serves as the template strand for in vitro
DNA synthesis, a synthetic 5’-end labeled
oligodeoxynucleotide is used as the primer.
Four separate polymerization reactions are performed,
each with a low (100 lower) concentration of one of the 4
ddNTPs in addition to higher concentrations of the
normal deoxynucleotide triphosphates (dNTPs)..
 Sanger’s Method cont’d
In each reaction, the ddNTP is randomly incorporated at
the positions of the corresponding dNTP; such addition
of a ddNTP terminates polymerization because the
absence of a 3’ hydroxy prevents addition of the next
nucleotide.
The mixture of terminated fragments from each of the
four reactions is subjected to gel electrophoresis in
parallel; the separated fragments then are detected by
autoradiography.
The sequence of the original DNA template strand can
be read directly from the resulting autoradiogram.
Sanger’s (dideoxy) Method for Sequencing DNA fragments

Used more frequently than
the Maxam-Gilbert method.
can be used to sequence
longer fragments of DNA
than the Maxam-Gilbert method
 The enzymatic—or dideoxy—
method of sequencing DNA.

In each lane, the
bands represent
fragments that have
terminated at
a given nucleotide
This reaction mixture will eventually produce a set (e.g., A in the
of DNAs of different lengths complementary to the leftmost lane) but
template DNA that is being sequenced and at different positions
terminating at each of the different A’s. The exact in the DNA
lengths of the DNA synthesis products can then
be used to determine the position of each A in the
growing chain.
 Strategy for automating DNA
sequencing reactions.
* Each dideoxynucleotide used in the Sanger method can be linked to
a fluorescent molecule that gives all the fragments terminating in that
nucleotide a particular color.
All four labeled ddNTPs are added to a single tube.

The resulting colored DNA fragments are then separated
by size in a single electrophoretic gel contained in a capillary tube (a
refinement of gel electrophoresis that allows for faster separations).

All fragments of a given length migrate through the capillary gel in a single
peak, and the color associated with each peak is detected using a laser
beam.
The DNA sequence is read by determining the sequence of colors in the
peaks as they pass the detector.
This information is fed directly to a computer, which determines the
sequence.
Fluorescent Automated DNA sequencing
 Production of High levels of
Proteins from Cloned cDNA
Once the desired cDNA is cloned, large
amounts of the encoded protein can be
synthesized in engineered E. coli cells.
Example, granulocyte colony-stimulating
factor can be produced at high levels in
expression vectors designed to produce
full length proteins at high levels.
A simple E. coli expression vector utilizing the lac operon

The lacZ gene can be replaced with the
G-CSF. When the resulting plasmid is
transformed into E. coli cells, addition
of IPTG and subsequent transcription
from the lac promoter produces G-CSF
mRNA, which is translated into G-CSF
protein.
Two-step expression vector system based on bacteriophage T7 RNA polymerase
and T7 late promoter
Creation of a Knockout mice
Isolation of mouse embryonic stem (ES)
cells with a gene targeted disruption by
positive and negative selection.

When exogenous DNA is introduced into
ES cells, random insertion via
nonhomologous recombination occurs
more frequently than gene-targeted
insertion via homologous recombination.

Recombinant cells in which one copy of the
gene X is disrupted can be obtained by using
a recombinant vector that carries gene X
disrupted with neor, a neomycin-resistance gene,
and outside the region of homology, tkHSV, the
thymidine kinase gene from herpes simplex virus

Nonhomologous insertions includes the tkHSV
gene, whereas homologous insertions doesn’t;
therefore, only cells with nonhomologous
insertion are sensitive to ganciclovir.
 General procedure for producing gene-
targeted knockout mice

Embryonic stem (ES) cells heterozygous
for a knockout mutation in a gene of
interest (X) and homozygous for a marker
gene (here, black color) are transplanted
into the blastocoel cavity of a 4.5-day
embryos that are homozygous for an
alternative marker (here, white color).

The early embryos then are implanted into
a peudopregnant female. Some of the
resulting progeny are chimeras, indicated
by their black and white coats.

Chimeric mice then are backcrossed to white
mice; black progeny from this mating have
ES-derived cells in their germ line.
by isolating DNA from a small amount of tail
tissue, it is possible to identify black mice
heterozygous for the black allele. Intercrossing
of these black mice produces individuals
homozygous for the disrupted allele, that is,
knockout mice.
Creation of a Knockout animal
General procedure for producing transgenic mice

Frequency of random integration
of exogenous DNA into the mice
genome at nonhomologous sites
is very high.
Production of transgenic mice is
a highly efficient and
straightforward process.
Cloning in mice. The gene for
Human growth hormone
was introduced into the genome
of the mouse on the right.
Expression of the gene resulted in
the unusually large size of this mouse
 Good bye!!
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