DNA Technology PDF

Summary

This document is a set of lecture notes on DNA technology. It covers topics like DNA sequencing, DNA cloning, the Human Genome Project, and various techniques involved. It includes helpful diagrams and figures to illustrate concepts.

Full Transcript

Chapter 19

DNA Technology

Lecture Presentations by
Nicole Tunbridge and
© 2021 Pearson Education Ltd. Kathleen Fitzpatrick
Figure 19.1b

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CONCEPT 19.1: DNA sequencing and DNA
cloning are valuable tools for genetic
engineering and biological inquiry
The main technologies for sequencing and
manipulating DNA are called DNA technology

The complementarity of the two DNA strands is the
basis for nucleic acid hybridization, the base
pairing of one strand of nucleic acid to the
complementary sequence on another strand

Genetic engineering is the direct manipulation of
genes for practical purposes
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The Human Genome Project

The first full human genome sequence was
completed in 2003

It took 13 years to be completed

It cost $1billion

The time and cost of genome sequencing have
been greatly reduced by improved methods

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DNA Sequencing

A gene’s complete nucleotide sequence can be
determined using a process called DNA
sequencing

The first automated procedure was based on a
technique called dideoxy or chain termination
sequencing, developed by Frederick Sanger
(Sanger Sequencing)

In the first decade of this century, “next-generation
sequencing” (NGS) techniques have been
developed that are rapid and inexpensive
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Figure 19.2

Next-generation DNA sequencing machines

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Video: Sanger Method of DNA Sequencing

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 In sequencing by synthesis (NGS), many DNA
fragments are copied to produce an enormous
number of identical fragments

A single strand of each fragment is immobilized and
the complementary strand synthesized one
nucleotide at a time

Thousands or hundreds of thousands of fragments
about 300 nucleotides long can be sequenced in
parallel

This is an example of “high-throughput” technology
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Figure 19.3
Sequencing by Synthesis: Next-Generation Sequencing

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 “Third-generation sequencing” techniques are
even faster and less expensive

In these methods, a single long DNA molecule is
sequenced as it moves through a very small pore
(nanopore) in a membrane

In one approach, each base is identified by the way
it interrupts an electric current as it passes through
the pore

Associated software allows identification and
analysis of the DNA sequence
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Figure 19.1a

A DNA strand is passed through a pore in a membrane. The
resulting changes in an electrical current are used to determine
the nucleotide sequence.

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Making Multiple Copies of a Gene or Other DNA
Segment
To work directly with specific genes, scientists
prepare well-defined DNA segments in multiple
identical copies by a process called DNA cloning

Plasmids are small, circular DNA molecules that
replicate separately from the bacterial chromosome

Researchers can insert DNA into a plasmid to
produce a recombinant DNA molecule, which
contains DNA from two different sources

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Figure 19.4

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Animation: Recombinant DNA

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 Reproduction of a recombinant plasmid in a
bacterial cell results in cloning of the plasmid
including the foreign DNA

This production of multiple copies of a single gene
is a type of DNA cloning called gene cloning

A plasmid used to clone a foreign gene is called a
cloning vector

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 Bacterial plasmids are widely used as cloning
vectors because they are:
– readily obtained
– easily manipulated
– easily introduced into bacterial cells
– rapidly multiplied once in the bacteria

Gene cloning is useful for amplifying genes to
produce a protein product for research, medical, or
other purposes

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Using Restriction Enzymes to Make a
Recombinant DNA Plasmid

Bacterial restriction enzymes cut DNA molecules
at specific DNA sequences called restriction sites
A restriction enzyme usually makes many cuts in a
long DNA molecule, yielding restriction fragments
The most useful restriction enzymes cut DNA
in a staggered way,
producing fragments
with at least one
single-stranded end
called a sticky end

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 Sticky ends can bond with complementary sticky
ends of other fragments
DNA ligase is an enzyme that seals the bonds
between restriction fragments
This allows researchers to join two DNA fragments
from different sources

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Animation: Restriction Enzymes

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Figure 19.5

Using a restriction enzyme and DNA ligase to make a
recombinant DNA plasmid

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 To check the recombinant plasmid, researchers
might cut the products again using the same
restriction enzyme

To separate and visualize the fragments produced,
gel electrophoresis is carried out

This technique uses a gel made of a polymer that
has microscopic holes of different sizes, through
which shorter fragments can travel faster

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Figure 19.6

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Animation: Gel Electrophoresis of DNA

https://www.youtube.com/watch?v=MhJT9yjnl88

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Amplifying DNA: The Polymerase Chain
Reaction (PCR) and Its Use in DNA Cloning
The polymerase chain reaction, PCR, can
produce many copies of a specific target segment
of DNA

A three-step cycle—heating (denaturing), cooling
(annealing), and extension—brings about a chain
reaction that produces an exponentially growing
population of identical DNA molecules

The process uses primers, short single-stranded
DNA molecules complementary to sequences to
either side of the target sequence
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 The key to PCR is an unusual, heat-stable DNA
polymerase called Taq polymerase

Other polymerases may be used as well; some are
more accurate and stable than Taq, such as Pfu
polymerase

The primers used are specific for the sequence to
be amplified

PCR amplification occasionally incorporates errors
into the amplified strands and so cannot substitute
for gene cloning in cells
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Figure 19.7

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 PCR is used to produce the specific DNA fragment
for cloning
PCR primers can be designed to include restriction
sites that allow the product to be cloned into
plasmid vectors
The resulting clones are sequenced and
error-free inserts selected

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