Chapter 12: DNA Technology PDF

Summary

This chapter explores the concepts of DNA profiling and genetic engineering. It details the history and applications of DNA technology in forensic science and medical fields, including recombinant DNA techniques and the production of genetically modified organisms. The chapter also examines relevant social, ethical, and legal issues.

Full Transcript

CHAPTER CONTENTS CHAPTER THREAD
Genetic Engineering 252 DNA Profiling
DNA Profiling and Forensic Science 259 BIOLOGY AND SOCIETY Using DNA to Establish Guilt
Bioinformatics 263 and Innocence 251

Safety and Ethical Issues 268 THE PROCESS OF SCIENCE Can Genomics Cure Cancer? 266
EVOLUTION CONNECTION The Y Chromosome as a
Window on History 271

DNA Profiling BIOLOGY AND SOCIETY

Using DNA to Establish Guilt and Innocence
It was a horrific crime in the heart of the nation’s capital: On February 24, 1981, a man broke into an apart-
ment, just miles from the White House, and attacked a 27-year-old woman. After binding and raping her, the
perpetrator stole traveler’s checks and ran off. The victim had only glimpses of her attacker. Several weeks
later, a police officer thought that 18-year-old Kirk Odom resembled a sketch of the perpetrator. A month
later, the victim picked Odom out of a police lineup.
At trial, a Special Agent of the FBI testified that hair found in the victim’s
clothing, when viewed under a microscope, was “indistinguishable” from
Odom’s hair. Despite Odom having an alibi for his whereabouts on the night
of the crime, after just a few hours of deliberation the jury convicted Odom
of several charges, including rape while armed. He was sentenced to 20 to
66 years in prison. Odom served more than 20 years before being released
on lifelong parole as a registered sex offender. However, in February 2011,
prompted by recent discoveries that indicated that the FBI’s microscopic hair
analysis technique was flawed—and subsequent overturned convictions in
other cases—a motion was filed to reopen the Odom case for DNA testing.
Modern forensic DNA analysis hinges on a simple fact: The cells of every
person (except identical twins) contain unique DNA. DNA profiling is the anal-
ysis of DNA samples to determine whether they come from the same individual.
In the Odom case, the government located sheets, clothing, and hair evidence
from the 1981 crime scene. In the more recent analysis, the results were con-
clusive and irrefutable: The DNA left at the crime scene did not match Odom’s.
In fact, the DNA matched a different man, a convicted sex offender (who was
never charged because the statute of limitations on the crime had expired). On
July 13, 2012—Odom’s 50th birthday—the court acknowledged that the original
hair analysis data was erroneous and that Kirk Odom had “suffered a terrible
injustice.” ­After 30 years, Odom was officially declared innocent by the court. A DNA profile. Even minuscule bits of evidence
A steady stream of stories such as this one demonstrates that DNA tech- can provide a DNA profile.
nology can provide evidence of either guilt or innocence. Beyond the court-
room, DNA technology has led to some of the most remarkable scientific advances in recent years: Crop plants
have been genetically modified to produce their own insecticides; human genes are being compared with
those of other animals to help shed light on what makes us distinctly human; and significant advances have
been made toward detecting and curing fatal genetic diseases. This chapter will describe these and other uses
of DNA technology and explain how various DNA techniques are performed. We’ll also examine some of the
social, legal, and ethical issues that lie at the intersection of biology and society.

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 Genetic Engineering
Chapter 12
DNA Technology

You may think of biotechnology, the manipulation of mass-produce a variety of useful chemicals, from ­
organisms or their components to make useful prod- cancer drugs to pesticides. Scientists have also
ucts, as a modern phenomenon, but it actually dates transferred genes from bacteria to plants and from
back to the dawn of civilization. Consider such ancient one ­animal species to another (Figure 12.1). Such
practices as using yeast to make bread and beer and ­engineering can serve a variety of purposes, from
the selective breeding of livestock. But when people use basic research (What does this gene do?) to ­medical
the term biotechnology today, they are usually referring ­applications (Can we create animal models for this
to DNA technology, modern laboratory techniques for ­human ­disease?).
studying and manipulating genetic material. Using the
methods of DNA technology, scientists can modify spe-
cific genes and move them between organisms as dif- Recombinant DNA
ferent as bacteria, plants, and animals. Organisms that
have acquired one or more genes by artificial means are Techniques
called genetically modified (GM) organisms. If the Although genetic engineering can be performed on
newly acquired gene is from another organism, typi- a variety of organisms, bacteria (Escherichia coli,
cally of another ­species, the recombinant organism is in ­particular) are the workhorses of modern bio-
called a transgenic organism. technology. To manipulate genes in the laboratory,
In the 1970s, the field of biotechnology exploded ­biologists often use bacterial plasmids, which are small,
CHECKPOINT with the invention of methods for making recombi- circular DNA molecules that duplicate separately from
nant DNA in the laboratory. Scientists can construct the larger bacterial chromosome (­Figure 12.2). Because
What is biotechnology? What
is recombinant DNA?
­recombinant DNA by combining pieces of DNA from plasmids can carry virtually any gene and are passed
sources, often different species two different sources—often from different species— from one generation of bacteria to the next, they are
­containing DNA from two different to form a single DNA molecule. Recombinant DNA key tools for gene cloning, the production of multiple
technology is widely used in genetic engineering, the identical copies of a gene-carrying piece of DNA. Gene
a useful product; a molecule
­organisms or their parts to ­produce
Answer: the manipulation of direct manipulation of genes for practical purposes. cloning methods are central to the ­production of useful
Scientists have genetically engineered bacteria to products from genetically engineered organisms.

▼ Figure 12.1 Genetic engineers produced glowing fish by transferring a gene
for a fluorescent protein originally obtained from jellies (“jellyfish”).

Plasmids

Bacterial

Colorized TEM 2,700×
chromosome
Remnant of
bacterium

▲ Figure 12.2 Bacterial plasmids. The micrograph shows a
bacterial cell that has been ruptured, revealing one long chro-
mosome and several smaller ­plasmids. The inset is an enlarged
view of a single plasmid.

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 How to Clone a Gene recombinant DNA plasmids. The recombinant Genetic Engineering
Consider a typical genetic engineering challenge: plasmids are then mixed with bacteria. Under the
A genetic engineer at a pharmaceutical company identi- right conditions, the bacteria take up the recombinant
fies a gene of interest that codes for a valuable protein, plasmids. Each bacterium, carrying its recombi-
such as a potential new drug. The biologist wants to nant plasmid, is allowed to reproduce via cell division
manufacture the protein on a large scale. Figure 12.3 to form a clone, a group of identical cells descended
­illustrates a way to accomplish this by using recombi- from a single original cell. As the bacteria multiply,
nant DNA techniques. the foreign gene carried by the recombinant plasmid is
To start, the biologist isolates two kinds of DNA: also copied. The transgenic bacteria with the gene CHECKPOINT
bacterial plasmids that will serve as vectors (gene of interest can then be grown in large tanks, producing Why are plasmids valuable
­carriers, shown in blue in the figure) and DNA from the protein in marketable quantities. The end products tools for the production of
another organism that includes the gene of interest of gene cloning may be copies of the gene itself, to be recombinant DNA?
(shown in yellow). This foreign DNA may be from used in additional genetic engineering projects, or the
by their bacterial host cells.
any foreign gene and are replicated
any type of organism, even a human. The DNA protein product of the cloned gene, to be harvested Answer: Plasmids can carry virtually

from the two sources is joined together, resulting in and used.

◀ Figure 12.3 Using ­
recombinant DNA
Cell containing gene
Bacterium of interest technology to produce useful products.

1 Gene inserted into
plasmid

Bacterial Plasmid
chromosome

Gene of
interest DNA of
Recombinant
chromosome
DNA (plasmid)
(”foreign” DNA)
2 Plasmid
put into
bacterial
cell

Recombinant
bacterium

3 Host cell grown in culture
to form a clone of cells
containing the cloned
gene of interest

A gene for pest A protein is
resistance is used to dissolve
inserted into blood clots in
plants. heart attack
therapy.
Some uses Some uses
of genes of proteins

4 The gene
and protein
A gene is used to Genes may be of interest Bacteria produce A protein is used to
alter bacteria for inserted into are isolated proteins, which prepare ”stone-washed“
cleaning up toxic other organisms. from the can be harvested blue jeans.
waste. bacteria. and used directly.

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 Chapter 12 Cutting and Pasting DNA specific points within the sequence, like a pair of highly
DNA Technology specific molecular scissors.
with Restriction Enzymes
As shown in Figure 12.3, recombinant DNA is created The top of ­Figure 12.4 shows a piece of DNA (blue)
by combining two ingredients: a bacterial plasmid and that contains one ­restriction site for a particular re-
the gene of interest. To understand how these DNA striction enzyme. The restriction enzyme cuts the
molecules are spliced together, you need to learn how DNA strands b ­ etween the bases A and G within the
enzymes cut and paste DNA. recognition sequence, producing pieces of DNA called
The cutting tools used for making recombinant DNA ­restriction fragments. The staggered cuts yield two
are bacterial enzymes called restriction enzymes. Biolo- double-stranded DNA fragments with single-stranded
gists have identified hundreds of restriction enzymes, ends, called “sticky ends.” Sticky ends are the key to
each recognizing a particular short DNA sequence, joining DNA restriction fragments originating from
usually four to eight nucleotides long. For example, one ­different sources. Next, a piece of DNA from another
restriction enzyme only recognizes the DNA sequence source ­(yellow) is added. N ­ otice that the yellow DNA
CHECKPOINT GAATTC, whereas another recognizes GGATCC. The has single-stranded ends ­identical in base sequence
If you mix a restriction DNA sequence recognized by a particular restriction to the sticky ends on the blue DNA because the same
enzyme that cuts within ­restriction enzyme was used to cut both types of DNA.
enzyme is called a ­restriction site. After a restric-
the sequence AATC with
tion ­enzyme binds to its restriction site, it cuts the two The complementary ends on the blue and yellow
DNA of the sequence
CGAATCTAGCAATCGCGA, strands of the DNA by breaking chemical bonds at fragments stick together by base pairing. The union
how many restriction between the blue and yellow fragments is then made
fragments will result? (For permanent by the “pasting” enzyme DNA ligase. This
Recognition site (recognition sequence)
simplicity, the sequence of enzyme connects the DNA pieces into continuous
for a restriction enzyme
only one of the two DNA
strands by forming bonds between adjacent nucleotides.
strands is listed.)
The final outcome is a single molecule of recombinant
will yield three restriction fragments. GA AT T C
Answer: Cuts at two restriction sites
C T T A AG DNA DNA. The process just described explains what happens
in step 1 of Figure 12.3.
1 A restriction enzyme cuts
the DNA into fragments.
Restriction Gel Electrophoresis
enzyme
To separate and visualize DNA fragments of
­different lengths, researchers carry out a technique
Stick
y called gel electrophoresis, a method for ­sorting
end AAT ­macromolecules—usually proteins or nucleic
TC
G G
­acids—primarily by their electrical charge and size.
TAA ­Figure 12.5 shows how gel electrophoresis separates
CT Stick
y
end DNA f­ ragments obtained from different sources. A
sample with many copies of the DNA from each source
2 A DNA fragment is added from AA
another source.
T TC is placed in a separate well (hole) at one end of a flat,
G rectangular gel. The gel is a thin slab of jellylike mate-
G
CT rial that acts as a molecular sieve. A negatively charged
T AA electrode is then attached to the DNA-containing end
of the gel and a positive electrode to the other end.
3 Fragments stick together by
base pairing.
­Because the phosphate (PO4−) groups of nucleotides
give DNA f­ ragments a negative charge, the ­fragments
TC G A AT T move through the gel toward the positive pole. How-
G A AT G C T TA A
C
C T TA A G ever, longer DNA fragments move more slowly through
the thicket of polymer fibers in the gel than do shorter
DNA fragments. To help you visualize the process,
4 DNA ligase joins the DNA imagine a small animal scampering quickly through
fragments into strands. ligase
a thicket of jungle vines, while a large animal plods
along the same distance much more slowly. Similarly,
▶ Figure 12.4 Cutting and pasting DNA.
over time, shorter molecules move farther through a
The production of ­recombinant DNA requires
two enzymes: a restriction enzyme, which cuts
gel than longer molecules. Gel electrophoresis thus
the original DNA molecules into pieces, and ­separates DNA fragments by length. When the cur-
DNA ligase, which pastes the pieces together. Recombinant DNA molecule rent is turned off, a series of bands—­visible as blue

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 ▼Figure 12.5 Gel electrophoresis of DNA molecules. The photo shows Genetic Engineering
DNA fragments of various sizes visibly stained on the gel.

Mixture of DNA
fragments of
different sizes

– –

Band of
longest
(slowest)
fragments
Power
source

Gel
Band of
shortest
(fastest)
fragments
+ + Completed gel

smudges in the photograph of the gel—is left in each pancreas. Insulin functions as a hormone and helps
column of the gel. Each band is a collection of DNA regulate the level of glucose in the blood. If the body CHECKPOINT
fragments of the same length. The bands can be made fails to produce enough insulin, the result is type 1 dia- You use a restriction
visible by staining, by exposure onto photographic betes. There is no cure, so people with this disease must enzyme to cut a long DNA
molecule that has three
film (if the DNA is radioactively labeled), or by mea- inject themselves daily with doses of insulin for the rest copies of the enzyme’s
suring fluorescence (if the DNA is labeled with a of their lives. recognition sequence
­fluorescent dye). Because human insulin is not readily available, clustered near one end.
diabetes was historically treated using insulin When you separate the
Millions of from cows and pigs. This treatment was restriction fragments by gel
Pharmaceutical individuals with
diabetes live
problematic, however. Pig and cow insu- electrophoresis, how do
you expect the bands to
Applications healthier lives
lins can cause allergic reactions in people
because their chemical structures differ
appear?
thanks to insulin
of the gel (large fragment)
By transferring the gene for a desired pro- slightly from that of human insulin. In ad- near the negative pole at the top
made by
tein into a bacterium, yeast, or other kind dition, by the 1970s, the supply of beef and
(small fragments) and one band
bacteria. tive pole at the bottom of the gel
of cell that is easy to grow in culture, scien- pork pancreas available for insulin extraction Answer: three bands near the posi-

tists can produce large quantities of useful could not keep up with the demand.
proteins that are present naturally only In 1978, scientists working at a biotechnology
in small amounts. In this section, you’ll company chemically synthesized DNA fragments and
learn about some applications of recom- linked them to form the two genes that code for the
binant DNA technology. two polypeptides that make up human insulin (see
Humulin is human insulin pro- Figure 11.7). They then inserted these artificial genes
duced by genetically modified bacte- into E. coli host cells. Under proper growing conditions,
ria (­Figure 12.6). In humans, insulin the transgenic bacteria cranked out large quantities of
is a protein normally made by the the human protein. In 1982, Humulin hit the market
as the world’s first genetically engineered pharmaceuti-
▶ Figure 12.6 Humulin, human
cal product. Today, it is produced around the clock in
insulin produced by genetically gigantic fermentation vats filled with a liquid culture
modified bacteria. of bacteria. Each day, more than 4 million people with

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 Chapter 12
DNA Technology

▲ Figure 12.7 A factory that produces genetically ▲ Figure 12.8 A genetically modified goat.
­engineered insulin.

diabetes use the insulin collected, purified, and pack- for an enzyme called lysozyme. This enzyme, found
aged at such facilities (Figure 12.7). naturally in breast milk, has antibacterial properties. In
Insulin is just one of many human proteins produced another example, the gene for a human blood protein
by genetically modified bacteria. Another example is has been inserted into the genome of a goat so that the
human growth hormone (HGH). Abnormally low lev- protein is secreted in the goat’s milk. The protein is then
els of this hormone during childhood and adolescence purified from the milk. Because transgenic animals are
can cause dwarfism. Because growth hormones from difficult to produce, researchers may create a single trans-
other animals are not effective in people, HGH was an genic animal and then breed or clone it. The resulting
early target of genetic engineers. Before genetically en- herd of transgenic animals could then serve as a grazing
gineered HGH became available in 1985, children with pharmaceutical factory—“pharm” animals.
an HGH deficiency could only be treated with scarce DNA technology is also helping medical researchers
and expensive supplies of HGH obtained from human develop vaccines. A vaccine is a harmless variant or deriv-
cadavers. Another important pharmaceutical product ative of a disease-causing microbe—such as a bacterium
produced by genetic engineering is tissue plasminogen or virus—that is used to prevent an infectious disease.
activator (abbreviated as tPA), a natural human protein When a person is inoculated, the vaccine stimulates the
that helps dissolve blood clots. If administered shortly immune system to develop lasting defenses against the
after a stroke, tPA reduces the risk of additional strokes microbe. For many viral diseases, the only way to prevent
and heart attacks. serious harm from the illness is to use vaccination to pre-
Besides bacteria, yeast and mammalian cells can also vent the illness in the first place. For example, the vaccine
be used to produce medically valuable human proteins. against hepatitis B, a disabling and sometimes fatal liver
For example, genetically modified mammalian cells disease, is produced by genetically engineered yeast cells
growing in laboratory cultures are currently used to that secrete a protein found on the microbe’s outer surface.
produce a hormone called erythropoietin (EPO) that
stimulates production of red blood cells. EPO is used
to treat anemia; unfortunately, some athletes abuse the Genetically Modified
drug to seek the advantage of artificially high levels of
oxygen-carrying red blood cells (a practice called “blood
Organisms in Agriculture
doping”). In recent decades, genetic engineers have Since ancient times, people have selectively bred
even developed transgenic plant cells that can ­agricultural crops to make them more useful
produce human drugs. Because they are eas- (see Figure 1.13). Today, DNA technology
Someday,
ily grown in culture and are unlikely to be genetically modified is quickly replacing traditional breeding
contaminated by human pathogens (such potatoes could programs as scientists work to improve the
as ­viruses), some scientists believe that car- prevent tens productivity of agriculturally important
rots may be the drug factories of the future! of thousands of plants and animals.
Genetically modified whole animals children from dying In the United States today, more than
are also used to produce drugs. Figure 12.8 of cholera. 80% of the corn crop, more than 90% of the
shows a transgenic goat that carries a gene soybean crop, and about 75% of the cotton crop

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 are genetically modified. Figure 12.9 shows corn that has Genetic Engineering
been genetically engineered to resist attack by an insect
called the European corn borer. Growing insect-resistant
plants reduces the need for chemical insecticides. In
another example, modified strawberry plants produce
bacterial proteins that act as a natural antifreeze, protect-
ing the delicate plants from the damages of cold weather.
Potatoes and rice have been engineered to produce
harmless proteins derived from the cholera bacterium;
researchers hope that these modified foods will one day
serve as an edible vaccine against cholera, a disease that
kills thousands of children in developing nations every
year. In India, the insertion of a natural but rare saltwater-
resistance gene has enabled new varieties of rice to thrive
in water three times as salty as seawater, allowing food to
be grown in drought-stricken or flooded regions.
Scientists are also using genetic engineering to im-
prove the nutritional value of crop plants (Figure 12.10).
One example is “golden rice 2,” a transgenic variety of rice
that carries genes from daffodils and corn. This rice could
help prevent vitamin A deficiency and resulting blind-
ness, especially in developing nations that depend on ▲ Figure 12.10 Genetically modified staple crops.
rice as a staple crop. Cassava, a starchy root crop that is “Golden rice 2,” the yellow grains shown here (top) alongside
a staple for nearly 1 billion people in developing ­nations, ordinary rice, has been genetically modified to produce high
has similarly been modified to produce increased levels of levels of beta-carotene, a molecule that the body converts to
iron and beta-carotene (which is ­converted to vitamin A vitamin A. Transgenic cassava (bottom), a starchy root crop that
serves as the main food source for nearly a billion people, has
in the body). However, controversy surrounds the use of been modified to produce extra nutrients.
GM foods, as we’ll discuss at the end of the chapter.
Genetic engineers are targeting agricultural animals as
well as plant crops. Although no transgenic animals are currently being sold as food, the Food and Drug Admin-
istration (FDA) has issued regulatory guidelines for their
eventual introduction. Scientists might, for example,
▼ Figure 12.9 Genetically modified corn. The corn plants identify in one variety of cattle a gene that
in this field carry a bacterial gene that helps prevent infestation causes the development of larger muscles
by the European corn borer (inset). (which make up most of the meat we
eat) and transfer it to other cattle or
even to chickens. Researchers have
genetically modified pigs to carry
a roundworm gene whose protein
converts less healthy fatty acids to
omega-3 fatty acids. Meat from the
modified pigs contains four to five
times as much healthy omega-3 fat as
regular pork. AquAdvantage is a trade
name for Atlantic salmon that have
been genetically modified to reach
market size in half the normal time
(18 months vs. 3 years). The FDA is
CHECKPOINT
currently reviewing AquAdvantage
What is a genetically
salmon; it may become the first GM
modified organism?
animal approved for consumption in duced through artificial means
the United States. As of late 2014, the Answer: one that carries DNA intro-

review continues.

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 Chapter 12
DNA Technology Human Gene Therapy
We’ve seen that bacteria, plants, and nonhuman animals
can be genetically modified—so what about humans?
Human gene therapy is intended to treat disease by
introducing new genes into an afflicted person. In cases
where a single defective gene causes a disorder, the mu-
tant version of a gene may be replaced or supplemented Normal
with the normal allele. This could potentially correct a human gene
genetic disorder, perhaps permanently. In other cases,
genes are inserted and expressed only long enough to 1 An RNA version is
inserted into a virus
treat a medical problem.
Figure 12.11 summarizes one approach to human
gene therapy. The procedure closely resembles the
gene cloning process shown in steps 1 through 3 of
RNA genome of virus
Figure 12.3, but in this instance human cells, rather
Inserted human RNA
than bacteria, are the targets. A gene from a nor-
mal individual is cloned, converted to an RNA version, Healthy person
2 Bone marrow
and then inserted into the RNA genome of a harmless cells are infected
­virus. Bone marrow cells are taken from the patient
and infected with the recombinant virus. The virus
inserts a DNA copy of its genome, including the nor-
mal human gene, into the DNA of the patient’s cells.
The ­engineered cells are then injected back into the 3 Viral DNA inserts
patient. The normal gene is transcribed and translated into the cell’s
chromosome
within the patient’s body, producing the desired protein.
Ideally, the nonmutant version of the gene would be in- Human chromosome
serted into cells that multiply throughout a person’s life. Bone marrow
Bone marrow cells, which include the stem cells that cell from the patient

give rise to all the types of blood cells, are prime candi-
Bone of person
dates. If the procedure succeeds, the cells will multiply with disease
permanently and produce a steady supply of the missing
protein, ­curing the patient.
The promise of gene therapy thus far exceeds actual Bone
marrow
results, but there have been some successes. In 2009, an
international research team conducted a trial that fo-
4 The engineered
cused on a form of progressive blindness linked to a de- cells are injected
fect in a gene responsible for producing light-detecting
▲ Figure 12.11 One approach to human gene therapy.
pigments in the eye. The researchers found that a single
injection of a virus carrying the normal gene into one
eye of affected children improved vision in that eye, periodically removed immune system cells from
sometimes enough to allow normal functioning, without the patients’ blood, infected them with a virus engi-
significant side effects. The other eye was left untreated neered to carry the normal allele of the defective gene,
as a control. then ­reinjected the blood into the patient. The treat-
From 2000 to 2011, gene therapy was used to cure ment cured the ­patients of SCID, but there have been
22 ­children with severe combined immunodeficiency some serious side effects: Four of the treated patients
CHECKPOINT (SCID), a fatal inherited disease caused by a defective ­developed leukemia, and one died after the inserted
Why are bone marrow stem gene that prevents development of the immune system, gene activated an ­oncogene (see Chapter 11), creating
cells ideally suited as targets requiring patients to remain isolated within protective cancerous blood cells. Gene therapy remains promis-
for gene therapy? “bubbles.” Unless treated with a bone marrow trans- ing, but there is very little evidence to date of safe and
plant, which is effective only 60% of the time, SCID effective ­application. Active research continues, with
person’s life
stem cells multiply throughout a
Answer: because bone marrow patients quickly die from infections by microbes that new, tougher safety guidelines in place that are meant to
most of us ­easily fend off. In these cases, researchers minimize dangers.

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 DNA Profiling and Forensic Science
DNA Profiling and
Forensic Science

When a crime is committed, body fluids (such as blood
or semen) or small pieces of tissue (such as skin beneath
DNA Profiling Techniques
a victim’s fingernails) may be left at the scene or on the In this section, you’ll learn about techniques for making
victim or assailant. As discussed in the Biology and Soci- a DNA profile.
ety section at the start of the chapter, such evidence can
be examined by DNA profiling, the analysis of DNA The Polymerase Chain Reaction (PCR)
samples to determine whether they come from the same The polymerase chain reaction (PCR) is a technique by
individual. Indeed, DNA profiling has rapidly trans- which a specific segment of DNA can be amplified: tar-
formed the field of forensics, the scientific analysis of geted and copied quickly and precisely. Through PCR,
evidence for crime scene investigations and other legal a scientist can obtain enough DNA from even minute
proceedings. To produce a DNA profile, scientists com- amounts of blood or other tissue to allow a DNA profile
pare DNA sequences that vary from person to person. to be constructed. In fact, a microscopic sample with as
Figure 12.12 presents an overview of a typical investi- few as 20 cells can be sufficient for PCR amplification.
gation using DNA profiling. First, DNA samples are In principle, PCR is simple. A DNA sample is mixed
isolated from the crime scene, suspects, victims, or other with nucleotides, the DNA replication enzyme DNA
evidence. Next, selected sequences from each DNA polymerase, and a few other ingredients. The solution
sample are amplified (copied many times) to produce­ is then exposed to cycles of heating (to separate the
a large sample of DNA fragments. Finally, the am- DNA strands) and cooling (to allow double-stranded
plified DNA fragments are compared. All together, these DNA to re-form). During these cycles, specific regions ▼ Figure 12.13 DNA
steps provide data about which samples are from the of each molecule of DNA are replicated, doubling the ­ mplification by PCR. The
a
same individual and which samples are unique. amount of that DNA (Figure 12.13). The result of this polymerase chain reaction
(PCR) is a method for mak-
▼ Figure 12.12 Overview of DNA profiling. In this example, ing many copies of a specific
DNA from suspect 1 does not match DNA found at the crime ­segment of DNA. Each round
scene, but DNA from suspect 2 does match. of PCR, performed on a
­tabletop thermal cycler
(shown at top), doubles the
total ­quantity of DNA.

Crime scene Suspect 1 Suspect 2

1 DNA isolated

2 DNA amplified

Initial
DNA
segment

3 DNA compared

1 2 4 8
Number of DNA molecules

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 Chapter 12 chain reaction is an exponentially growing population forensic scientists typically compare about a dozen
DNA Technology of identical DNA molecules. The key to automated short s­ egments of noncoding repetitive DNA that are
PCR is an unusually heat-stable DNA polymerase, known to vary ­between people. Have you ever seen a
first isolated from prokaryotes living in hot springs puzzle in a ­magazine that presents two nearly identical
(such as those shown in Figure 13.15B). Unlike most photos and asks you to find the few differences between
proteins, this enzyme can withstand the heat at the them? In a similar way, scientists can focus on the few
start of each cycle. areas of difference in the human genome, ignoring the
A DNA molecule within a starting sample is likely identical majority.
to be very long. But, most often, only a very small Repetitive DNA, which makes up much of the
target region of that large DNA molecule needs to DNA that lies between genes in humans, consists of
be amplified. The key to amplifying one particular nucleotide sequences that are present in multiple cop-
­segment of DNA and no others is the use of p ­ rimers, ies in the genome. Some of this DNA consists of short
short (usually 15–20 nucleotides long), chemically sequences repeated many times tandemly (one after
synthesized single-stranded DNA molecules. For another); such a series of repeats in the genome is called
each experiment, specific primers are chosen that are a short tandem repeat (STR). For example, one person
­complementary to sequences found only at each end might have the sequence AGAT repeated 12 times in
of the target sequence. The primers thus bind to se- a row at one place in the genome, the sequence GATA
quences that flank the target sequence, marking the repeated 35 times at a second place, and so on; another
start and end points for the segment of DNA to be person is likely to have the same ­sequences at the same
amplified. Beginning with a single DNA molecule and places but with a different number of repeats. Like genes
the appropriate primers, automated PCR can generate that cause physical traits, these stretches of repetitive
hundreds of billions of copies of the desired sequence DNA are more likely to be an exact match between rela-
in a few hours. tives than b­ etween unrelated individuals.
In addition to forensic applications, PCR can be STR analysis is a method of DNA profiling that
used in the treatment and diagnosis of disease. For compares the lengths of STR sequences at specific
example, because the sequence of the genome of HIV sites in the genome. The standard STR analysis proce-
(the virus that causes AIDS) is known, PCR can be dure used by law enforcement compares the number
used to a­ mplify, and thus detect, HIV in blood or tis- of repeats of specific four-nucleotide DNA sequences
sue samples. In fact, PCR is often the best way to detect at 13 sites scattered throughout the genome. Each
this otherwise elusive virus. Medical scientists can now repeat site, which typically contains from 3 to 50 four-­
diagnose hundreds of human genetic disorders by us- nucleotide repeats in a row, varies widely from person
ing PCR with primers that target the genes associated to person. In fact, some STRs used in the standard
with these disorders. The amplified DNA product is procedure have up to 80 variations in the number of
then studied to reveal the presence or absence of the repeats. In the United States, the number of repeats
disease-causing mutation. Among the genes for human at each site is entered into a database called CODIS
diseases that have been identified are those for sickle- (Combined DNA Index System) administered by the
cell disease, hemophilia, cystic fibrosis, Huntington’s Federal ­Bureau of Investigation. Law enforcement
disease, and Duchenne muscular dystrophy. Individu- agencies around the world can access CODIS to search
CHECKPOINT als ­afflicted with such diseases can often be identi- for matches to DNA samples they have obtained from
Why is only the slightest fied ­before the onset of symptoms, even before birth, crime scenes or suspects.
trace of DNA at a crime allowing for preventative medical care to begin. PCR Consider the two samples of DNA shown in
scene often sufficient for can also be used to identify symptomless carriers of ­Figure 12.14. Imagine that the top DNA segment
forensic analysis? potentially harmful recessive alleles (see Figure 9.14). was obtained at a crime scene and the bottom from
Parents may thus be informed of whether they have a a suspect’s blood. The two segments have the same
analysis
to produce enough molecules for
Answer: because PCR can be used risk of bearing a child with a rare disease that they do number of repeats at the first site: 7 repeats of the four-­
not themselves display. nucleotide DNA sequence AGAT (in orange). Notice,
however, that they differ in the number of repeats at
Short Tandem Repeat (STR) Analysis the second site: 8 repeats of GATA (in purple) in the
How do you prove that two samples of DNA come crime scene DNA, compared with 12 repeats in the
from the same person? You could compare the en- suspect’s DNA. To create a DNA profile, a scientist uses
tire genomes found in the two samples. But such PCR to specifically amplify the regions of DNA that
an approach is impractical because the DNA of two ­include these STR sites. The resulting fragments are
humans of the same sex is 99.9% identical. Instead, then compared.

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 STR site 1 STR site 2 ◀ Figure 12.14 Short tandem DNA Profiling and
r­ epeat (STR) sites. Scattered Forensic Science
AGAT GATA
throughout the genome, STR sites
Crime scene DNA contain tandem repeats of four-­
nucleotide sequences. The number
of repetitions at each site can vary
Same number of Different numbers of from individual to individual. In this
short tandem repeats short tandem repeats figure, both DNA ­samples have the
same number of repeats (7) at the
first STR site, but ­different numbers
Suspect‘s DNA (8 versus 12) at the second.

AGAT GATA

Figure 12.15 shows the gel that would result from proved a convicted man innocent and also helped
using gel electrophoresis to separate the DNA frag- identify the true perpetrator.
ments from the example in Figure 12.14. (This figure Just how reliable is a genetic profile? In forensic
CHECKPOINT
simplifies the process; an actual STR analysis uses more cases using STR analysis with the 13 standard mark-
sites than 2 and uses a different method to visualize the What are STRs, and why
ers, the probability of two people having identical DNA
are they useful for DNA
results.) The differences in the locations of the bands profiles is somewhere between one chance in 10 bil- profiling?
reflect the different lengths of the DNA fragments. This lion and one in several trillion. (The exact probability STR sites.
gel would provide evidence that the crime scene DNA depends on the frequency of the individual’s particular numbers of repeats at the various

did not come from the suspect. markers in the general population.) Thus, despite prob-
different people have different
valuable for DNA profiling because
As happened in the case discussed in the Biol- lems that can still arise from insufficient data, human within the human genome. STRs are

ogy and Society section, DNA profiling can provide error, or flawed evidence, genetic profiles are now
repeated many times in a row
peats) are nucleotide sequences
­evidence of either guilt or innocence. As of 2014, ­accepted as compelling evidence by legal experts and Answer: STRs (short tandem re-

lawyers at the Innocence Project, a nonprofit legal or- scientists alike.
ganization located in New York City, have helped to ex-
onerate more than 310 convicted criminals in 35 states,
including 18 who were on death row. ­The ­average ▼ Figure 12.16 DNA profiling: proof of innocence and
guilt. In 1984, Earl Washington was convicted and sentenced
sentence served by those who were ­exonerated was 14 to death for a 1982 rape and murder. In 2000, STR analysis
years. In nearly half of these cases, DNA profiling has showed conclusively that he was innocent. Because every per-
also identified the true perpetrators. Figure 12.16 pres- son has two chromosomes, each STR site is represented by two
ents some data from a real case in which STR analysis numbers of repeats. The
table shows the number
of repeats for three STR
markers in three samples:
from semen found on the
Amplified Amplified victim, from Washington,
crime scene suspect’s and from another man
DNA DNA who was in prison after
an unrelated conviction.
These and other STR data
– (not shown) exonerated
Washington and led the
Longer
other man to plead guilty
fragments
to the murder.

Source of STR STR STR
sample marker 1 marker 2 marker 3
Shorter
+ fragments Semen on victim 17,19 13,16 12,12

▲ Figure 12.15 Visualizing STR fragment patterns. This
figure shows the bands that would result from gel electropho- Earl Washington 16,18 14,15 11,12
resis of the STR sites illustrated in Figure 12.14. Notice that one
of the bands from the crime scene DNA does not match one Kenneth Tinsley 17,19 13,16 12,12
of the bands from the suspect’s DNA.

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 Chapter 12
DNA Technology Investigating Murder,
Paternity, and Ancient DNA
Since its introduction in 1986, DNA profiling has
­become a standard tool of forensics and has provided
crucial evidence in many famous investigations. After
the death of terrorist leader Osama bin Laden in 2011,
U.S. Special Forces members obtained a sample of his
DNA. Within hours, a military laboratory in Afghani-
stan compared the tissue against samples previously
­obtained from several of bin Laden’s relatives, includ-
ing his sister who had died of brain cancer in a Boston
­hospital in 2010. Although facial recognition and an
eyewitness identification provided preliminary evidence,
it was DNA that provided a conclusive match, officially
ending the long hunt for the notorious terrorist.
DNA profiling can also be used to identify murder
victims. The largest such effort in history took place after
the World Trade Center attack on September 11, 2001.
Forensic scientists in New York City worked for years to
identify more than 20,000 samples of victims’ remains.
DNA profiles of tissue samples from the disaster site
were matched to DNA profiles from tissue known to be
from the victims or their relatives. More than half of the
victims identified at the World Trade Center site were
recognized solely by DNA evidence, providing closure
▲ Figure 12.17 Marie Antoinette. DNA profiling proved that
to many grieving families. Since that time, the victims of Louis (depicted with his mother in this 1785 painting), the son
other atrocities, such as mass killings during civil wars in of the Queen of France, did not survive the French Revolution.
Europe and Africa, have been identified using DNA pro-
filing techniques. In 2010, for example, DNA analysis was DNA profiling can also help protect endangered species
used to identify the remains of war crime victims who by conclusively proving the origin of contraband animal
had been buried in mass graves in Bosnia 15 years earlier. products. For example, analysis of seized elephant tusks can
DNA profiling can also be used to identify victims of nat- pinpoint the location of the poaching, allowing enforce-
ural disasters. After a tsunami devastated southern Asian ment officials to increase surveillance and prosecute those
the day after Christmas 2004, DNA profiling was used to responsible. In 2014, three tiger poachers in India were sen-
identify hundreds of victims, mostly foreign tourists. tenced to five years in jail after DNA profiling matched the
Comparing the DNA of a mother, her child, and the pur- dead tigers’ flesh to tissue under the poachers’ fingernails.
ported father can settle a question of paternity. Sometimes Modern methods of DNA profiling are so specific
paternity is of historical interest: DNA profiling proved that and powerful that the DNA samples can be in a partially
Thomas Jefferson or a close male relative fathered a child ­degraded state. Such advances are revolutionizing the study
with an enslaved woman, Sally Hemings. In another his- of ancient remains. For example, a 2014 study of DNA ex-
torical case, researchers wished to investigate whether any tracted from five mummified Egyptian heads (dating from
descendants of Marie Antoinette (Figure 12.17), one-time 800 b.c. to 100 a.d.) was able to deduce the geographic
queen of France, survived the French Revolution. DNA origins of the individuals, as well as identify DNA from the
extracted from a preserved heart said to belong to her son pathogens that cause the diseases malaria and toxoplasmo-
was compared to DNA ­extracted from a lock of Marie’s hair. sis. Another study determined that DNA extracted from
A DNA match proved that her last known heir had, in fact, a 27,000-year-old Siberian mammoth was 98.6% identical
died in jail during the revolution. More recently, a former to DNA from modern African elephants. Other studies in-
backup singer for the “Godfather of Soul” James Brown volving a large collection of mammoth samples suggested
sued his estate ­after his death, claiming that her child was that the last populations of the huge beasts migrated from
Brown’s son. A DNA paternity test proved her claim, and North America to Siberia, where separate species interbred
25% of Brown’s estate was awarded to the mother and child. and, eventually, died out several thousand years ago.

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 Bioinformatics
Bioinformatics

In the past decade, new experimental techniques The idea is that each type of base interrupts the current
have generated enormous volumes of data related to for a slightly different length of time. Such techniques,
DNA sequences. The need to make sense of an ever- if perfected, may usher in a new era of faster, even more
increasing flood of information has spawned the field ­affordable sequencing.
of ­bioinformatics, the application of computational
methods to the storage and analysis of biological data. In
this section, we’ll explore some of the methods by which Genomics
sequence data are accumulated, as well as many of the Improved DNA sequencing techniques have transformed
practical ways such knowledge can be put to use. the way in which we can explore fundamental biological
questions about evolution and how life works. A major
leap forward occurred in 1995 when a team of scientists
DNA Sequencing announced that it had determined the nucleotide se-
Researchers can exploit the principle of complemen- quence of the entire genome of Haemophilus influenzae,
tary base pairing to determine the complete nucleotide a bacterium that can cause several human diseases, in-
sequence of a DNA molecule. This process is called cluding pneumonia and meningitis. Genomics, the study
DNA sequencing. In one standard procedure, the DNA of complete sets of genes (genomes), was born.
is first cut into fragments, and then each fragment is The first targets of genomics research were bacteria,­
sequenced (Figure 12.18). In the past decade, “next- which have relatively little DNA (as you can see in
generation sequencing” techniques have been developed ­Table 12.1). But soon the attention of genomics researchers
that can simultaneously sequence thousands or hun-
dreds of thousands of fragments, each of which can be Table 12.1 Some Important Sequenced Genomes*
­400–1,000 ­nucleotides long. This technology makes it
Approximate
possible to ­sequence nearly a million nucleotides per Year Size of Genome Number
hour! This is an example of “high-throughput” DNA Organism Completed (in base pairs) of Genes
technology, which is currently the method of choice for
Haemophilus influenzae (bacterium) 1995 1.8 million 1,700
studies where massive numbers of DNA samples—even
Saccharomyces cerevisiae (yeast) 1996 12 million 6,300
representing an entire genome—are being sequenced.
In “third-­generation sequencing,” a single, very long Escherichia coli 1997 4.6 million 4,400
DNA molecule is sequenced on its own. Several groups (bacterium)

of ­scientists have been working on the idea of moving a Caenorhabditis elegans (roundworm) 1998 100 million 20,100
single strand of a DNA molecule through a very small
Drosophila melanogaster 2000 165 million 14,000
pore in a membrane (a nanopore), detecting the bases (fruit fly)
one by one by their interruption of an electrical current.
Arabidopsis thaliana (mustard plant) 2000 120 million 25,500
▼ Figure 12.18 A DNA sequencer. This high-throughput
Oryza sativa (rice) 2002 430 million 42,000
DNA sequencing machine can process half a billion bases
in a single 10-hour run. Homo sapiens (human) 2003 3.0 billion 21,000

Rattus norvegicus 2004 2.8 billion 20,000
(lab rat)

Pan troglodytes 2005 3.1 billion 20,000
(chimpanzee)

Macaca mulatta (macaque) 2007 2.9 billion 22,000

Ornithorhynchus anatinus 2008 1.8 billion 18,500
(duck-billed platypus)

Prunus persica (peach) 2013 227 million 27,900
*Some of the values listed are likely to be revised as genome analysis continues.

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 Chapter 12 turned toward more complex organisms with much larger Any sequence in the database can be ­retrieved and ana-
DNA Technology genomes. Baker’s yeast ­(Saccharo­myces ­cerevisiae) was lyzed. For example, software can compare a collection
the first eukaryote to have its full sequence determined, of sequences from different species and diagram them
and the roundworm Caenorhabditis elegans was the first as an evolutionary tree based on the sequence relation-
multicellular organism. Other sequenced animals include ships. Bioinformatics has thereby revolutionized evolu-
the fruit fly (Drosophila ­melanogaster) and lab rat (Rattus tionary biology by opening a vast new reservoir of data
norvegicus), both model organisms for genetics research. that can test evolutionary hypotheses. Next we’ll discuss
Among the sequenced plants are Arabidopsis thaliana, a particularly notable ­example of a sequenced animal
a type of mustard plant used as a model organism, and ­genome—our own.
rice (Oryza sativa), one of the world’s most economically
important crops.
As of 2014, the genomes of thousands of species
The Human Genome
have been published, and tens of thousands more are in The Human Genome Project was a massive scientific
progress. The majority of organisms sequenced to date endeavor to determine the nucleotide sequence of all the
CHECKPOINT are prokaryotes, including more than 4,000 bacterial DNA in the human genome and to identify the location
Approximately how many species and nearly 200 archaea. Hundreds of eukaryotic and sequence of every gene. The project began in 1990 as
nucleotides and genes are genomes—­including protists, fungi, plants, and animals
contained in the human both invertebrate and vertebrate—have also been com- ▼ Figure 12.19 Genome sequencing. In the photo at the
genome?
and 21,000 genes pleted. Genome sequences have been determined for bottom, a technician performs a step in the whole-genome
Answer: about 3 billion nucleotides cells from several cancers, for ancient