Forensic Genetics Module 6 PDF

Summary

This document provides an overview of Forensic Genetics module 6 from the University of Florida. It introduces DNA analysis in forensic practice. It emphasizes the uniqueness of DNA in individuals and the importance of forensic evidence in a judicial system. The document also describes the use of DNA in human identification, even in cases of mass disaster or paternity testing. The document mentions several keywords such as DNA analysis and forensic genetics.

Full Transcript

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Module 6: Page 1: Module Overview
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Module 6: DNA Profiling & Forensic Investigation Page 1 Module
Overview

Introduction
Now we will look to the use of DNA analysis as a tool in forensic practice...more on this is
a moment. This course, as mentioned at the start of the term, is designed as an
introduction to genetics and intended to be user friendly for non-geneticists, yet still be
useful to those who eat, sleep, drink, and socialize genes. Within the wider program of
University of Florida courses there are courses specifically detailing Forensic Analysis of
DNA, so this course is designed to address a headline of necessity, while providing a
grounding to the forensic aspects of DNA profiling. The Discussion Board for this course
remains a great way of tailoring the content to fit the class. From module 1 you will have
hopefully explored the web and decided and agreed with your classmates on a couple of
good websites to support your studies. These keep changing but if you have no websites
to consult let us know and we will try to help out! It may also be worth revisiting topics
such as genomic mapping, recombination, and population genetics as they are an
essential backdrop that we will not repeat here.

Within the field of forensic DNA analysis, the primary focus for the collection of evidence
might be summarized by some as convicting the guilty and freeing the innocent. Criminals
ultimately leave traces behind: biological evidence, fibers, modus operandi in repeated
crimes, financial records, cell phone traces, and so on. The task of the forensic scientist is
to collect and evaluate evidence to determine its usefulness in a robust judicial system.
Of course, there may be other reasons than crime to use such evidence, including
identification of individuals after a mass disaster or in paternity testing. DNA is one way of

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attempting to stamp individuality on the scene - "this individual was here because they left
a trace"; "this person must be the father". There may be other reason as well, for
example, "these remains are not human". Before DNA, and now alongside it, there was
blood group analysis, fingerprint comparison, and other forms of "profiling" of an
individual such as graphology and psychological profiling. Where DNA scores significantly
is its complete reliance on statistics from the very outset of the study of genetics. So DNA
does not claim to give absolute answers, but answers with a degree of confidence and
reliability unlike any other forensic discipline.

Objectives
By the completion of this module the student should:

Appreciate that an individual's DNA is believed to be unique
Realize what identical twins means at a DNA level!
Be able to review the history of DNA typing
Understand the uses of DNA testing
Understand the pitfalls of DNA testing
Have a general overview of the technology involved

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Module 6: Page 2: The Concept of Individuality
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Module 6: DNA Profiling & Forensic Investigation Page 2 The
Concept of Individuality

The Concept of Individuality
To some this may be an obvious place to begin, but the concept of individuality is a
surprisingly Western (and modern) one at a philosophical level. Think back in history, and
in some places today, how important family vengeance was, and how guilt passed from
one generation to the next. The importance of individuality is thus a product, not just of
biology, but also of culture. But having said that, we acknowledge that we are individuals;
each of us is unique. We know that identical twins are genetically identical, but we would
also concede that they are two individual people. to this, identity and individuality may be
considered slightly different concepts.

We are all different. In the past, fingerprint evidence and other less reputable means of
determining differences allowed crime investigation to focus on a single individual and
confirm their proximity to a crime scene. The discovery of DNA structure, and more
importantly, the development of readily usable technology, has revolutionized identity
matching. Perhaps at some point DNA will not be enough or will require additional
investigation. This is because, as we have alluded to in previous modules, DNA is
inherited from father and mother and during the life of an individual our somatic DNA is
subject to recombination and mutation. In the case of the genes, coding for
immunoglobulins in B lymphocytes and T cell receptors of T lymphocytes, recombination
results in hyper-variability, allowing differences in DNA sequence even between otherwise
identical twins. Whether this property is useful, how widespread, and if we would wish to
use it is another matter.

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We have 23 pairs of chromosomes. Between individuals we have about 99.5% similarity;
that is, we are only about 0.5% different. That may not seem a lot, but at approximately
2% different and you are a chimpanzee Links to an external site.. So in forensic
practice, we put a huge emphasis on this tiny proportion where we differ. Of our full
complement of DNA, only about 4% actually codes for anything and the greatest
variability is often in non-coding regions. For many years, these regions were referred to
as "junk DNA", but are increasingly termed "filler DNA", or simply, "non-coding DNA" in
forensic circles. In contrast to traditional genetic mapping, forensic DNA testing is not
about gene transcription, but is much more centered around variable, non-coding areas of
repetitive sequences that represent about a quarter of the genome.

Fine, so if individuality can be ascertained from exhaustive searching of DNA; what use
are fingerprints then? Maybe that is a question best addressed on the discussion board
but for starters:

In fingerprinting, we are brought up to believe everyone is unique, no two fingerprints are
identical (including identical twins). Just like snowflakes. The problem is that fingerprint
matching preceded modern day statistical analysis and has arguably never been robustly
validated. A small number of points are compared. If they match, then proof of identity is
presumed - but with what statistical certainty? This has been addressed in the
controversial 2016 United States PCAST report Links to an external site.. This report is
required reading for nearly every forensic science practitioner in the U.S and was
especially critical of those "comparison" fields of forensic science. A major issue...No
statistics - so instead we rely on expert opinion regarding the evidence. How do we know
it is believable? How can its scientific validity be tested? But we are not here to dismiss
other techniques, but instead to flag the concern that they appear to have less statistical
validity than DNA testing and that they seem to be regarded as a means of proving
identity, rather than the more scientific approach of disproof. But as in any evidence
scenario, several sources of valid data are more valuable than a single source, no matter
how scientific we might wish it to be.

What is uniqueness?
It would appear that maybe we cannot prove it, but we can have probabilities so
infinitesimal that to all intents and purposes we have established uniqueness. This is the
practical approach adopted by agencies such as the FBI and others, although the debate
continues. There are a couple of caveats though. Calculations depend on (i) the type of
DNA assay (ii) the number of different tests (iii) the degree of relatedness (ask yourself
what the effect would be if humans had multiple monozygotic pregnancies!).

Finally, and we will return to this, finding DNA at a scene is not confirmation of guilt.
Source attribution Links to an external site. may lead us to accept an individual as the
originator of the sample, but it does not prove complicity in a crime.

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Module 6: Page 3: A Historical Perspective
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Module 6: DNA Profiling & Forensic Investigation Page 3 A
Historical Perspective

A Historical Perspective
It was in the 1940s that DNA was implicated as the carrier of genetic uniqueness, and
1953 when Watson and Crick figured that DNA was packaged as a double helix. We see
approximately ten years or so between these two cardinal discoveries. In the late 1970s it
was realized that mapping the genome could be aided by utilizing enzymes which cut
DNA at restricted sequence specific sites. As individuals differ in where these enzymes
cut, thus giving different fragment sizes, the restriction fragment length polymorphism
(RFLP) was born! In 1984 Alec Jeffreys in Leicester, England used scaled up RFLP
technology to profile individuals' DNA. Three years later, in 1987, Colin Pitchfork entered
the history books with the dubious distinction of being betrayed by his own DNA. This is
the first criminal case reported to have used DNA evidence to assist in a conviction. Just
over a year later, polymerase chain reaction (PCR) Links to an external site.,
discovered by American biochemist Kary Mullis, finally emerged and made DNA
technology available to any laboratory and allowed massive scaling up of effort and
output. Genome mapping and sequencing followed in hot pursuit. By the late 1990s
cloning became a reality and Dolly the sheep Links to an external site. was born. During
this time the forensic community had moved from the classical Jeffreys' approach, looking

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at multiple loci with large amounts of DNA being required and Southern blot analysis, to
single locus testing and the use of PCR to study tiny amounts of source DNA, that may
even be quite seriously degraded.

Further refinement came with exploitation of the stability of mitochondrial DNA in historical
or decomposed tissues to identify maternal identity. Mitochondrial DNA is almost entirely
inherited as a single haplotype from the mother as it is present in the oocyte. The study of
two hypervariable regions allows lineage tracing and identification of remains between
maternally unrelated sources. By analogy, the study of variable regions of the Y
chromosome facilitated studies of paternal lineage.

An emerging profiling technique in forensic DNA laboratories is the use of Next
Generation Sequencing (NGS). NGS was originally referred to as massively-parallel
sequencing, because it allowed for decoding of multiple DNA strands simultaneously in
contrast to the single strand Sanger style sequencing Links to an external site.
performed by capillary electrophoresis (CE). Moreover, the addition of targeted Single
Nucleotide Polymorphism (SNP) arrays has spawned an entirely new avenue for forensic
identification in the field of Investigative Genetic Genealogy (IGG) Links to an external
site.. Criminal investigations that have sat "cold" for years, have now been solved in
recent years using this new ancestral-based technology. One example is that of Seattle
Washington's Green River killer Links to an external site..

And finally, before we move on, not just humans can be DNA profiled. Potatoes,
elephants, strawberries, whatever can all be profiled as an aid in breeding programs,
conservation projects, and even for use in forensic practice.

Should we test everyone?
If everyone from a population was DNA typed, any sample collected should, in theory, be
attributable. Any crime scene, for example a rape, where DNA evidence is collected
should lead to rapid identification and apprehension of the guilty party. True or false?
Again the argument hinges on the distinction between excluding or including an
individual. What should we collect? DNA and retain the sample indefinitely, or the result of
the DNA profiling?

If we have DNA from everyone, can we then use it to look for gene-disease associations?

Are an individuals' rights to privacy protected if their ancestry SNP profile in a database is
used to identify a familial relative using IGG?

How available should the information be to law enforcers, courts, insurance companies,
or government?

What happens if I discover inadvertently that I am not my child's genetic parent? What
are the long-term implications of knowing?

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You may already have raised and discussed these issues in relation to Assignment 6, if
not, this should be more food for thought and discussion now.

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Module 6: Page 4: Some Technical and Other Pitfalls
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Module 6: DNA Profiling & Forensic Investigation Page 4 Some
Technical and Other Pitfalls

Some Technical and Other Pitfalls
Before we briefly visit the methodology of DNA testing, there are some vital points to
consider. The optimal place to learn the practicalities of DNA testing is in an operational
laboratory or in an academic laboratory specializing in teaching quality assurance and
control. The best place is not by distance learning in the comfort of your own home or
workplace! However, the great advantage of distance education is the opportunity to
reflect, discuss, and think the unthinkable. Many of the potential pitfalls are of course well
known to you. We will mention some in no particular order and encourage you to extend
the list and discussion on the course Discussion Board.

Contamination
As in every example where you are seeking to gather evidence, the sampling procedures
used and the degree of technical skill, verified by good quality assurance protocols, must
be of the highest standards. The potential for contamination occurs at nearly every stage
of laboratory analysis: sampling of the evidence, extraction of DNA from the substrate,
quantification, amplification, and setup of the sample for an NGS or CE run. This is why
standard operating procedures (SOPs), good laboratory practices (GLP), and audit and
quality assurance schemes are all essential for a modern scientific laboratory. A further
important point to emphasize, is that collection of evidence in the field, if improperly
performed, ruins everything that follows, no matter how good the science is. Some use
the term, "garbage in-garbage out", other variations exist... Protocols must start at the

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scene of a crime and evidence gathering. Straying from this goal may have the collateral
effect of discrediting the laboratory and could potentially limit the use of the evidence in a
court of law.

Degradation
Warm, humid conditions, bacterial contamination from soil, gastric contents, exposure to
the air, decomposition, fire, and chemicals may all cause DNA to degrade. For the
classical approach of RFLP analysis, large amounts of DNA in good condition are
required. Any of the factors above may degrade the DNA to small, unusable fragments.
PCR can deal more readily with small fragments, and mitochondrial DNA may survive
longer in a useful form. Tooth pulp may be a useful repository for DNA if all else fails. After
collection of a sample, it is important to stop further degradation as quickly as possible.
Degraded DNA often results in partial resolution of a DNA result or even a failed test.
Particularly in PCR assays this is worth remembering. If a PCR assay gives a positive
result or a negative one there is a danger of a failed assay being mistaken for a negative
result. Validation of DNA quality is always a useful check as well as optimal design of
PCR strategies. The majority of chemistries used to quantify and amplify DNA in forensic
laboratories have incorporated measures to assess situations of possible DNA
degradation and inhibition due to external agents. This allows the scientist to take
preventative measures to combat these issues in order to obtain the best outcomes.

Mixtures
In a sexual assault, the majority of DNA collected may be from the victim, especially if
there is bleeding. If the assailant was reported to have worn a condom, has had a
vasectomy, or is otherwise azospermic (too few sperm), there may be very little of the
assailant's DNA to deposited. Approaches developed to analyze such samples must take
into consideration that the assailant's DNA may be a minority of the sample and care
must be taken to maximize its usefulness. Find out what techniques can be employed to
try to overcome such difficulties and share your findings with your colleagues on the
Discussion Board for this module. You may also wish to speculate on the Discussion
Board whether may be other concerns inherent with analysis of very small amounts of
DNA from sperm cells, which originate as a result of meiotic division and are, therefore,
haploid.

Approaches have been developed to try to deduce which alleles in a mixed sample come
from the same source on the basis of the strength of signal the different alleles produce
when they are detected. The theory being that if you have four alleles at a locus, two of
which give a very strong signal of equivalent strength and two of which give a much
weaker signal of equivalent strength the two stronger alleles came from one individual
and the two weaker alleles from another individual. This may seem plausible if we
surmise that the DNA from one of the contributors was in excess of the other in the
sample analyzed, but what other alternatives might have given rise to this result?

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Consider the scenario when we have 5 peaks - how many different individuals might have
contributed to the sample? Think about all the scenarios where we have individuals who
are heterozygous for alleles, homozygous for alleles, and the situation where individuals
share alleles in common. Remember we may not always have a distinction in the peak
height that might provide a clue to the allele allocation. Mixture analysis is complex and
should not be considered definitive. Often, the mixture in its entirety must be considered
when formulating determinations on the number of contributors (NOC) along with the
presence of major, minor, and contributions foreign to those reasonably assumed to be
present. Over the past decade, technological advancements using statistical algorithms
have been employed to assist in these aspects of mixture deconvolution. These will be
discussed later in this course.

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Module 6: Page 5: Some Technical and Other Pitfalls -
Continued
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Module 6: DNA Profiling & Forensic Investigation Page 5 Some
Technical and Other Pitfalls - Continued

Some Technical and Other Pitfalls - Continued

"Innocent" presence of DNA
Let's say I visit your home (which you will be relieved to learn is not very likely), you may
offer me some hospitality. I may use your bathroom. I may shed some hairs and/or touch
some items while washing. Now suppose your residence is burglarized and your home
transforms to a crime scene. Samples are obtained of hairs, swabs of "touched" surfaces,
and so on. The DNA analysis is performed on the items collected. If my DNA is present
does that make me a suspect? Well, yes maybe - but hopefully I have a cast iron alibi. It
wasn't me - honest! My DNA may easily be at a scene for perfectly explainable reasons.
DNA is fairly stable given reasonable environmental conditions and so its presence in
space cannot be linked to its presence in time - that is the time of a crime. The ability to
detect increasingly smaller traces of DNA by techniques such as LCN (Low Copy
Number) DNA analysis should ring alarm bells with the competent scientist. Beware the
temptation to attach greater significance to the fact that a profile might be detected – in
actual fact it wasn't me there at all; perhaps someone else had borrowed my coat. The
presence of my DNA does not even confirm my presence at the scene. It is simply an
observation to be reconciled to every other piece of data. By contrast if my fingerprints
were found at the scene at least we can be sure I was physically there, if you believe the
fingerprint analysis that is...

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Quality assurance
Although it is not typically talked about when referring to forensic laboratories in regular
conversation, the importance of quality assurance and control cannot be understated.
Suffice is to say here that going through the motions is not enough. There must be a
translation of procedure into verifiable practice. There is sometimes an interesting debate
within my laboratory staff (not in the clinical laboratories but the research laboratories)
how the relative quality and skill of their molecular genetic work compares to a "jobbing"
forensic profiling or sequencing laboratory. The answer is, of course, that in general the
"non-academic" laboratory has much more stringent standards and procedures. The
forensic laboratory cannot afford a false positive later corrected, or a false negative, and
there is no scope for asking for a better sample because the freezer broke down. A solid
quality assurance program is essential to any modern forensic laboratory and will surely
have individuals (Quality Managers/Officers) whose entire focus is maintaining the quality
system.

Prosecutor's fallacy
It's not within the scope of this module to cover the area of DNA interpretation and
statistics in depth, but we have already stressed how important statistics are in
presentation of DNA evidence. Remember that we have moved away from the term DNA
"fingerprinting" to "profiling" or "typing" because the former has connotations of exactness
that we (incorrectly) associate with conventional fingerprinting. The level of proof we
require will vary. Identification of lineage in an anthropological survey is less stringent
than the identification of an alleged rapist. In practice, a number of assays are performed
that lead to a degree of unlikeliness that anyone other than the suspect is the source of
the DNA. But it is only a degree of probability, a confidence limit. If I develop a DNA
profile from an evidentiary item and calculate that the probability of a DNA match with
someone other than the suspect is 1 in 1 million, what am I saying?

Let's suppose there are not reasons locally, such as inbreeding and an identical twin, to
complicate matters, we can say confidently that we cannot exclude the suspect with a
probability of being right 999,999 out of 1,000,000 times. Of course, a further set of
polymorphic markers may just prove that one time in a million and we can go on and
exclude involvement. It is apparent that the fewer tests we use (the fewer polymorphic
markers we look at) the more likely we are to fail to exclude an innocent party as a
possible source of the DNA. The prosecutor's fallacy is to transpose the unlikeliness of
being able to exclude guilt (1 in 1 million) as being the same as the probability of guilt and
there is, therefore, 999,999 chances in 1,000,000 that the suspect is guilty as charged!

We had better mention the defender's fallacy as well, if there is a one in a million chance
of this not being the suspect's DNA then in a country with a population of 300 million, 299
other people will match this DNA profile. Therefore, the accused has a 299 in 300 chance

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of being innocent! Confused? It sure can be. This example reveals the importance of the
scientist presenting their results in an unbiased and appropriate manner in legal
proceedings.

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Module 6: Page 6: DNA Extraction and Polymerase
Chain reaction (PCR)
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Module 6: DNA Profiling & Forensic Investigation Page 6 DNA
Extraction and Polymerase Chain reaction (PCR)

DNA Extraction and Polymerase Chain reaction (PCR)
High-grade DNA material is not usually available in forensic investigations and so
extraction is a critical phase of the DNA analysis procedure to ensure there is maximal
return of quality and quantity of the DNA extract. In addition, the end product must be free
from contaminant chemical impurities that inhibit PCR reactions. Details (procedures
manuals) for extraction methodologies are readily available online from commercial
manufacturers of biochemical and molecular biology products, public forensic labs, and
other sources.

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Polymerase chain reaction (PCR) is an invaluable technique, because it can be used (i)
on small samples (ii) small fragments, for example those obtained from degraded DNA
(iii) much of the process can be automated (iv) it is rapid (v) it does not require use of
radioactive probes. The key is to design oligonuleotide primers, which we commonly refer
to as primers, that correspond to genomic nuclear or mitochondrial DNA. Under
appropriate conditions, these anneal to their complementary sequence in the sample
DNA, which has taken up the single stranded form. The addition of a polymerase enzyme
produces a new strand of DNA at the site of interest: think back to the process of DNA
replication and you will see the similarities. The fascinating bit to PCR is that the enzyme
is thermostable. The heat-resistant polymerase commonly used for PCR is derived from
the bacterium Thermus Aquaticus (known as Taq Polymerase) which are found in hot
springs; originally discovered in Yellowstone Nation Park in the Pacific Northwest of the
United States. Using Taq Polymerase, we can heat the sample to separate the new
strands from the original template in order to get the single stranded form again and on
cooling, the strands recombine, but because there is still lots of primer, these will anneal
to their complementary sequence and we can again generate new strands as the enzyme
has not been denatured by heat. Cycle after cycle of this process results in an
exponential increase in the target sequence quite specifically. Hence, the name
polymerase chain reaction, or PCR.

Restriction Fragment Length Polymorphism (RFLP)

It was the Restriction Length Fragment Polymorphism (RFLP) technique that was the
original method of DNA analysis applied to forensic casework back in the 1980s and it
was this method that was dubbed "DNA fingerprinting". With RFLP analysis more DNA is
required than for the techniques currently employed and the DNA must have a larger
fragment size. DNA aliquots are digested with restriction enzymes that cut only at specific
known sites in the DNA strand. When DNA from different individuals is digested,
polymorphisms result in different sizes after cutting with the restriction enzyme. These
can be separated by electrophoresis on a gel according to size. The gel is made of
polyacrylamide which acts like a sieve by virtue of pores which form in the gel as it "sets"
or crosslinks. When a potential difference is applied across the gel the negatively charged
DNA molecules migrate through the gel from the cathode (negative electrode) to the

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anode (positive electrode). The smaller the DNA fragment the easier it is for it to "wiggle"
its way through the gel. Larger fragments are retained in the gel for longer and, hence,
the fragments will travel through the gel at a rate that is inversely proportional to their
length. After separation the entire genomic DNA, comprising different sized fragments, is
present on the gel so the whole thing is an unsightly smear of DNA! What we need to do
is be able to identify and highlight the variable regions we are interested in and then
visualize them to record the presence of bands which will be unique to the individual if
sufficient different sites are studied. Visualization again relies on the property of DNA
when denatured to lose its double strand conformation on heating but regain it on cooling.
Instead of interposing a primer on cooling the trick for RFLP analysis is to have a short
probe made from the target sequence, labeled with radioactivity or some other marker.
This binds to the denatured single stranded DNA fragments and can be detected by
detecting the radioactivity or fluorescence. Because the probe binds the digested
genomic DNA wherever it migrated in the gel the size of visualized fragments can be
measured and different samples compared.

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Module 6: Page 7: So What Strategy Should We Use?
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Module 6: DNA Profiling & Forensic Investigation Page 7 So What
Strategy Should We Use?

So What Strategy Should We Use?
Up to 15 sites of extremely variable DNA can be studied by RFLP analysis. Some of the
limitations of classic RFLP analysis were analysis time, DNA quantity required, and
quality of the sample, but the results can be extremely accurate and thorough, allowing
really impressive statistical significance for the time. The original work of Jeffreys relied
upon a probe that bound to a number of different loci. Newer applications have tended
towards single locus probes that increase the stringency of hybridization reactions. Use of
four single locus probes can give very good DNA profiles that are technically repeatable,
but of course the downside is that the power of discrimination (that is the ability to exclude
samples as being the same, or to confirm uniqueness) is reduced.

STR Profiling
The use of short tandem repeats (STR) as a target exploits using markers which are
highly variable. STRs are preferred to larger polymorphisms (variable number tandem
repeats VNTRs) because of the attractiveness of being able to automate STR analysis
and use PCR on degraded DNA. STRs are based on loci with tetranucleotide repeats
with nigh on 90 different alleles at some of the loci tested, for example the D21S11 locus1.
The different alleles differ in the number of times the particular tetranucleotide being
analyzed is repeated at the locus, which may vary from a few to dozens of times.
Because of the small size of the STR loci and extreme variability PCR analysis is an ideal
approach and indeed several different loci may be studied in the same PCR reaction.
This is referred to as multiplexing. If fluorescent labeled nucleotides are used, the results
can be read by a Genetic analyzer, allowing greater throughput and standardization.

Traditional DNA sequencers utilized vertical polyacrylamide slab gels to separate the
PCR products on the basis of their size, as described previously. However, since their
introduction in the mid-90s, forensic laboratories have the shift to separate the fragments
by capillary electrophoresis (CE). Rather than having a large slab gel of polyacrylamide,
capillary electrophoresis uses fine capillaries of 50-100μm diameter which are packed
with a viscous polymer through which the DNA fragments migrate. The polymer serves
the same purpose as the polyacrylamide "sieve", but the capillary electrophoresis system

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has the advantage in being able to separate a sample in minutes rather than hours,
because higher voltages can be used in the separation. Minute amounts of sample are
needed for the analysis, which makes it preferable when samples are in short supply and
increases the possibility for reanalyzing samples if need be. The system can be fully
automated (injecting the sample, separating the fragments and fragment detection) and
there is no risk of cross-contamination between lanes of the gel or a need to track lanes
for that matter. The first CE instruments introduced had a single capillary and would
process one sample at a time. Although more time consuming than modern-day CEs, the
ease of detection was an acceptable trade-off from that of the slab-style instrumentation.

Applied Biosystems 3500 Genetic Analyzer -image credit to Thermofisher.com

However, capillary arrays have now been developed such as the Applied Biosystems
3500Genetic Analyzer, 8 capillary system shown which has 8 individual capillary tubes
combine in an array.

If four or five STR loci are examined this gives a high level of discrimination between
samples and individuals, but the number of loci studied can be increased depending on
background variability (for example, related to ethnicity) and the importance of exclusion
in the case being examined. The more loci that are used to generate a DNA profile the
less likely it is to get an adventitious match.

In the United States, the Federal Bureau of Investigation (FBI) CODIS database formerly
required typing 13 STR loci which were referred to as "the core 13"; however, in 2017
moved to requiring an expanded 20 loci for DNA profiles entered into the US national
database, which is known as NDIS (National DNA Index System). The software for
management of the database and profile comparisons is called CODIS (COmbined DNA
Index System) and is used for NDIS as well as databases at U.S. state (SDIS) and local
(LDIS) crime lab levels (and also in some select non-U.S. countries). Commercially

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available amplification "kits" are used that include the required 20 loci. The UK National
DNA Databasestores profiles produced from commercially available kits encompassing
16 loci, Scotland uses 21 loci. The likelihood of obtaining a match from two unrelated
individuals by chance when comparing two full profiles is presented in Court as being in
the neighborhood of 1 in 1 billion or greater. The electropherogram below depicts
appearance of a modern STR profile.

Positive Control 9948 - Qiagen Investigator 24plex kit, Analyzed using Life Technologies
Genemapper ID-X software

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