The Biotechnology Education Company ®
sed
Revi nd
a
ated
Upd
EDVO-Kit #
VNTR Human
DNA Typing
Using PCR
334
Storage: See Page 3 for
specific storage instructions
EXPERIMENT OBJECTIVE:
In this experiment, students will use their own genomic DNA.
Using Polymerase Chain Reaction (PCR) and Agarose Gel
Electrophoresis, they will identify polymorphisms in
the D1S80 region of their chromosome 1.
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334.130821
2
EDVO-Kit #
VNTR Human DNA Typing Using PCR
334
xxx
Table of Contents
Experiment Components
3
Experiment Requirements
4
Background Information
5
Experiment Procedures
Experiment Overview and General Instructions
9
Module I-A: Isolation of DNA from Human Cheek Cells
10
Module I-B: Isolation of DNA from Human Hair
11
Module II: Amplification of the D1S80 Locus
12
Module III: Separation of PCR Reaction Products
by Agarose Gel Electrophoresis
15
Study Questions
18
Instructor's Guidelines
19
Pre-Lab Preparations
20
Experiment Results and Analysis
23
Study Questions and Answers
24
Appendices
25
A
Troubleshooting Guides
26
B
Preparation and Handling of PCR Samples With Wax
28
C
Bulk Preparation of Agarose Gels
29
Material Safety Data Sheets can be found on our website:
www.edvotek.com
334.130821
13
Module IV: Staining Agarose Gels
EDVOTEK, The Biotechnology Education Company, and InstaStain are registered trademarks of
EDVOTEK, Inc. UltraSpec-Agarose, PCR EdvoBeads, and FlashBlue are trademarks of EDVOTEK, Inc.
EDVOTEK - The Biotechnology Education Company® • 1-800-EDVOTEK • www.edvotek.com
VNTR Human DNA Typing Using PCR
3
EDVO-Kit #
334
Experiment Components
Experiment # 334 contains
material for up to 25 human DNA
typing reactions.
Sample volumes are very small.
It is important to quick spin the
tube contents in a microcentrifuge
to obtain sufficient volume for
pipetting. Spin samples for 10-20
seconds at maximum speed.
Component
Storage
Check (√)
A
Tubes with PCR EdvoBeads™
Each PCR EdvoBead™ contains
• dNTP Mixture
• Taq DNA Polymerase Buffer
• Taq DNA Polymerase
• MgCl2
• Reaction Buffer
Room Temperature
❑
B
D1S80 Primer mix concentrate
-20°C Freezer
❑
C
200 base pair ladder
-20°C Freezer
D
Control DNA concentrate
-20°C Freezer
E
TE buffer
-20°C Freezer
F
Proteinase K
Room temperature
❑
❑
❑
❑
NOTE: Components B and D are now supplied in concentrated form.
Reagents & Supplies
Store all components below at room temperature.
Component
All components are intended for
educational research only. They
are not to be used for diagnostic
or drug purposes, nor administered to or consumed by humans
or animals.
Check (√)
•
UltraSpec-Agarose™
•
Electrophoresis Buffer (50x)
•
10x Gel Loading Solution
•
InstaStain® Ethidium Bromide
•
FlashBlue™ Liquid Stain
•
Conical tube (15 ml)
•
Microcentrifuge Tubes
•
PCR tubes (0.2 ml - for thermal cyclers with 0.2 ml template)
•
Disposable plastic cups
•
Salt packets
•
Wax beads (for waterbath option or thermal cyclers
without heated lid)
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1-800-EDVOTEK • www.edvotek.com
FAX: 202-370-1501 • email: info@edvotek.com
334.130821
❑
❑
❑
❑
❑
❑
❑
❑
❑
❑
❑
4
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
xxx
Experiment Requirements
*If you do not have a thermal
cycler, PCR experiments can
be conducted, with proper
care, using three waterbaths.
However, a thermal cycler
assures a significantly higher
rate of success.
•
(NOT included in this experiment)
•
•
•
•
•
•
•
•
Thermal cycler (EDVOTEK Cat. # 541 highly recommended)
or three waterbaths*
Horizontal gel electrophoresis apparatus
D.C. power supply
Balance
Microcentrifuge
Waterbath (55º C and boiling) (EDVOTEK Cat. # 539 highly recommended)
UV Transilluminator or UV Photodocumentation system (use if staining with
InstaStain® Ethidium Bromide)
UV safety goggles
White light visualization system (optional - use if staining with
FlashBlue™)
Automatic micropipets (5-50 µl) with tips
Microwave or hot plate
Pipet pump
250 ml flasks or beakers
Hot gloves
Disposable laboratory gloves
Distilled or deionized water
Spring water
•
•
Ice buckets and ice
Bleach solution
•
•
•
•
•
•
•
•
334.130821
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
5
334
VNTR Human DNA Typing
In humans, DNA is packaged into 23 pairs of chromosomes that are
inherited from an individual’s biological parents. Although most
of this genetic material is identical in every person, small differences or “polymorphisms” in the DNA sequence occur throughout
the genome, making each of us unique. For example, the simplest
difference is a Single Nucleotide Polymorphism (or SNP). Short
repetitive stretches of DNA at specific locations in the genome can
vary in number to produce STRs (Short Tandem Repeats) and longer
repetitive segments are called VNTRs (Variable Number of Tandem Repeats). Most polymorphisms occur in non-coding regions
of DNA, but those that do not may disrupt a gene and can result
in disease. Medical diagnostic tests are used routinely to identify
specific polymorphisms associated with disease.
The first use of forensic DNA fingerprinting occurred in the United
Kingdom in 1984, following the pioneering work of Dr. Alex Jeffreys at the University of Leicester. Analysis by Jeffreys led to the
apprehension of a murderer in the first DNA fingerprinting case
in September, 1987. The first conviction using DNA evidence occurred on November 6, 1987 in Orlando, Florida. Since then, DNA
analysis has been used in thousands of convictions. Additionally,
hundreds of convicted prison inmates have been exonerated from
their crimes, including several death row inmates. The original DNA
fingerprinting technology utilized a method called Restriction Fragment Length Polymorphism (RFLP) analysis, which involves digesting the DNA with restriction enzymes, separating the fragments
by agarose gel electrophoresis, transferring the DNA to a membrane, and hybridizing the membrane with probes to polymorphic
regions. Although RFLP is very precise, it is time-consuming and
requires large amounts of DNA. Because of this, the RFLP method
is no longer used in forensics; however, it remains in use in certain
medical diagnostic tests.
STR - 2-6 bp repeats, repeated
3-100 times.
CRIME SCENE
Hair
Body Fluid
Stain
Skin
Cells
SUSPECT #1
SUSPECT #2
Blood Draw
Blood Draw
Treat to release DNA
Perform PCR
to amplify
specific
polymorphic
regions
Crime Suspect Suspect
Scene
#2
#1
Suspect #2 matches
Crime Scene
Figure 1:
Extraction and Electrophoresis of
DNA Samples
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reserved.
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Background Information
Analyzing several different polymorphisms within a person’s
genome generates a unique DNA “fingerprint”. DNA fingerprints
can allow us to distinguish one individual from another. Because
polymorphisms are inherited, DNA fingerprints can also be used to
determine paternity/maternity (and other familial relationships).
The best-known application of DNA fingerprinting is in the field
of forensic science. The first step in forensic DNA fingerprinting is
the legal collection of biological evidence (often present as a stain)
from the crime scene or victim. The sample is treated with a detergent to rupture (lyse) cell membranes, and the cellular DNA is extracted for further analysis (Figure 1). After DNA is extracted from
these samples, forensic scientists can develop a DNA fingerprint.
The DNA fingerprint from a crime scene can then be compared
to the DNA fingerprints of different suspects. A match provides
strong evidence that the suspect was present at the crime scene.
NOTE:
VNTR - 15 - 70 bp repeats,
repeated five to 100 times.
6
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Background Information
VNTR Human DNA Typing
Today, forensic scientists use the Polymerase Chain Reaction (PCR) to produce DNA fingerprints. PCR is a
technology that has further revolutionized the science of DNA fingerprinting based on its ease of use and
its ability to amplify DNA. This technique allows researchers to quickly create many copies of a specific region of DNA in vitro. PCR requires 500-fold less DNA than traditional RFLP analysis and it can be performed
in one afternoon. PCR was invented in 1984 by Dr. Kary Mullis at the Cetus Corporation in California. For
this ground breaking technology, Mullis was awarded the Nobel Prize in Chemistry in 1993.
Forensic scientists use PCR to analyze highly polymorphic DNA regions. By examining several different
VNTRs or STRs from the same individual, investigators obtain a unique DNA fingerprint for that individual
which is unlike that of any other person (except for an identical twin). One VNTR, known as D1S80, is
present on human chromosome 1. It comprises a 16-nucleotide sequence that is repeated between 16 and
40 times. An individual who is homozygous for the D1S80 genotype will have equal repeat numbers on
both homologues of chromosome 1, displaying a single PCR product following agarose gel electrophoresis
(Figure 2A). More commonly, a person will be heterozygous at this loci, resulting in differing D1S80 repeat
numbers. Amplification of DNA from heterozygous individuals will result in two distinct PCR products
(Figure 2B). For most applications, law enforcement agencies will analyze STRs, as their smaller size makes
them easier to amplify, thus requiring less starting DNA.
Before performing PCR, template DNA is extracted from various biological sources (in forensic cases blood, tissue, or bodily fluid). Because PCR is very sensitive, only a few copies of the gene are required.
Nevertheless, freshly isolated DNA will provide better amplification results than older DNA specimens that
may have become degraded. In order to amplify the specific DNA or target sequence, two primers (short &
synthetic DNA molecules) are designed to correspond to the ends of the target sequence.
To perform PCR, the template DNA and a molar excess of primers are mixed with the four “free” deoxynucleotides (dATP, dCTP, dGTP, and dTTP), and a thermostable DNA polymerase. The most commonly used
DNA polymerase is Taq DNA polymerase. This enzyme, originally purified from a bacterium that inhabits
hot springs, is stable at very high temperatures. These components (template DNA, primers, the four deoxynucleotides, and Taq DNA polymerase) are mixed with a buffer that contains Mg+2, an essential
Figure 2A:
Homozygous
Condition
(Lane B) Maternal
Figure 2:
PCR Amplification
Products of D1S80
Primer 1
200 base
pair ladder
(Lane A)
Paternal
A
B
C
Primer 1
Paternal
1200bp
Primer 2
1000bp
800bp
Maternal
600bp
Figure 2B:
Heterozygous
Condition
(Lane C)
400bp
200bp
Primer 2
Gel results are not drawn to scale.
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reserved.
334.130821
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
7
334
VNTR Human DNA Typing
Target Sequence
= Separation of
two DNA strands
5'
3'
3'
5'
5'
3'
3'
5'
= Primer 1
Cycle 1
5'
5'
3'
3'
3'
3'
5'
Anneal
2 primers
40°C - 65°C
3'
5'
5'
5'
3'
5'
5'
5'
5'
5'
3'
5'
5'
5'
3'
5'
5'
3'
3'
5'
5'
3'
5'
5'
Denature
94°C
5'
5'
5'
3'
Cycle 3
Cycle 2
3'
5'
The Experiment
= Primer 2
3'
5'
5'
5'
3'
5'
5'
3'
3'
5'
5'
3'
5'
Figure 3: Polymerase Chain Reaction
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reserved.
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Extension
72°C
8
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
VNTR Human DNA Typing
Background Information
cofactor for Taq polymerase. The PCR reaction mixture is subjected to sequential heating/cooling cycles at
three different temperatures in a thermal cycler.
•
In the first step, known as “denaturation”, the mixture is heated to near boiling (94° C - 96° C) to “unzip” (or melt) the target DNA. The high temperature disrupts the hydrogen bonds between the two
complementary DNA strands and causes their separation.
•
In the second step, known as “annealing”, the reaction mixture is cooled to 45° C - 65° C, which allows
the primers to base pair with the target DNA sequence.
•
In the third step, known as “extension”, the temperature is raised to 72° C. This is the optimal temperature at which Taq polymerase can add nucleotides to the hybridized primers to synthesize the new
complementary strands.
These three steps - denaturation, annealing, and extension - constitute one PCR “cycle” (Figure 3). Each
PCR cycle doubles the amount of the target DNA in less than five minutes. In order to produce enough
DNA for analysis, twenty to forty cycles may be required. To simplify this process, a specialized machine,
called a “thermal cycler” or a “PCR machine”, was created to rapidly heat and cool the samples.
A match between the crime scene DNA and a suspect’s DNA at a single locus does not prove guilt, nor does
it rule out innocence. Therefore, multiple loci are tested. In 1990, the Federal Bureau of Investigation (FBI)
established the Combined DNA Index System (CODIS), a system which allows comparison of crime scene
DNA to DNA profiles in a convicted offender and a forensic (crime scene) index. A match of crime scene
DNA to a profile in the convicted offender index indicates a suspect for the crime, whereas a match of
crime scene DNA to the forensic index (a different crime scene) indicates a serial offender. The DNA fingerprints stored in CODIS contain data on thirteen loci (see Figure 4). The odds of a match at all thirteen loci
are less than one in a trillion. CODIS has now been used to solve dozens of cases where authorities had not
been able to identify a suspect for the crime under investigation.
1
2
3
4
5
6
7
8
A
9
10
11
12
H
I
13
14
15
16
17
18
19
J
22
X
L
K
D
G
E
21
M
B
C
20
F
Figure 4:
13 CODIS Core STR Loci and Chromosomal Position
CODIS Sites:
A - TPOX
B - D3S1358
C - FGA
D - D5S818
E - CSF1PQ
F - D7S820
G - D8S1179
H - TH01
I - VWA
J - D13S317
K - D16S539
L - D18S51
M - D21S11
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reserved.
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Y
VNTR Human DNA Typing Using PCR
EDVO-Kit #
9
334
Experiment Overview and General Instructions
EXPERIMENT OBJECTIVE:
In this experiment, students will use their own genomic DNA. Using Polymerase
Chain Reaction (PCR) and Agarose Gel Electrophoresis, they will identify polymorphisms in the D1S80 region of their chromosome 1.
Wear gloves
and safety goggles
Be sure to READ and UNDERSTAND the instructions completely BEFORE starting
the experiment. If you are unsure of something, ASK YOUR INSTRUCTOR!
•
Wear gloves and goggles while working in the laboratory.
•
Exercise caution when working in the laboratory – you will be using equipment that can be dangerous if used incorrectly.
•
Wear protective gloves when working with hot reagents like boiling water
and melted agarose.
•
DO NOT MOUTH PIPET REAGENTS - USE PIPET PUMPS.
•
Always wash hands thoroughly with soap and water after working in the
laboratory.
•
Contaminated laboratory waste (saliva solution, cup, pipet, etc.) must be
disinfected with 15% bleach solution prior to disposal. Be sure to properly
dispose any biological samples according to your institutional guidelines.
Module I - 50 min.
Isolation of DNA from
Cheek Cells or Human Hair
Module II - 70 min.
Amplification of extracted
DNA by PCR
Module III - 50-70 min.
Separation of PCR Product
by Electrophoresis
Module IV - 5 min.
Staining Agarose
Gels
NOTE: Experimental times are
approximate.
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reserved.
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The Experiment
IMPORTANT
10
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Module I-A: Isolation of DNA from Human Cheek Cells
Preferred Method
1.5 ml
2.
1.
4. SPIN
3.
T.C.
T.C.
60
T.C.
Full speed
2 min.
The Experiment
sec.
5.
Swirl
7.
6.
55° C
Vortex
or Flick
8.
99° C
15
15
140 µl
Lysis
Buffer
min.
min.
99
99
Warning!
Students should
use screw-cap
tubes when
boiling samples.
Vigorously 20 sec.
© 2013 Edvotek® All Rights Reserved.
9.
SPIN
10.
80 µl
Supernatant
Low speed
2 min.
1.
2.
LABEL a 1.5 ml screw top microcentrifuge tube and a cup with your lab group and/or initials.
RINSE your mouth vigorously for 60 seconds using 10 ml saline solution. EXPEL
the solution into cup.
STEP 4:
3. SWIRL the cup gently to resuspend the cells. TRANSFER 1.5 ml of solution into
If cell pellet size is not
the labeled tube.
large enough, repeat
steps 3 - 4 until you
4. CENTRIFUGE the cell suspension for 2 min. at full speed to pellet the cells.
have a large size
POUR off the supernatant, but DO NOT DISTURB THE CELL PELLET! Repeat
pellet. For best results,
steps 3 and 4 twice more.
make sure your cell
5. RESUSPEND the cheek cells in 140 µl lysis buffer by pipetting up and down or
pellet is at least the
size of a match head.
by vortexing vigorously.
6. CAP the tube and PLACE in a waterbath float. INCUBATE the sample in a 55° C
waterbath for 15 min.
STEP 7: If a vortex
7. MIX the sample by vortexing or flicking the tube vigorously for 20 seconds.
is not available, mix
samples by flicking the
8. INCUBATE the sample in a 99° C waterbath for 15 min. Be sure to use screwtube vigorously for 20
cap tubes when boiling DNA isolation samples.
seconds.
9. CENTRIFUGE the cellular lysate for 2 minutes at low speed (6000 rpm).
10. TRANSFER 80 µl of the supernatant to a clean, labeled microcentrifuge tube.
PLACE tube in ice.
11. PROCEED to Module II: Amplification of the D1S80 Locus.
OPTIONAL STOPPING POINT:
The extracted DNA may be stored at -20°C for amplification at a later time.
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reserved.
334.130821
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
11
334
Module I-B: Isolation of DNA from Human Hair
1.
3.
2.
T.C.
4.
SPIN
5.
Tweeze
55° C
Vortex
or Flick
7.
8. SPIN
9.
55° C
15
15
min.
99
10.
99° C
Vigorously 20 sec.
Full speed
10 sec.
Vortex
or Flick
12. SPIN
11.
10
For best results, harvest
hairs from the scalp. The
root structure from these
hairs will be thicker and
will yield more DNA than
those from the eyebrow.
13.
80 µl
Supernatant
min.
99
min.
99
IMPORTANT:
Vigorously 20 sec.
Shaft
HUMAN
HAIR
Sheath
Low speed
2 min.
Root
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
LABEL a 1.5 ml screw top microcentrifuge tube with your lab group and/or initials.
Using tweezers, GRASP 2-3 hair shafts at the base and PULL quickly. COLLECT at
STEPS 7 & 11
least 5 hairs that include the root and the sheath (a sticky barrel-shaped layer of
If a vortex is not
cells that encircles the root end of the hair).
available, mix
Using a clean scalpel or scissors, TRIM away any extra hair from the root (leave
samples by flicking
about 1 cm in length from the root). TRANSFER the roots to the labeled tube using
the tube vigorously
for 20 seconds.
forceps.
CAP the tube and CENTRIFUGE the sample for 10 seconds at full speed to collect the
roots at the bottom of the tube.
ADD 140 µL lysis buffer to the tube. For best results, completely IMMERSE the follicles in the solution.
CAP the tube and PLACE it in a waterbath float. INCUBATE the sample in a 55° C waterbath for 15 min.
MIX the sample by vortexing or flicking the tube vigorously for 20 seconds.
CENTRIFUGE the sample for 10 seconds at full speed to collect the roots at the bottom of the tube.
INCUBATE the sample at 55° C for an additional 15 min.
MOVE the sample to a 99° C waterbath. INCUBATE for 10 min. Be sure to use screw-cap tubes when
boiling samples.
MIX the sample by vortexing or flicking the tube vigorously for 20 seconds.
CENTRIFUGE the cellular lysate for 2 min. at low speed (6000 rpm).
TRANSFER 80 µl of the supernatant to a clean, labeled microcentrifuge tube. PLACE tube in ice.
PROCEED to Module II: Amplification of the D1S80 Locus.
OPTIONAL STOPPING POINT:
The supernatant may be stored at -20°C for amplification at a later time.
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reserved.
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The Experiment
6.
140 µl
Lysis
Buffer
Full speed
10 sec.
Trim
Warning!
Students should
use screw-cap
tubes when boiling
samples.
12
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Module II: Amplification of the D1S80 Locus
2.
The Experiment
1.
• 20 µl D1S80 primer
• 5 µl extracted DNA
• PCR EdvoBead
4.
1.
2.
3.
4.
Gently mix
3.
SPIN
NOTES AND REMINDERS:
This kit includes enough DNA to
set up 3-4 control reactions. At
least one control reaction should
be performed per class to confirm
that PCR was successful.
#1
5.
If your thermal cycler does not
have a heated lid, it is necessary
to overlay the PCR reaction with
wax to prevent evaporation. See
Appendix B for guidelines.
ADD 20 µL D1S80 primer mix, 5 µL extracted DNA (or control DNA) and one PCR EdvoBead to
a labeled 0.2 ml or 0.5 ml PCR tube (depending on the Thermal Cycler).
MIX the PCR sample. Make sure the PCR EdvoBead is completely dissolved.
CENTRIFUGE to collect the sample at the bottom of the tube.
AMPLIFY DNA using PCR:
PCR cycling conditions:
Initial denaturation 94°C for 4 minutes
94°C for 30 seconds
65°C for 30 seconds
35 cycles
72°C for 30 seconds
Final Extension 72°C for 4 minutes
5.
ADD 5 µL 10x gel loading solution to each tube. PROCEED to Module III: Electrophoresis of
PCR product.
OPTIONAL STOPPING POINT
The PCR samples may be stored at -20°C for electrophoresis at a later time.
Duplication of any part of this document is permitted for non-profit educational purposes only. Copyright © 2000-2013 EDVOTEK, Inc., all rights
reserved.
334.130821
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
13
334
Module III: Separation of PCR Reaction Products by Electrophoresis
1.
50
2.
3.
x
Concentrated
buffer
Distilled
water
1:00
Wear gloves
and safety goggles
Agarose
Flask
Caution! Flask will be HOT!
5.
7 x 14 cm gels are recommended. Each gel can
be shared by 4 students.
Place well-former template
(comb) in the first set of
notches.
60°C
6.
WAIT
Pour
60°C
1.
2.
3.
4.
5.
6.
If you are unfamiliar with
agarose gel prep and
electrophoresis, detailed
instructions and helpful
resources are available at
www.edvotek.com
7.
20
min.
DILUTE concentrated (50X) buffer with distilled water to create 1X buffer (see Table A).
MIX agarose powder with 1X buffer in a 250 ml flask (see Table B, page 14).
DISSOLVE agarose powder by boiling the solution. MICROWAVE the solution on high for
1 minute. Carefully REMOVE the flask from the microwave and MIX by swirling the flask.
Continue to HEAT the solution in 15-second bursts until the agarose is completely dissolved (the solution should be clear like water).
COOL agarose to 60° C with careful swirling to promote even dissipation of heat.
While agarose is cooling, SEAL the ends of the gel-casting tray with the rubber end caps.
PLACE the well template (comb) in the appropriate notch.
POUR the cooled agarose solution into the prepared
Table
gel-casting tray. The gel should thoroughly solidify
1x Electrophoresis Buffer (Chamber Buffer)
within 20 minutes. The gel will stiffen and become
Dilution
less transparent as it solidifies.
Total Volume
EDVOTEK
Distilled
50x Conc.
Required
Model #
+ Water
REMOVE end caps and comb. Take particular care
Buffer
when removing the comb to prevent damage to the
6 ml
294 ml
300 ml
M6+
wells.
A
7.
M12
400 ml
8 ml
392 ml
M36
1000 ml
20 ml
980 ml
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reserved.
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The Experiment
NOTES:
4.
14
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Module III: Separation of PCR Reaction Products by Electrophoresis
8.
Reminder:
9.
Before loading the samples,
make sure the gel is properly
oriented in the apparatus
chamber.
Pour
The Experiment
1X Diluted
Buffer
11.
10.
Wear gloves
and safety goggles
8.
PLACE gel (on the tray) into electrophoresis chamber. COVER the gel with 1X electrophoresis buffer
(See Table B for recommended volumes). The gel should be completely submerged.
9. LOAD the entire sample (30 µL) into the well. RECORD the position of the samples in Table 1, below.
10. PLACE safety cover. CHECK that the gel is properly oriented. Remember, the DNA samples will migrate toward the positive (red) electrode.
11. CONNECT leads to the power source and PERFORM electrophoresis (See Table C for time and voltage
guidelines).
12. After electrophoresis is complete, REMOVE
the gel and casting tray from the electroTable
phoresis chamber and proceed to STAINING
Individual 1.5% UltraSpec-Agarose™ Gel
the agarose gel.
B
Table 1
Lane
Recommended
Size of Gel
Casting tray
Concentrated
Buffer (50x)
7 x 7 cm
0.5 ml
24.5 ml
0.38 g
25 ml
7 x 14 cm
1.0 ml
49.0 ml
0.75 g
50 ml
+
Distilled
Water
+
Amt of
Agarose
=
TOTAL
Volume
Sample Name
1
200 bp ladder
Table
2
Control DNA*
C
3
Student #1
4
Student #2
5
Student #3
6
Student #4
Time and Voltage Guidelines
(1.5% - 7 x 14 cm Agarose Gel)
Recommended Time
Minimum
Maximum
125
55 min.
1 hour 15 min.
70
2 hours 15 min.
3 hours
50
3 hours 25 min.
5 hours
Volts
* Optional, or additional student sample.
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
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334
Module IV-A: Staining Agarose Gels using InstaStain® Ethidium Bromide
Preferred Method
1.
2.
3.
Moisten
the gel
id
e
.
U.S
5.
d in
Pen
ent
Pat
g
6.
-
InstaStain®
m
Bro
STAIN
300 nm
5
min.
Ethid
nt Pending
U.S. Pate
m
InstaStain® Ethidiu
Bromide
U.S. Patent
Pending
WEAR GLOVES AND GOGGLES WHEN USING THIS PRODUCT.
1.
Carefully REMOVE the agarose gel and casting tray from the electrophoresis chamber. SLIDE the gel
off of the casting tray on to a piece of plastic wrap on a flat surface.
DO NOT STAIN GELS IN THE ELECTROPHORESIS APPARATUS.
2.
MOISTEN the gel with a few drops of electrophoresis buffer.
3.
Wearing gloves, REMOVE and DISCARD the clear plastic protective sheet from the unprinted side of
the InstaStain® card(s). PLACE the unprinted side of the InstaStain® Ethidium Bromide card(s) on the
gel. You will need 2 cards to stain a 7 x 14 cm gel.
4.
With a gloved hand, REMOVE air bubbles between the card and the gel by firmly running your fingers
over the entire surface. Otherwise, those regions will not stain.
5.
PLACE the casting tray on top of the gel/card stack. PLACE a small weight (i.e. an empty glass beaker)
on top of the casting tray. This ensures that the InstaStain® Ethidium Bromide card is in direct contact
with the gel surface. STAIN the gel for 3-5 min. for an 0.8% gel or 8-10 min. for a gel 1.0% or greater.
6.
REMOVE the InstaStain® Ethidium Bromide card(s). VISUALIZE the gel using a long wavelength ultraviolet transilluminator (300 nm). DNA should appear as bright orange bands on a dark background.
BE SURE TO WEAR UV-PROTECTIVE EYEWEAR!
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The Experiment
4.
m
idiu
Eth
in®
Sta
sta
In
16
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Module IV-B: Staining Agarose Gels using FlashBlue™
1.
2.
10
x
Concentrated
FlashBlue™ Stain
Wear gloves
and safety goggles
Distilled
water
The Experiment
Flask
3.
5.
4.
STAIN
Pour
5
min.
(-)
1
2
3
4
5
6
DESTAIN
Pour
20
min.
(+)
1.
DILUTE 10 ml of 10x concentrated FlashBlue™ with 90 mL of water in a flask and MIX well.
2.
REMOVE the agarose gel and casting tray from the electrophoresis chamber. SLIDE the gel off of the
casting tray into a small, clean gel-staining tray.
3.
COVER the gel with the 1x FlashBlue™ stain solution. STAIN the gel for 5 minutes. For best results, use
an orbital shaker to gently agitate the gel while staining. STAINING THE GEL FOR LONGER THAN 5
MINUTES WILL REQUIRE EXTRA DESTAINING TIME.
4.
TRANSFER the gel to a second small tray. COVER the gel with water. DESTAIN for at least 20 minutes
with gentle shaking (longer periods will yield better results). Frequent changes of the water will accelerate destaining.
5.
REMOVE the gel from the destaining liquid. VISUALIZE results using a white light visualization system.
DNA will appear as dark blue bands on a light blue background.
Alternate Protocol:
1.
2.
3.
DILUTE one mL of concentrated FlashBlue™ stain with 149 mL dH2O.
COVER the gel with diluted FlashBlue™ stain.
SOAK the gel in the staining liquid for at least three hours. For best results, stain gels overnight.
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VNTR Human DNA Typing Using PCR
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334
Study Questions
Answer the following study questions in your laboratory notebook or on a
separate worksheet.
Compare your D1S80 PCR product with those of the rest of the class.
Did any students have genotypes similar to yours? How could you
explain such similarities?
2.
What is polymorphic DNA? How is it used for identification purposes?
3.
What is CODIS? How is it used to solve crimes?
4.
What is the difference between a STR and a VNTR? Which (STR or
VNTR) is predominantly used in law enforcement? Why?
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The Experiment
1.
18
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
xxx
Instructor’s Guide
OVERVIEW OF INSTRUCTOR’S PRELAB PREPARATION:
This section outlines the recommended prelab preparations and approximate
time requirement to complete each prelab activity.
Preparation For:
Module I:
Isolation of DNA
from Hair or
Cheek Cells
Module II:
Amplification of
Extracted DNA
What to do:
When:
Time Required:
Prepare and aliquot
various reagents
(Saline, Lysis buffer)
Up to one day before performing the
experiment. IMPORTANT: Prepare the Lysis
buffer no more than one hour before
performing the experiment.
30 min.
Equilibrate waterbaths
at 55 ° C and boiling.
One hour before performing
the experiment.
5 min.
Prepare and aliquot various
reagents (Primer, DNA
template, ladder, etc.)
One day to 30 min. before performing
the experiment.
30 min.
Program Thermal Cycler
One hour before performing
the experiment.
15 min.
Up to one day before performing
the experiment.
45 min.
The class period or overnight after the
class period.
10 min.
Module III:
Separation of PCR
Product by
Electrophoresis
Prepare diluted TAE buffer
Module IV:
Staining
Prepare staining
components
Prepare molten agarose
and pour gel
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EDVO-Kit #
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334
Pre-Lab Preparations: Module I
MODULE I-A: ISOLATION OF DNA FROM HUMAN CHEEK CELLS
Reagents to be Shared by
Two Students:
• 300 µl Lysis buffer
• 15% bleach solution
Warning !!
Remind students to only use
screw-cap tubes when boiling
their DNA samples. The snap-top
tubes can potentially pop open
and cause injury.
Preparation of Saline Solution
1.
To prepare the saline solution, dissolve all 8 salt packets in 500 ml of
drinking water. Cap and invert bottle to mix.
2.
Aliquot 10 ml of saline solution per cup. Distribute one cup per student.
Preparation of Lysis Buffer
(Prepared no more than one hour before starting the experiment.)
1.
Add 100 µl of TE buffer (E) to the tube of Proteinase K (F) and allow the
sample to hydrate for several minutes. After the sample is hydrated,
pipet up and down several times to thoroughly mix the material.
2.
Transfer the entire amount of the rehydrated Proteinase K solution to a
15 ml conical tube containing an additional 4 ml of TE buffer (E).
3.
Invert the tube several times to mix. Label this tube “Lysis Buffer”.
4.
Aliquot 300 µl of Lysis Buffer into 13 labeled microcentrifuge tubes.
5.
Distribute one tube of “Lysis Buffer” to each student pair.
MODULE I-B: ISOLATION OF DNA FROM HUMAN HAIR
Preparation of Lysis Buffer
FOR MODULE I-B
Each Student should receive:
• One screw-cap tube
• One microcentrifuge tube
Reagents to be Shared by
Two Students:
• 300 µl Lysis buffer
(Prepared no more than one hour before starting the experiment)
1.
Add 100 µl of TE buffer (E) to the tube of Proteinase K (F) and allow the
sample to hydrate for several minutes. After the sample is hydrated,
pipet up and down several times to thoroughly mix the material.
2.
Transfer the entire amount of the rehydrated Proteinase K solution to a
15 ml conical tube containing an additional 4 ml of TE buffer (E).
3.
Invert the tube several times to mix. Label this tube “Lysis Buffer”.
4.
Aliquot 300 µl of Lysis Buffer into 13 labeled microcentrifuge tubes.
5.
Distribute one tube of “Lysis Buffer” to each student pair.
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The Experiment
FOR MODULE I-A
Each Student should receive:
• One cup containing 10 ml of
saline solution
• One screw-cap tube
• One microcentrifuge tube
20
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Pre-Lab Preparations - Module II: Amplification of the Extracted DNA
Instructor’s Guide
Preparation of the D1S80 Primer
FOR MODULE II
Each Student should receive:
• One PCR tube and PCR
EdvoBead™
• 20 µl Gel Loading Solution
Reagents to be Shared by
Two Students:
• 50 µl D1S80 Primer Solution
1.
Thaw the D1S80 Primer Mix Concentrate (B) on ice.
2.
Add 1 ml of TE Buffer (E) to the tube of Primer Mix Concentrate (B). Cap
tube and mix.
3.
Aliquot 50 µl of the diluted Primer Mix into 13 labeled microcentrifuge
tubes.
4.
Distribute one tube of diluted D1S80 Primer to each student pair.
Preparation of the Control DNA
1.
This kit includes enough DNA to set up 4 control reactions. At least one
control reaction should be performed per class to confirm that PCR was
successful.
2.
Thaw the tube of Control DNA Concentrate (D) on ice.
3.
Add 20 µl of TE buffer (E) to the tube containing Control DNA Concentrate. Pipet up and down to mix.
4.
Dispense 8 µl of the diluted control DNA for each control reaction.
Additional Materials
•
Dispense 20 µl of 10x Gel Loading Solution to each student pair.
Programming the Thermal Cycler
The Thermal cycler should be programmed as outlined in Module II in the
Student’s Experimental Procedure.
•
Accurate temperatures and cycle times are critical. A pre-run for one
cycle (takes approximately 3 to 5 min.) is recommended to check that
the thermal cycler is properly programmed.
•
For thermal cyclers that do not have a heated lid, it is necessary to place
a layer of wax above the PCR reactions in the microcentrifuge tubes to
prevent evaporation. See Appendix B for instructions.
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VNTR Human DNA Typing Using PCR
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Pre-Lab Preparations - Module III: Separation of PCR Product by Electrophoresis
If students are unfamiliar with
using micropipets, we recommended performing Cat. #S-44,
Micropipetting Basics or Cat.
#S-43, DNA DuraGel™ prior to
conducting this advanced level
experiment.
PREPARATION OF AGAROSE GELS
This experiment requires one 1.5% agarose gel per student group.
A 7 x 14 cm gel is recommended. You can choose whether to prepare the gels in advance or have the students prepare their own.
Allow approximately 30-40 minutes for this procedure.
Individual Gel Preparation:
Each student group can be responsible for casting their own
individual gel prior to conducting the experiment. See Module III
in the Student’s Experimental Procedure. Students will need 50x
concentrated buffer, distilled water and agarose powder.
Batch Gel Preparation:
To save time, a larger quantity of agarose solution can be prepared for sharing by the class. See Appendix C.
Preparing Gels in Advance:
FOR MODULE III
Each Student Group
should receive:
• 50x concentrated buffer
• Distilled Water
• UltraSpec-Agarose™ Powder
• Tube of 200 bp ladder (30 µl)
• Control PCR reaction (optional)
Gels may be prepared ahead and stored for later use. Solidified
gels can be store under buffer in the refrigerator for up to 2
weeks.
Do not freeze gels at -20ºC as freezing will destroy the gels.
Gels that have been removed from their trays for storage should
be “anchored” back to the tray with a few drops of molten agarose before being placed into the tray. This will prevent the gels
from sliding around in the trays and the chambers.
Additional Materials:
Each 1.5% gel should be loaded with the 200 base pair ladder and
samples from 4 or 5 students. The control PCR reaction can also be
loaded in one of the wells.
•
Aliquot 30 µl of the 200 base-pair ladder (C) into labeled microcentrifuge tubes and distribute one tube of ladder per gel.
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Instructor’s Guide
NOTE:
Accurate pipetting is critical for
maximizing successful experiment results. EDVOTEK Series 300
experiments are designed for
students who have had previous
experience with micropipetting
techniques and agarose gel
electrophoresis.
22
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Instructor’s Guide
Pre-Lab Preparations - Module IV: Staining
FOR MODULE IV
Each Student Group
should receive:
• 2 InstaStain® cards per
7 x 14 cm gel
Wear gloves
and safety goggles
STAINING WITH INSTASTAIN® ETHIDIUM
BROMIDE
Preferred Method
InstaStain® Ethidium Bromide provides the sensitivity of ethidium bromide
while minimizing the volume of liquid waste generated by staining and
destaining a gel. An agarose gel stained with InstaStain® Ethidium Bromide
is ready for visualization in as little as 3 minutes! Each InstaStain® card will
stain 49 cm2 of gel (7 x 7 cm). You will need 2 cards to stain a 7 x 14 cm gel.
Use a mid-range ultraviolet transilluminator (Cat. #558) to visualize gels stained with
InstaStain® Ethidium Bromide. BE SURE TO WEAR UV-PROTECTIVE EYEWEAR!
•
Standard DNA markers should be visible after staining even if other DNA samples
are faint or absent. If bands appear faint, repeat staining with a fresh InstaStain
card for an additional 3-5 min. If markers are not visible, troubleshoot for problems
with electrophoretic separation.
•
Ethidium bromide is a listed mutagen. Wear gloves and protective eyewear when
using this product. UV protective eyewear is required for visualization with a UV
transilluminator.
•
InstaStain® Ethidium Bromide cards and stained gels should be discarded using
institutional guidelines for solid chemical waste.
STAINING WITH FLASHBLUE™
FlashBlue™ can be used as an alternative to Ethidium Bromide in this experiment.
However, FlashBlue™ is less sensitive than InstaStain® Ethidium Bromide and will take a
longer time to obtain results.
FlashBlue™ stain, however, is optimized to shorten the time required for both staining
and destaining steps. Agarose gels can be stained with diluted FlashBlue™ for 5 minutes
and destained for only 20 minutes. For the best results, leave the gel in liquid overnight.
This will allow the stained gel to “equilibrate” in the destaining solution, resulting in
dark blue DNA bands contrasting against a uniformly light blue background. A white
light box (Cat. #552) is recommended for visualizing gels stained with FlashBlue™.
•
Stained gels may be stored in destaining liquid for several weeks with refrigeration,
although the bands may fade with time. If this happens, re-stain the gel.
•
Destained gels can be discarded in solid waste disposal. Destaining solutions can be
disposed of down the drain.
PHOTODOCUMENTATION OF DNA (OPTIONAL)
Once gels are stained, you may wish to photograph your results. There are many different photodocumentation systems available, including digital systems that are interfaced
directly with computers. Specific instructions will vary depending upon the type of photodocumentation system you are using.
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VNTR Human DNA Typing Using PCR
EDVO-Kit #
23
334
Experiment Results and Analysis
Student #5
Student #4
Student #3
Student #2
Student #1
200 base
pair ladder
Student #5
Student #4
Student #2
Student #3
Student #1
200 base
pair ladder
Instructor’s Guide
1200 bp
1000 bp
800 bp
600 bp
400 bp
200 bp
1200bp
1000bp
800bp
600bp
Short gel
400bp
200bp
Idealized Schematics
Long Gel
The idealized schematics show a
few of the possible PCR products
from different genotypes.
Students' PCR products should show
one or two bands with lengths between 360 and 800 base pairs.
Note:
Depending on the PCR conditions used, a
diffuse, small-molecular weight band, known
as a "primer dimer", may be present below
the 200 bp marker. This is a PCR artifact and
can be ignored. Other minor bands may also
appear due to nonspecific primer binding
and the subsequent amplification of these
sequences.
Photo of
Gel Results
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Please refer to the kit
insert for the Answers to
Study Questions
VNTR Human DNA Typing Using PCR
EDVO-Kit #
334
Appendices
A
EDVOTEK® Troubleshooting Guide
B
Preparation and Handling of PCR Samples With Wax
C
Bulk Preparation of Agarose Gels
Material Safety Data Sheets:
Now available for your convenient download on www.edvotek.com.
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1-800-EDVOTEK • www.edvotek.com
FAX: 202-370-1501 • email: info@edvotek.com
334.130821
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26
Appendix A
EDVO-Kit #
334
EDVOTEK® Troubleshooting Guides
DNA EXTRACTION
PROBLEM:
There is no cell pellet
after centrifuging the
cheek cell suspension.
I was not able to extract
DNA from hair.
Poor DNA Extraction
The extracted DNA is
very cloudy.
CAUSE:
ANSWER:
Not enough cheek cells in suspension
Mouth must be vigorously rinsed for at least 60 sec.
to harvest loose cheek cells.
Sample not centrifuged fast enough
Spin cells at maximum speed (17,000 x g) for 2 min.
If your centrifuge does not reach this speed, spin at
highest available speed for 4 min.
Not enough hairs used for extraction
Use at least five hairs for the DNA extraction.
No follicle was present on hair shaft
The best place to collect hairs for this experiment is
the head. Pick hair follicles which have a bulbous
base (sheath cells).
Samples not mixed well enough during
extraction
In addition to flicking the tube, vortex or pipet up and
down to mix the sample.
Proteinase K inactive because it was
prepared too far in advance.
Prepare Proteinase K within one hour of use.
Water baths not at proper temperature
Use a thermometer to confirm water bath set point.
Not enough DNA
Try cheek cell extraction. Final DNA concentrations
are usually higher.
Cellular debris from pellet transferred to
tube
Centrifuge sample again and move supernatant to a
fresh tube. Take care to avoid pellet.
Cellular debris not separated from
supernatant
Centrifuge sample again. If possible, centrifuge at a
higher speed. Move cleared supernatant to a fresh
tube.
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Appendix A
27
EDVO-Kit #
334
PCR AND ELECTROPHORESIS
PROBLEM:
CAUSE:
ANSWER:
Make sure the heated lid reaches the appropriate temperature.
There is very little liquid
left in tube after PCR
Sample has evaporated
If your thermal cycler does not have a heated lid, overlay the
PCR reaction with wax (see Appendix B for details)
Make sure students close the lid of the PCR tube properly.
Pipetting error
Make sure students pipet 20 µL primer mix and 5 µL extracted
DNA into the 0.2 mL tube.
Ensure that the electrophoresis buffer was correctly diluted.
The gel was not prepared properly.
Gels of higher concentration (> 0.8%) require special attention
when melting the agarose. Make sure that the solution is
completely clear of “clumps” and glassy granules before
pouring gels.
The gel was not stained properly.
Repeat staining.
Malfunctioning electrophoresis unit or
power source.
Contact the manufacturer of the electrophoresis unit
or power source.
The gel was not stained for a sufficient
period of time.
Repeat staining protocol.
The ladder, control DNA,
and student PCR products
are not visible on the gel.
After staining the gel,
the DNA bands are faint.
After staining, the ladder
is visible but no PCR
products are present.
Repeat PCR with fresh PCR EdvoBeads™ and primers.
PCR amplification was unsuccessful.
Ensure that the thermal cycler has been properly
programmed. See Module II for guidelines
Student DNA sample was not concentrated
enough.
Poor DNA extraction. Extract new DNA. Cheek cell
extraction usually results in higher DNA yield.
Student DNA sample was degraded
If DNA is not used immediately following extraction, store
sample at -20°C.
Wrong volumes of DNA and primer added
to PCR reaction
Practice using pipettes
Some students have more
or less amplification than
others.
Concentration of DNA varies by sample.
There is an inherent variability in the extraction
process. For best results, use cheek cell extraction.
Low molecular weight
band in PCR samples
Primer dimer
Low concentration of extracted DNA in PCR reaction.
DNA bands were not
resolved.
Tracking dye should migrate at least 3.5 cm
(if using a 7x7 cm tray), and at least 6 cm
(if using a 7x14 cm tray) from the wells to
ensure adequate separation.
Be sure to run the gel at least 6 cm before staining
and visualizing the DNA (approximately one hour at
125 V).
DNA bands fade when
gels are kept at 4°C.
DNA stained with FlashBlue™ may
fade with time
Re-stain the gel with FlashBlue™
After staining, the ladder
and control PCR products
are visible on gel, but
some student samples
are not present.
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28
Appendix B
EDVO-Kit #
334
Preparation and Handling of PCR Samples With Wax
ONLY For Thermal Cyclers WITHOUT Heated Lids, or Manual PCR Using Three Waterbaths
Using a wax overlay on reaction components prevents evaporation during the
PCR process.
HOW TO PREPARE A WAX OVERLAY
1.
Add PCR components to the 0.2 ml PCR Tube as outlined in Module II.
2.
Centrifuge at full speed for five seconds to collect sample at bottom of the
tube.
3.
Using clean forceps, add one wax bead to the PCR tube.
4.
Place samples in PCR machine and proceed with Module II.
PREPARING PCR SAMPLES FOR ELECTROPHORESIS
1.
After PCR is completed, melt the wax overlay by heating the sample at 94° C
for three minutes or until the wax melts.
2.
Using a clean pipette, remove as much overlay wax as possible.
3.
Allow the remaining wax to solidify.
4.
Use a pipette tip to puncture the thin layer of remaining wax. Using a fresh
pipette tip, remove the PCR product and transfer to a new tube.
5.
Add 5 µL of 10x Gel Loading Buffer to the sample. Proceed to Module III to
perform electrophoresis.
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29
Appendix C
EDVO-Kit #
334
Bulk Preparation of Agarose Gels
To save time, electrophoresis buffer and agarose gel solution can be prepared in larger quantities for sharing
by the class. Unused diluted buffer can be used at a later time and solidified agarose gel can be remelted.
BULK ELECTROPHORESIS BUFFER
Bulk preparation of 1X electrophoresis buffer is
outlined in Table D.
BATCH AGAROSE GELS (1.5%)
Table
D
Bulk Preparation of Electrophoresis Buffer
50x Conc.
Buffer
Distilled
Water
Total Volume
Required
2,940 ml
3000 ml (3 L)
+
60 ml
Bulk preparation of 1.5% agarose gel is outlined in Table E.
Note:
The UltraSpec-Agarose™ kit
component is usually labeled
with the amount it contains.
Please read the label carefully.
If the amount of agarose is not
specified or if the bottle's plastic
seal has been broken, weigh the
agarose to ensure you are using
the correct amount.
1.
Use a 500 ml flask to prepare the diluted gel buffer
2.
Pour the appropriate amount of UltraSpec-Agarose™ into the prepared buffer.
Swirl to disperse clumps.
3.
With a marking pen, indicate the level of solution volume on the outside of the
flask.
4.
Heat the agarose solution as outlined previously for individual gel preparation.
The heating time will require adjustment due to the larger total volume of gel
buffer solution.
5.
Cool the agarose solution to 60°C with swirling to promote even dissipation of heat. If evaporation
has occurred, add distilled water to bring the solution up to the original volume as marked on the
flask in step 3.
6.
Dispense the required volume of cooled agarose solution for casting each gel. The volume required
is dependent upon the size of the gel bed.
7.
Allow the gel to completely solidify. It will become firm and cool to the touch after approximately
20 minutes. Proceed with electrophoresis (Module II) or store the gels at 4º C under buffer.
Table
Batch Preparation of
1.5% UltraSpec-Agarose™
E
Amt of
Agarose
60˚C
+
50x Conc.
Buffer
+
Distilled
Water
=
Diluted
Buffer (1x)
4.5 g
6.0 ml
294 ml
300 ml
6.0 g
8.0 ml
392 ml
400 ml
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