DNA Lab Helps Identify Troop Remains
By Fred W. Baker III
American Forces Press Service
WASHINGTON, Sept. 30, 2008 – Thumb-tacked
to the inside of Jennifer O’Callaghan’s office cubicle is a picture of
Marine Capt. William Francis Mullen.
On her desk is a red metal bracelet engraved with his name, and the date the fighter pilot went missing.
Mitochondrial
DNA analysts Christina Miller, right, Jamie Steinitz, center, and
Jennifer Kappeller work to prepare bone and tooth samples for DNA
extraction. The DNA lab is one of the oldest and largest labs in the
world that works with ancient DNA testing, or testing from severely
degraded samples. DoD photo by Fred W. Baker III
(Click photo for screen-resolution image);high-resolution image available.
Mullen
presumably was shot down during a combat mission in Laos in 1966. His
body was never found, but O’Callaghan hopes to change that.
“Hopefully, one day, we will find him, too,” she said.
O’Callaghan
works as a mitochondrial DNA analyst at the Armed Forces DNA
Identification Laboratory in Rockville, Md. She is not connected to
Mullen in any way other than by the passion that drives her and the
others at the lab to painstakingly work through extracting and
sequencing the mitochondrial DNA of 800 bone and tooth samples each
year provided by the Joint POW/MIA Accounting Command, or JPAC.
DNA
testing, once deemed unreliable by the scientific community, has
developed to become a key piece of evidence in nearly 85 percent of all
missing troop identifications, DoD officials said.
“Once people
realized the value of the DNA for forensic examinations and
identifications of degraded or unrecognizable remains, it solidified
DNA’s role in human identification,” said Army Lt. Col. Louis Finelli,
chief deputy medical examiner and director of the DoD DNA registry.
Five
teams of technicians, analysts and supervisors work on the cases that
are flown in from the JPAC, which is based in Hawaii. The JPAC is one
of a handful of DoD agencies charged with recovering and identifying
missing servicemembers from past wars. Its Central Identification Lab
sends the bone and tooth samples to the DNA lab even as its forensic
anthropologists work to identify the remains of recovered
servicemembers using other means, such as dental and personnel records,
personal items and historical accounts.
The DNA lab has two main
missions. One is to provide DNA testing on the remains of current
servicemembers who die, and the other is to provide DNA testing on the
remains of servicemembers who have been recovered from past wars. In
the latter respect, the DNA lab is one of the oldest and largest labs
in the world that works with what’s known as “ancient DNA testing,” or
testing from severely degraded samples. It also is the world’s leader
in working with mitochondrial DNA, officials said.
Nuclear DNA
testing is most commonly used now in forensic labs around the world to
pinpoint a specific identity. But the drawback is that it can be used
mostly only on high-quality samples, and other appropriate DNA
references by which to confirm the identity are necessary, such as
samples from immediate kin or a blood reference sample.
Mitochondrial
DNA, or mtDNA, on the other hand, points only to maternal lineage, but
it is easier to extract from severely degraded bone and tooth samples,
and reference samples can be from any maternal relative, regardless of
the generation. This is especially helpful for identifying
servicemembers’ remains from past wars, because some remains are
decades old and many immediate family members of the servicemembers
have since died.
The development of using mtDNA testing to aid
identification of servicemembers has led to a boom in business for the
lab. It has shot up from testing only about 200 samples a year in 1995
to having plans to test as many as 1,000 a year by 2010. Also, since
the early 1990s, the lab has processed 12,000 DNA reference samples
from family members. Their sample results are entered into a database
that is referenced against the missing servicemembers’ DNA test results.
Finelli said the mission of the lab speaks to DoD’s efforts to recover its missing servicemembers.
“I think we’re unrivaled in that capacity in the world,” Finelli said.
The
sampling process can take months, or sometimes years, depending on the
quality of the sample. The scientists there work in the “blind,” not
knowing many of the particulars surrounding the cases of those they are
testing. Bone and tooth samples are sent to the lab in a small
cardboard envelope sealed with evidence tape to protect them from
tampering. Inside is a letter with a case and sample number, the
conflict and region from which the sample is returned.
JPAC’s
recovery teams travel on about 70 missions a year to some of the most
remote locations around the world to recover the remains. The DNA lab
has received samples from drained rice paddies, termite mounds,
glaciers and the sides of mountains, said Jackie Raskin-Burns, a
supervisory DNA analyst at AFDIL. She said when remains arrive, the
scientists can’t help but wonder who they are and what their story was.
“Every
case is different, and every case is exciting,” Raskin-Burns said. She
has worked at the lab for 14 years, and said the cases become personal
for those who work on them. She keeps track of all cases she works on
and matches them with the DoD notifications released after the families
are notified.
“I still get goose bumps when a sequence matches a
reference,” she said. “I still get a little pit in my stomach when it
doesn’t, because you so want to help bring these guys home.”
The
samples provided are small -- typically only about 5 grams, weighing
less than one-half of an ounce. The surface of each sample is sanded
and cleaned to remove external contaminates. Technicians take about
half of the sample, about the size of a pea, and grind it into a fine
powder. Only about two-tenths of a gram of the powder is used for
sampling.
The samples are purified, and everything in the cell
is removed except for the pure mtDNA. The target area of the mtDNA is
then replicated within the sample to give the scientists a sufficient
number of copies to work with. Hundreds of thousands of copies of the
targeted mtDNA are made. When finished, the mtDNA is separated and
actually is visible on a gel when illuminated by an ultraviolet light.
Once
the scientists verify that mtDNA has been obtained and that the sample
is clean and accurate, it again is purified and then broken down into
its base pair components. Each of the components is fluorescently
tagged, allowing the analysts to record the exact order of the
components.
The order of these components -- the mitochondrial
DNA sequence -- is compared to a reference sequence. Each difference in
the sequence is noted, and those differences are compared to a database
of other reference sequences.
Mitochondrial DNA is not exclusive
to an individual, and some sequences are very common. Therefore, a
sequence match does not necessarily prove relationship, because others
can have the same sequence. But, if two sequences do not match, it does
prove they are not related maternally.
So, if anthropologists
recover remains from an airplane crash, they already think they know
who was on the plane. When tested, if the mtDNA sequence matches that
servicemember’s family reference sample, it is strong evidence that the
sample, indeed, came from the person they believed to be on the plane.
The test results are combined with other evidence gathered at the crash
site and by forensic anthropologists to make an identification.
On
the other hand, if the mtDNA sequence from the recovered remains does
not match that of a maternal relative of the servicemember thought to
be on the plane, the scientists can conclude that the remains are not
those they believed them to be.
Once the sequence comparisons
are made, a report is sent to the Central Identification Laboratory at
the JPAC. If needed, it will return the samples to have them compared
to relatives in the family reference sample database. The DNA lab does
not make any servicemember identifications. It simply renders a report
that indicates whether sample sequences are consistent with reference
samples, or that a relationship cannot be determined.
Much of
the work is done in test tubes in sterile labs by scientists clad in
white lab coats and goggles. Air locks and separate ventilation systems
keep stray DNA and other contaminants from ruining the tests. Despite
what could be a cold and impersonal scientific environment, many at the
lab say they feel personally connected to the mission and are
determined to help return the remains to their families.
“If a
case doesn’t look like it’s working, I’ll put that much more effort
into trying to get something out of it, because I know this is
somebody’s relative,” O’Callaghan said. “This is somebody’s brother.
This is somebody’s father. And I can be the one who can help bring him
home.”
O’Callaghan picked Mullen’s name and profile from the
Vietnam War Memorial when she started working at the lab. Her husband
is a former Marine who served in combat, and O’Callaghan said that as a
family member, she appreciates the lab’s mission.
“I would want
somebody to do this for me if something happened to him in Iraq,” she
said. “So I am very happy to do this for someone else.”
Raskin-Burns
has attended about a dozen presentations of servicemembers’ remains to
their families. She said the look on the family members’ faces has kept
her at the lab for 14 years.
“When you’re working so hard at one
thing for such a long time, to be rewarded by having this person go
home to their family, it’s very touching and becomes very personal,”
she said.
As a soldier, Finelli said that DoD’s efforts are well
spent, and even owed, to servicemembers’ families and to those who have
died in combat.
“The parents entrust their sons and daughters to
the government every day. It’s only right that we provide an answer
back to them should [their sons and daughters] pay the ultimate
sacrifice in the line of service to the country,” Finelli said. “Nobody
wants to be the lonely soldier out on the battlefield, not embraced by
their country, who they died for.”
Finelli said he expects that
the lab’s mission will continue to grow as research and technology
continue to break new ground in identifying servicemembers’ remains.
The lab now leads the way in mtDNA research for the rest of the world,
he said, noting that private organizations and other governments have
asked for help in many high-profile cases in the past decade. And DoD
is investigating expanding the use of DNA testing in the current war on
terror, Finelli said.
With the advances in technology and
science, Finelli said, he thinks the days of returning servicemembers’
remains to their families decades after they died on the battlefield
are over.
“There will never be an unknown soldier out there ever
again,” Finelli said. “The government has put their trust and funding
into making sure they can tell my parents who I am.”
Related Sites:
Armed Forces DNA Identification Lab
Joint POW/MIA Accounting Command
Special Report: Honoring the Pledge
Jackie
Raskin-Burns, a supervisory DNA analyst at the Armed Forces DNA
Identifications Lab in Rockville, Md., explains the mitochondrial DNA
extraction process. Mitochondrial DNA testing is used to help identify
the remains of servicemembers recovered from past wars. DoD photo by
Fred W. Baker III Download screen-resolution Download high-resolution |
Carla
Paintner, a supervisory DNA analyst at the Armed Forces DNA
Identifications Lab in Rockville, Md., holds a test tube of a finely
ground bone sample ready to begin the process of extracting the
mitochondrial DNA. The lab samples the mitochondrial DNA of 800 bone
and tooth samples a year provided by the Joint POW/MIA Accounting
Command. DoD photo by Fred W. Baker III Download screen-resolution Download high-resolution |
The
picture and profile of Marine Capt. William Francis Mullen is
thumb-tacked to the inside of Jennifer O’Callaghan’s office cubicle at
the Armed Forces DNA Identifications Lab in Rockville, Md. O’Callaghan
works as a mitochondrial DNA analyst at the lab and hopes that her work
will lead to the eventual identification of the missing fighter pilot’s
remains. Mullen presumably was shot down during a combat mission in
Laos in 1966. DoD photo by Fred W. Baker III Download screen-resolution Download high-resolution |
Jennifer
O’Callaghan, a mitochondrial DNA analyst at the Armed Forces DNA
Identifications Lab in Rockville, Md., explains sequencing and how it
compares to a reference sample. Mitochondrial DNA points only to
maternal lineage, but it is easier to extract from severely degraded
bone and tooth samples. DoD photo by Fred W. Baker III Download screen-resolution Download high-resolution |
Mitochondrial
DNA technicians Skip Graf and Allison Fain work in the amplification
lab at the Armed Forces DNA Identifications Lab in Rockville, Md. The
target area of mitochondrial DNA is replicated within the sample to
give the scientists sufficient copies to work with. DoD photo by Fred
W. Baker III Download screen-resolution Download high-resolution |
Mitochondrial
DNA analyst Christina Miller sands a bone sample to remove surface
contaminants before grinding it into a fine powder and extracting its
DNA. DNA testing has developed to become a key piece of evidence in
nearly 85 percent of all missing troop identifications. DoD photo by
Fred W. Baker III Download screen-resolution Download high-resolution |
Mitochondrial
DNA technician Timothy Herbert sets up samples for sequencing at the
Armed Forces DNA Identifications Lab in Rockville, Md. The order of the
mitochondrial DNA sequence is compared to a reference sequence. Each
difference in the sequence is noted and those differences are compared
to a database of other reference sequences. DoD photo by Fred W. Baker
III Download screen-resolution Download high-resolution |
An
ultraviolet light shows the amplified mitochondrial DNA on an agarous
gel held by technician Chris Johnson. Hundreds of thousands of copies
of the target DNA are replicated during the process. DoD photo by Fred
W. Baker III Download screen-resolution Download high-resolution |
Mitochondrial
DNA technician Brittany Box readies a sample to amplify its target DNA.
The target area is duplicated within the sample to give the scientists
sufficient copies to work with. DoD photo by Fred W. Baker III Download screen-resolution Download high-resolution |
Mitochondrial
DNA technician Brittany Box loads a plate of samples into a thermal
cycler that will replicate the target DNA. The development of using
mitochondrial DNA testing to aid identification of servicemembers has
increased in the lab from only about 200 samples a year in 1995 to 800
now. The lab plans to test as many as 1,000 a year by 2010. DoD photo
by Fred W. Baker III
Download screen-resolution Download high-resolution |