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Scientists explore humankind's past with mtDNA.
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Tracing Ancestry with MtDNA
by Rick Groleau
In 1987, three scientists announced in the journal Nature that they had
found a common ancestor to us all, a woman who lived in Africa 200,000 years
ago. She was given the name "Eve," which was great for capturing
attention, though somewhat misleading, as the name at once brought to mind
the biblical Eve, and with it the mistaken notion that the ancestor was the
first of our species—the woman from whom all humankind descended.
The "Eve" in question was actually the most recent common ancestor through
matrilineal descent of all humans living today. That is, all people alive today
can trace some of their genetic heritage through their mothers back to this one woman.
The scientists hypothesized this ancient woman's existence by looking within
the cells of living people and analyzing short loops of genetic code known as
mitochondrial DNA, or mtDNA for short. In recent years, scientists have used
mtDNA to trace the evolution and migration of human species, including when the
common ancestor to modern humans and Neanderthals lived—though there has
been considerable debate over the validity and value of the findings.
In reproduction, the nuclear DNA of one parent mixes with the nuclear DNA of
the other. MtDNA, on the other hand, passes on from mother to offspring
unaltered.
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Nuclear DNA vs mitochondrial DNA
When someone mentions human DNA, what do you think of? If you know a little
about the topic, perhaps you think of the 46 chromosomes that inhabit the
nucleus of almost every cell that comprises your body. These chromosomes hold
the vast bulk of genetic information that you've inherited from your parents.
Outside the nucleus, but still within the cell, lie mitochondria. Mitochondria
are tiny structures that help cells in a number of ways, including producing
the energy that cells need. Each mitochondrion—there are about 1,700 in
every human cell—includes an identical loop of DNA about 16,000 base pairs
long containing 37 genes. In contrast, nuclear DNA consists of three billion
base pairs and an estimated 70,000 genes. (This estimate has been revised upward several times
since the announcement that the human genome had been decoded, and likely
will be again.)
Inheriting mtDNA
Whenever an egg cell is fertilized, nuclear chromosomes from a sperm cell enter
the egg and combine with the egg's nuclear DNA, producing a mixture of both
parents' genetic code. The mtDNA from the sperm cell, however, is left behind,
outside of the egg cell.
So the fertilized egg contains a mixture of the father and mother's nuclear DNA
and an exact copy of the mother's mtDNA, but none of the father's mtDNA. The
result is that mtDNA is passed on only along the maternal line. This means that
all of the mtDNA in the cells of a person's body are copies of his or her
mother's mtDNA, and all of the mother's mtDNA is a copy of her mother's, and so
on. No matter how far back you go, mtDNA is always inherited only from the
mother.
If you went back six generations in your own family tree, you'd see that your
nuclear DNA is inherited from 32 men and 32 women[1]. Your mtDNA, on the other
hand, would have come from only one of those 32 women.
Defining mitochondrial ancestors
Let's get back to "Eve." The ancestor referred to in the 1987 Nature
article can be more precisely stated as "the most recent common ancestor
through matrilineal descent of all humans living today." In other words, she is
the most recent person from whom everyone now living on Earth has inherited his
or her mtDNA. This certainly does not mean that she is the ancestral mother of
all who came after her; during her time and even before her time there were
many women and men who contributed to the nuclear genes we now carry. (To see
how this can be, check out Tracing Ancestry.) It also does not
mean that the mtDNA originated with this "Eve"; she and her contemporaries also
had their own "most recent common ancestor though matrilineal descent," a woman
who lived even further into the past who passed on her mtDNA to everyone living
during "Eve's" time. (We get our mtDNA from that same, older ancestor. She's
just not, to us, the most recent common ancestor.)
So what about all of the mtDNA of the other women who lived during "Eve's" time?
What happened to it? Simply this: Somewhere between now and then, they had
female descendants who had only sons (or no children). When this happened, the
passing on of their mtDNA halted.
Finding mitochondrial ancestors
Even though everyone on Earth living today has inherited his or her mtDNA from
one person who lived long ago, our mtDNA is not exactly alike. Random mutations
have altered the genetic code over the millennia. But these mutations are
organized, in a way. For example, let's say that 10,000 years after the most
recent common ancestor, one of the mtDNA branches experienced a mutation. From
that point on, that line of mtDNA would include that alteration. Another branch
might experience a mutation in a different location. This alteration would also
be passed on. What we would eventually end up with are some descendants who
have mtDNA that is exactly or very much like that of some people's, somewhat like that
of others, and less like that of yet others. By looking at the similarities
and differences of the mtDNA of all of these individuals, researchers could try
to reconstruct where the branching took place.
This is what some researchers have done. For the original 1987 Nature
article, the three authors (Rebecca Cann, Mark Stoneking, and Allan Wilson)
looked at the mtDNA of 147 people from continents around the world (though for
Africans, they relied on African Americans[2]). Later, with the help of a
computer program, they put together a sort of family tree, grouping those with
the most similar DNA together, then grouping the groups, and then grouping the groups of
groups. The tree they ended up with showed that one of the two primary branches
consisted only of African mtDNA and that the other branch consisted of mtDNA from
all over the world, including Africa. From this, they inferred that the most recent common mtDNA ancestor was an
African woman.[3]
Dating mitochondrial ancestors
The three researchers went even further—they estimated the age of the
ancestor. To get the estimate, they made the assumption that the random
mutations occurred at a steady rate. And since they now had an idea of how much
the mtDNA had changed from the ancestor's, all they needed was the mutation
rate to determine the age of the ancestor. For instance, if they took the
mutation rate to be one in every 1,000 years and knew that there was a
difference of 10 mutations between the mtDNA of people living today and the
mtDNA of an ancestor who lived long ago, then they could infer that the
ancestor lived 10,000 years ago.
Cann, Stoneking, and Wilson estimated the mutation rate by looking at the mtDNA
of groups of people whose ancestors migrated to areas at known times. One group
was Australian aborigines, whose ancestors moved to the island-continent a
then-calculated 30,000 years ago.[4] Since the three then knew how long it
took for that group's mtDNA to diverge as well as how much it diverged, they
determined the mutation rate. Using this rate, they determined that the most
recent common ancestor lived 140,000 to 290,000 years ago (which they roughly
averaged to 200,000 years ago). That was back in 1987. Since then, researchers
have updated the estimate to 120,000 to 150,000 years ago. However, the margin
for error for this estimate and the previous one are significant—when all of
the variables are taken into account, the current range is more like 50,000 to
500,000.
Mitochondrial DNA is extracted from the bones of Neanderthals
and compared to the mtDNA of living Homo sapiens.
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Neanderthals and mtDNA
Finding out about our most recent common ancestor relies solely on inferences
from the mtDNA of people living today. What if we could actually compare our
mtDNA with mtDNA of a distant ancestor? This, in fact, has been done, with
mtDNA from the bones of Neanderthals. Comparing mtDNA of these Neanderthals to
mtDNA of living people from various continents, researchers have found that the
Neanderthals' mtDNA is not more closely related to that of people from any one
continent over another. This was an unwelcome finding for anthropologists who believe
that there was some interbreeding between Neanderthals and early modern humans living in Europe
(which might have helped to explain why modern Europeans possess some Neanderthal-like
features); these particular anthropologists instead would have expected the Neanderthals' mtDNA
to be more similar to that of modern Europeans than to that of other peoples. Moreover,
the researchers determined that the common ancestor to Neanderthals and modern
Homo sapiens lived as long as 500,000 years ago, well before the most
recent common mtDNA ancestor of modern humans. This suggests (though it does
not prove) that Neanderthals went extinct without contributing to the gene pool
of any modern humans.
Final note
There are many variables that can affect the mutation rate of mtDNA, including
even the possibility that mtDNA is not always inherited strictly through maternal
lines. In fact, recent studies show that paternal mtDNA can on rare occasions enter an egg during
fertilization and alter the maternal
mtDNA through recombination. Such recombination would drastically affect the
mutation rate and throw off date estimates.
Not surprisingly, there is currently a heated debate over the value of
"mitochondrial Eve"—especially between history-hunting geneticists and
some fossil-finding paleoanthropologists. According to these
anthropologists, even if we could accurately gauge the age of the ancestor,
that knowledge is meaningless because all she really is is the woman whose
mtDNA did not die out due to random lineage extinctions. Furthermore, her
status as the most recent common ancestor doesn't mean that she and her
contemporaries were any different from their ancestors. (Remember, she and all
of her contemporaries had their own mitochondrial Eve.)
Perhaps the most valuable finding regarding the "most recent common ancestor"
is that she probably lived in Africa—a finding that supports the most
popular theories about the worldwide spread of hominids.
Rick Groleau is managing editor of NOVA Online.
Notes
1. Unless two or more of those 64 married each other and bore
children from which you are descended. For example, your great-great-grandfather on your
mother's side might have married and had children with your great-great-grandmother
on your father's side. In that case, the number of your ancestors in this example
would drop to 63.
2. Although the original study was criticized for using African Americans
instead of native Africans, a subsequent study in which the researchers used
mtDNA from native Africans came up with similar results.
3. Other researchers later showed that the computer program could come up with
other variations of the tree, some of which did not place an African at the
root of the tree. This study, then, cannot be viewed as definitive proof that
the ancestor lived in Africa. However, it does still suggest that humans
originated in Africa, a hypothesis that other, more recent studies support.
4. The date for the migration to Australia is now estimated to be 50,000 to
60,000 years ago.
Sources
"Human Evolution." Svante Pääbo. Trends in Genetics. 15(12): M13-M16, 1999.
"Neanderthal DNA Sequences and the Origin of Modern Humans." Matthias
Krings, et al. Cell, July 11, 1997.
"Mitochondrial DNA and Human Evolution." Rebecca L. Cann, Mark Stoneking,
Allan C. Wilson. Nature, January 1, 1987.
"The Case of Mitochondrial Eve." Frank R. Zindler. American
Atheist, February 1988.
Shreeve, James. The Neanderthal Enigma: Solving the Mystery of Modern
Human Origins. New York: Avon Books, 1995.
Stringer, Christopher; Clive Gamble. In Search of the Neanderthals:
Solving the Puzzle of Human Origins. New York: Thames and Hudson, Inc.,
1993.
Related features on NOVA Online
Photos: (1,2) WGBH/NOVA.
Casts of Characters |
Into the Fray |
Tracing Ancestry with MtDNA |
Dig and Deduce
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