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The Birth of Birth
180 million years ago, our ancestors were still hatching from eggs. Then something radical happened.
March/April 2007
by Steve Olson '78
Steve Olson '78 was a National Book Award finalist in 2002. His most recent book is Count Down.
For months, here on the third floor of Osborn
Laboratory, just at the foot of Science Hill, graduate student Vinny Lynch has
been trying to get platefuls of reluctant cells to grow and divide. His
dissertation and PhD could depend on this project. So could an unprecedented
effort to uncover the origins of one of nature’s most remarkable creations: the
womb.
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How does evolution give rise to new body parts?
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Lynch, who has long curly hair and a colorful tattoo
of a carp that wraps around his calf, takes a petri dish from the incubator and
puts it under a microscope. The cells look like translucent leaves on a bank of
snow—“just like any other cells,” Lynch says. But these cells
aren’t like other cells. They’re missing a crucial gene known as HoxA-11. During the development of a human
embryo, this gene helps direct the construction of arms, legs, vertebrae, and
—if Lynch and his advisor, Gunter Wagner, are right—the mammalian female
reproductive tract.
Without the missing gene, the cells aren’t doing
well. They grow slowly. They react poorly to the hormones Lynch gives them.
That’s an annoyance, given Lynch and Wagner’s ambitions for this experiment.
They want to take on perhaps the most hotly debated topic in evolutionary
biology today: how does evolution give rise to new body parts?
Even Charles Darwin once wrote that he “felt
much difficulty in understanding the origin of simple parts.” He saw quite
clearly how existing parts could evolve into more complex structures. Evolution
is adept at working with what’s already there—accentuating the positive
(nocturnal mammals have evolved larger eyes) and eliminating the negative
(Arctic hares no longer have dark fur in the winter). But how do entirely new
biological features originate—the eye, hair, the uterus?
The question still dominates many debates over
evolution. Creationists claim that complex structures are evidence of God's
handiwork. They say that the intricate biochemistry of life, the precisely
fashioned parts of organisms, and especially the self-awareness and moral sense
of humans could not have simply evolved. And even many of those who accept the
reality of evolution are sometimes incredulous at its creativity. As the
biologist Richard Dawkins has written, “People have a hard time believing
that so simple a mechanism could deliver such powerful results.” Maybe
that’s one reason why just 14 percent of Americans unequivocally accept the
standard scientific account of how evolution works.
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Nature produces new body parts all the time.
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Yet nature produces new body parts all the time, if
you think about the word “new” in a different context. A fertilized egg
slowly drifting down a woman’s fallopian tube has pretty much the same internal
components as any other human cell. But just nine months later, that single
cell will have produced an organism with arms, ears, blood vessels, digestive
organs, a brain, and, in females, a new collection of eggs waiting to begin the
process anew.
The instructions for making all these parts reside in
the DNA of the fertilized egg. As an embryo develops, each new cell inherits
the same DNA as in the original fertilized egg. But different segments of DNA
are active in different kinds of cells. “The differences between body
parts in embryological development are caused by differential expression of
genes,” says Wagner, 52, a sinewy, precise, soft-spoken man. “Certain
genes are only expressed in the liver and others in the brain. The key to
understanding what makes a tooth or a liver or a thumb has to be related to the
ways genes are regulated.”
So if you want to make a different body part, you
have to change the DNA in a fertilized cell. The links between DNA,
development, and evolution have been obvious since DNA was identified as the
carrier of genetic information more than 50 years ago. But only in the past
couple of decades have biologists been able to investigate the connection.
First, they had to develop the tools of genetic engineering. When biologists
could change specific genes in mouse and fruit fly embryos, they could analyze
the effects on the growing animal.
Even more important, biologists needed some way of
determining how DNA has changed over evolutionary time. Except in rare cases
(such as with bones buried in cold caves), extinct organisms don’t leave their
DNA behind. But biologists have figured out a work-around.
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Two branches of biology have formed a new field: evolutionary-developmental biology, or “evo-devo.” |
As scientists began to sequence the genomes of humans
and other organisms, they realized that they could reconstruct much of the
genomes of extinct organisms by comparing the DNA of species descended from
common ancestors. For example, we now know most of the genetic code of the
common ancestor of humans and chimpanzees—an ape-like animal that lived
about six million years ago—because much of the DNA common to humans and
chimpanzees descended to us, unchanged, from that ancestor. Where the DNA is
different, scientists can usually figure out the genetic sequence of the common
ancestor by analyzing the DNA of other primates.
The combination of these new techniques has allowed
two branches of biology to come together to form a new field:
evolutionary-developmental biology, or “evo-devo.” “There has
been an explosion of findings that have been enabled essentially by genetic
technologies,” says Stephen Stearns, the Edward P. Bass Professor of
Ecology and Evolutionary Biology at Yale. “Evo-devo is in the process of
settling a lot of important and long-standing questions by giving us a very
detailed picture of how genes result in organisms.”
One remarkable finding from evo-devo is how similar
human beings are, on a genetic level, to other organisms. “Most animals
share very similar sets of genes,” says Sean B. Carroll, an evo-devo
pioneer at the University of Wisconsin-Madison. “It was thought maybe 35
years ago that novel structures had to involve new genes. It’s sort of
intuitive that if you’re going to make new things, you need new genes. But that
seems to be pretty much wrong. Novelty and diversity come from using the same
things in new and different ways.”
Wagner’s work on the female reproductive tract began
as a hunch. Several years ago, Wagner was looking at the role of HoxA-11 in the development of limbs when he
came across an unusual finding. Researchers at the University of Cincinnati
College of Medicine had found that female mice without a functioning HoxA-11 gene are infertile. They produce
healthy eggs, which develop normally if they are transplanted into other mice.
But the eggs can’t develop inside their own mothers because they can’t implant
in the uterine wall.
Some scientists would ignore a tangential finding
like this. Tracking down the cause of the effect was sure to be complicated; a
graduate student could spend years on the project and have little to show for
it. Wagner saw nothing but potential. “When something unexpected
happens,” he says, “you have to pursue it.”
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Wagner pursues the unexpected.
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Pursuing the unexpected is a pretty good summary of
Wagner’s scientific style. Born and raised in Vienna, he became fascinated with
evolution as an undergraduate and worked as a graduate student on the
mathematics of evolutionary theory. But after earning his PhD in 1979, he did
two postdoctoral fellowships designed to develop his laboratory skills in
neurobiology. After joining the University of Vienna faculty, he quickly became
known for synthesizing mathematical analysis and hands-on lab work. Yale
recruited him in 1991; the following year, he received a MacArthur “genius"
grant.
Wagner, now the Alison Richard Professor of Ecology
and Evolutionary Biology at Yale, has built an extraordinarily wide-ranging
research group. Students and postdoctoral fellows in his lab have studied,
among many other topics, the evolution of fins, the mathematics of gene
interactions, limb regeneration in amphibians, and the origin of birds' wings.
Lynch was a brand-new graduate student whe n Wagner
started studying the infertile mice, and he eagerly volunteered to work on the
project. The evolution of the mammalian reproductive tract is an inherently
interesting problem. Almost everyone has wondered at some point about the odd
juxtaposition of the reproductive and excretory systems. (The classic
formulation of the problem among biologists is: why is the sewer system routed
through the entertainment center?) But human plumbing, at least in females, is
a model of decorum compared with that of our evolutionary kin. In reptiles and
birds, the female reproductive tract consists of a relatively simple tube. Eggs
drop into the top of the tube from the ovary. As they make their way toward the
outside world, the eggs are surrounded by the yolk, the white, and a hard
shell. The tube then empties into an all-purpose excretory tract called the
cloaca. In Latin, cloaca means sewer, which gives you a pretty good idea of
what’s going on down there in our nonmammalian relatives.
(The penis has a different story. It has evolved a
number of times in separate animal lineages. Perhaps more alarmingly, it also
has disappeared a number of times among species that evolved other ways of
delivering sperm to eggs.)
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The earliest mammals laid eggs, like the reptiles from which they evolved. |
The earliest mammals laid eggs, like the reptiles
from which they evolved. But about 180 million years ago, a mammalian species
that probably looked something like a small mole or opossum began doing things
differently. It started retaining its eggs in its body for part of their
development. “It’s much more adaptive for the female to hold the eggs
within her for longer and longer periods,” Lynch argues. “Maybe there
were high tides, or bad storms in the spring, when you lay your eggs. That way,
the female can control the environment.”
This was an interesting time in the evolution of
mammals. Two kinds of egg-laying mammals, descendants of those that lived 180
million years ago, survive today: the platypus and the echidnas. The echidna,
which looks like a hedgehog and lives in New Guinea and Australia, still has a
reproductive system much like that of reptiles. But when baby echidnas hatch,
their mothers provide them with milk rather than scraps of gathered food.
Another group of mammals, represented today by the
marsupials, went partway toward internal development and then veered in another
direction. An opossum embryo, for example, attaches to the reproductive tract
of its mother. But it receives food and oxygen there for just a few days before
it emerges from the birth canal, crawls into its mother’s pouch, and latches
onto a teat to continue its development.
All other mammals living today are descended from
ancestors that evolved ways to nurture embryos internally for weeks or months.
But to carry an embryo to term, our mammalian ancestors needed a much more
complicated reproductive system than in reptiles and birds. They needed the
uterus, where the embryo develops. They needed the vagina, which is similar in
structure to the cloaca but is apparently, Wagner says, “a complete
developmental novelty.” And they needed the endometrium—specialized
cells within the uterus where the embryo can attach.
The mice that lacked HoxA-11 also lacked a functioning
endometrium. There could be many explanations for that. But it was possible,
Wagner thought, that HoxA-11 and related genes were key in the evolution of this
critical new part.
In 2001, Wagner and Lynch set out to determine whether
changes in HoxA-11 helped
bring about the evolution of the endometrium. For this experiment, they didn’t
need petri dishes. They used computers.
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Very old genes have learned new tricks. |
HoxA-11 is one of a large group of genes that biologists are
studying intensively. The Hox genes are the classic example in evo-devo of very
old genes that have learned new tricks. Originally discovered in fruit flies,
these genes were later shown to coordinate the development of body parts in all
animals, from sea anemones to humans. Essentially, a Hox gene acts like the
director of a movie. It tells hundreds of other genes to turn on or turn off.
In turn, these active and inactive genes then determine where a cell should go
during development and what that cell should be. Furthermore, each Hox gene is
like a director who works on several movies at once. A given Hox gene might
direct the construction of arms and legs, fingers and toes, and the digestive
tract. And in true Hollywood style, a Hox gene can run amok: when cancer cells
begin to proliferate, Hox genes are often at the center of the chaos.
For their research, Wagner and Lynch first obtained
the DNA sequence of HoxA-11 from several organisms, including humans, mice, opossums,
chickens, and fish. (The sequences for some organisms were already available in
databases; for others, Wagner and Lynch sequenced the gene themselves.) They
reasoned that organisms without a uterus, like chickens and fish, should have a HoxA-11 gene
similar to the ancestral version. In contrast, mammals like humans and mice
should have a version of the gene that includes the directions for making a
uterus. Marsupials like the opossum or kangaroo should be intermediate cases,
since they have some of the components needed for internal development but not
all.
When a gene like HoxA-11 evolves, the process leaves a
telltale trace. Changes in a DNA sequence—caused by chance copying errors
when a cell divides—may have no effect on the protein encoded by a gene.
These silent changes happen more or less at random and at a constant rate,
which establishes a sort of ticking clock that can be used to time evolutionary
processes. Other DNA changes do alter proteins. Many of these changes are harmful,
and the organisms that have them die or fail to reproduce. But some
protein-altering changes enable an organism to have more offspring. Over
successive generations, these changes can become more common. By comparing the
rate of beneficial changes with the background rate of neutral changes,
geneticists can estimate when the changes to a gene proliferated because they
gave the organism an advantage. In short, they can find out when an
evolutionary change to a gene took place.
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Wagner’s hunch paid off dramatically. |
Wagner’s hunch paid off dramatically. When he and
Lynch compared the DNA sequences of animals with and without a uterus, they
found a burst of evolutionary change in HoxA-11 about 180 million years ago, just
when the fossil record suggests that the uterus was beginning to take shape.
The finding, says Jeffrey Innis, a Hox expert at the University of Michigan, “demonstrates
the power of relating new genomic sequences to evolutionary and anatomical
information.”
It was the first time that change in a single gene
had been tied to the evolution of a novel body part—confirmation that a
small change in a very old gene had been essential in creating something new.
Lynch’s current experiment is an attempt to build on
this work and find out how HoxA-11 does what it does. The cells in his incubator are mouse
uterine cells from which the HoxA-11 gene has been removed. As a result, their output of
proteins has changed. They can’t make the crucial proteins of the endometrium
that enable an embryo to attach.
Lynch has dozens of petri dishes in the incubator,
and millions of cells in each dish. (A sign on the lab door reads, “Capacity: 1012.”) If he can get these cells to grow well,
he and Wagner are planning to reinsert the HoxA-11 gene from various organisms into
the cells. Their hypothesis is that HoxA-11 from a mouse or a human should
return the cells to their fecund state: the mix of proteins they produce will
be the same as that of normal mouse uterine cells.
But HoxA-11 from a chicken should fail to change the proteins. And the
genes from an opossum and a platypus should fall somewhere in between.
The problem is that removing the HoxA-11 gene appears to have altered the
cells in some more fundamental way. They don’t seem to realize any longer that
they are uterine cells; they don’t respond to the hormones that would trigger
normal uterine cells to mature. To Lynch, it suggests that the missing HoxA-11 must have an unknown function
earlier in the cell’s development. “They’re having an identity
crisis,” he says.
It’s a setback that might take some time to solve, Lynch acknowledges. But he doesn’t seem to mind. For one thing, he has learned
from Wagner that unexpected outcomes can provide rich scientific insights.
Already, he points out, “we’ve learned something cool—that HoxA-11 is needed for cell identity.”
And Lynch knows that he and Wagner are working on one
of the great mysteries of biology. They’re showing that biological creativity
does not require a divine act of creation. It just requires time. Evolution is
itself an experimentalist. It tries a new arrangement of molecules to see what
will happen. If the experiment fails, it is discarded. But every once in a
while an experiment succeeds, and on that successful result, new experiments
can be conducted. The mechanism is simple, but it creates wonders.  |
