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In 1966, a young chemist suggested a radical new theory for how life might have
begun on Earth. Fifty years on, we ask if there was any truth in his ideas
By Martha Henriques
24 August 2016
A rock is the ultimate example of inanimate, dead matter. After all, it just
sits there, and only moves if it is pushed. But what if some minerals are not
as stone-dead as we thought?
Chemist Graham Cairns-Smith has spent his entire scientific career pushing a
simple, radical idea: life did not begin with fiddly organic molecules like
DNA, but with simple crystals.
It is now 50 years since Cairns-Smith first put forward his ideas about the
origin of life. Some scientists have ridiculed them; others have, cautiously or
wholeheartedly, embraced them. They have never become mainstream orthodoxy, but
they have never quite gone away either. Was there any truth to Cairns-Smith's
daring proposal? Did life really come from crystals?
In June 2016 I visited Cairns-Smith and his wife Dorothy at their house on the
outskirts of Glasgow, UK. Now 85, he has a rare condition related to
Parkinson's disease, which has affected his mobility. However, his scientific
curiosity and his sense of humour remain undimmed.
He was a dour man and he sort of muttered, 'A pity you chose science'
While he will most likely be remembered for his theories on the origin of life,
his first passion was painting.
"We met when he was at Glasgow and he was doing these," says Dorothy, showing
me the prolific collection lining almost every wall in the downstairs of their
house. "He was going through an abstract phase."
Cairns-Smith's success as a painter eventually became too demanding. He was
putting on one-man shows and getting paintings into the Royal Scottish Academy,
but decided to quit and focus on science, which offered a more reliable income
with which to support a family.
"There was a man called William Crosbie, who was a very well-known Scottish
painter, who was teaching him [at Glasgow]," Dorothy recalls. "He was a dour
man and he sort of muttered, 'A pity you chose science'."
However, Cairns-Smith does not seem to have any regrets about his decision.
Copies of his scientific books, and the sketches he drew to illustrate them,
are spread across his upstairs study. They have just as much of a presence in
the house as his artwork.
As a student at the University of Edinburgh in the 1950s, Cairns-Smith became
fascinated by the problem of how life began.
Through his studies of organic chemistry, Cairns-Smith understood that the
essential molecules of life such as DNA and proteins could be delicate and
temperamental. So how could complex molecules like these spring from the soup
of simple compounds on the primordial Earth? This puzzle still occupies
scientists today.
To Cairns-Smith, the experiment raised more questions than it answered
In a study published in 1953 the same year that the structure of DNA was
discovered a biochemist called Stanley Miller sent a bolt of electricity
through a mixture of gases and liquids thought to have been present on the
early Earth. The spark turned these simple chemicals into some of the most
basic building blocks of life: amino acids, the units that link together to
make proteins.
The story hit the headlines. "Science: Semi-creation" was the headline in Time
magazine. Miller's study became a landmark scientific paper.
But to Cairns-Smith, the experiment raised more questions than it answered.
Although Miller had made some of the most essential compounds of life, his
experiment did not explain how they and other building blocks such as
nucleotides, which make up DNA first came together in an ordered way, to form
the complex molecules necessary for life.
His aim was to find a system much simpler than modern life
In Miller's experiment, "simpler molecules are more likely to be found and more
likely to form than more complex molecules," says Cairns-Smith. "The idea you'd
make a nucleotide is ridiculous. The more complicated the molecule, the less of
it will form."
For Cairns-Smith, this was the real problem. He thought there had to be another
stage before our elaborate system of genetic material took over.
"It was an extremely interesting experiment," says Cairns-Smith. He also
describes it as "beautiful". But it did not satisfy his curiosity.
So he decided to go back to basics.
Cairns-Smith asked himself two questions: What are the essential properties
needed for a living system, and can those properties be found anywhere other
than the forms of life that we know today?
If you look at clay under a microscope, you will find that it is made of tiny
crystals
His aim was to find a system much simpler than modern life, but which had some
of the crucial properties of a living system. He found an answer in an unlikely
place: clays.
Most of us, if we think about clay at all, probably just remember how bad we
were in pottery class at school. Clay, at first glance, is just a sort of damp,
vaguely gritty dirt.
But Cairns-Smith knew there was more to clay than that. In an abstract way, it
can be rather life-like.
If you look at clay under a microscope, you will find that it is made of tiny
crystals. Within each crystal, atoms are arranged in a structure that repeats
in a tightly-packed, regular pattern.
Crystals' essential characteristics mean they are primed to begin evolving
Each crystal can grow, if it is placed in water laced with the same chemical
components. Crystals can also split apart, with one "mother" crystal giving
rise to "daughter" crystals.
Each crystal can even have its own peculiarities, which it can pass on to its
daughter crystals much like living things inherit traits from their parents.
And sometimes, when a crystal breaks apart, new quirks can be introduced, for
instance because of the stress of breaking. This is similar to the process of
genetic mutation, which creates new traits in living things.
In other words, Cairns-Smith reasoned, crystals' essential characteristics mean
they are primed to begin evolving.
When a crystal passes its peculiarities onto its daughters, these unique traits
could either help or hinder the new crystals.
For instance, the daughters may end up more likely to be able to split into two
crystals. If the characteristics of a crystal affect its ability to split
apart, then in effect that crystal has an evolutionary advantage.
In 50 years there have only been a handful of experiments exploring
Cairns-Smith's ideas
In a sense, physical flaws or peculiarities in a crystal could be thought of as
genetic information. As a result, Cairns-Smith thought that crystal minerals
could be subject to a simple form of evolution by natural selection. This idea
is now called the "crystals-as-genes hypothesis".
At a later stage, Cairns-Smith reasoned, biological molecules like DNA began to
associate with the crystals. This helped the replication process. Eventually, a
"genetic takeover" happened: the biological molecules developed the ability to
replicate by themselves, and left the crystals behind.
Cairns-Smith set all this out in a paper published in 1966, half a century ago.
His ideas are elegant, but there is a big problem: they have proved almost
impossible to test. In 50 years there have only been a handful of experiments
exploring Cairns-Smith's ideas.
The trouble is that there is no experimental technique for studying minerals at
the tiny scales necessary to examine the processes Cairns-Smith outlined, says
Dieter Braun of Ludwig Maximilian University of Munich in Germany.
I fell in love with the book because it was so unlike a typical scientific
monograph
Researchers would have to minutely examine nanoscale crystals, underwater, over
a period of days to monitor how they behave. "That's just technologically very
difficult," Braun says.
He says we would need something analogous to genetic sequencing, the method by
which researchers "read" the letters of DNA that make up the human genome. "You
know, it took us 40 years to get sequencing for a molecule like DNA really
working fast," says Braun.
Braun adds that geneticists had a powerful motivation to perfect DNA
sequencing: it promised new medical treatments. Studying clay crystals would be
equally difficult and expensive, with no practical benefit.
Even so, at least one element of Cairns-Smith's hypothesis has been put to the
test.
Bart Kahr is a crystallographer at New York University in the US. He first
discovered Cairns-Smith's ideas when he came across one of his books in a shop
in the mid-1980s.
He wanted to track how mother crystals pass on their traits to daughter
crystals
"I fell in love with the book because it was so unlike a typical scientific
monograph," says Kahr. "It was so impossibly rich [in] genuinely new ideas, and
it was written in a kind of a literary vein, almost."
The next time Kahr saw the idea mentioned was in the mid-2000s when it was
harshly criticised.
"I was astonished that, 25 years on, people would still invoke the
crystals-as-genes theory, only to knock it down by instantly saying that
there's not any evidence for it whatsoever," says Kahr. "It was like a
persistent straw man, that everybody felt that they had to acknowledge, but
only to then pejoratively dismiss it as not ever having been tested."
Kahr decided to test it in his lab. He wanted to track how mother crystals pass
on their traits to daughter crystals, to find out whether inheritance might
work in clay minerals.
He decided to focus on a set of crystal traits called "screw dislocations".
These are columns running throughout the crystal, where part of it has been
nudged slightly out of alignment. Dislocations come about through the process
of crystal growth, and the pattern of dislocations throughout a crystal can
form a unique pattern.
Clays are just lousy crystals
Cairns-Smith had likened these irregularities to the holes in old-fashioned
computer punch cards. In the same way, he supposed that these dislocations
could act as a store of information.
Kahr wanted to test whether this pattern of dislocations would be inherited by
the daughter crystal, and how many mutations new dislocations would be
introduced when a daughter crystal broke off.
To avoid some of the experimental difficulties that Braun foresaw, Kahr used
crystals of potassium hydrogen phthalate, which were easier to work with than
clay. "Clays are just lousy crystals," he says.
Kahr and his team developed a technique to map the screw dislocations of mother
and daughter phthalate crystals. They found that they could see the
dislocations mapping on from mother to daughter crystal quite neatly. The
results were published in 2007.
Fewer mutations would have been "more like life as we know it now"
However, they were surprised by just how many additional defects appeared in
the daughter crystals after they had broken off. The daughter crystals were
riddled with these "mutations", and typically had at least as many new
dislocations as inherited ones.
That was a problem for Cairns-Smith's ideas. If the crystals were to gradually
evolve, there needed to be more inheritance than mutation, so that mothers
could have a strong effect on their daughters' pattern of dislocations.
"For this to be a convincing demonstration, you can't go from a frog to a
monkey in a single generation," he says. Fewer mutations would have been "more
like life as we know it now".
However, Kahr is not the only one to have explored Cairns-Smith's ideas.
Rebecca Schulman, a bio-engineer at Johns Hopkins University in Baltimore,
Maryland, was also inspired by the crystals-as-genes hypothesis.
She had found a way to represent and copy information, in crystal form
In a series of experiments published over the last decade, she has designed a
system where information is coded in a crystal structure. Rather than using
naturally-occurring minerals, Schulman used crystals of nanometre-scale tiles
that were made of DNA.
This DNA did not carry information in the way that it usually does in our
cells. Instead, Schulman used it like Velcro to stick the tiles together in a
crystal structure. It was the order of the tiles that encoded the information.
"If we could build any kind of crystal based on the very simple physical rules
that we know crystals must obey, then it's possible to imagine interesting
evolution processes that could emerge in relatively simple environments," she
says.
Schulman found, first through computer simulation and then by experiment, that
the DNA tiles could stack up in a particular pattern, effectively encoding
information in a crystal structure. She had found a way to represent and copy
information, in crystal form.
On a theoretical level, her findings are useful for studies of the origin of
life. "Part of the goal for origin-of-life research is very broadly to ask how
one can design systems in chemistry where information can be replicated," says
Schulman.
He could never get funding
However, Schulman's studies do not show that Cairns-Smith's theory is correct.
For one thing, her experiments did not use clay. More broadly, just because the
process works in the lab does not necessarily imply that life on Earth really
began that way.
That is about it for rigorous experimental tests of the crystals-as-genes idea.
Cairns-Smith himself tried for years to put his ideas to the test, but made
little headway.
"He could never get funding," Dorothy says. A major stumbling block to securing
research grants was that his work straddled too many different disciplines.
"One time we went to California, and Graham gave lectures to the Menlo Park
Geology Survey," says Dorothy. "They all said, well, your geology's fine but I
don't think your chemistry's right. Then he gave a lecture to NASA on the
chemistry side and they said, well, your chemistry's fine but I'm not sure
about your biology. And then he lectured to Berkeley and they said, well, your
biology's fine but I'm not sure about your geology."
I was supremely disappointed by people who think that more complicated ideas
are more likely to be true
Cairns-Smith found a more eager audience in science journalists and the popular
press. Other scientists showed interest, too: the evolutionary biologist and
writer Richard Dawkins discussed the crystals-as-genes hypothesis in his 1986
book The Blind Watchmaker.
Eventually Cairns-Smith's publisher encouraged him to write a popular science
book on his ideas. Entitled Seven Clues to the Origin of Life, it was published
in 1990. Written in the style of a murder mystery, it is about as gripping as a
book on organic chemistry can get.
Cairns-Smith says he enjoyed writing for wider audiences, because putting a
point simply and intuitively held a satisfaction for him. "I was supremely
disappointed by people who think that more complicated ideas are more likely to
be true," he says.
But despite his best efforts, his ideas did not enter the scientific
mainstream.
"I'm puzzled generally speaking at why some things in science seem to catch on
and others seem not to catch on," says Kahr. "There's no accounting for popular
taste."
But even if Cairns-Smith's specific ideas never pan out, there are two ways in
which they continue to influence the science of the origin of life even today.
Until now, origin of life research was really chemistry-dominated
The first is that they raise the question of what constitutes life, and offer a
way in which life-like processes can arise without familiar molecules like DNA.
"It's a good idea to look around beyond what biology is really teaching us,"
says Braun. "Why not scope out the possibilities quite widely? I'm all in for
that."
Secondly, Cairns-Smith's multidisciplinary approach fusing biology, chemistry
and geology was way ahead of its time.
"Until now, origin of life research was really chemistry-dominated," says
Braun. But in the last couple of decades, it has become broader: as well as
trying to make the key chemicals of life, researchers are also using genetics
to work out what the earliest life was like, and using geology to figure out
the conditions in which it formed.
The specific scenario he envisaged may well be completely wrong
"I guess people will still see it as a little bit of an oddity, but he was
really pointing us in the right direction," says Braun. "People now realise
that life is not arising just in water in a glass flask, but in all the
chemistry of the environment and from geology. That's his legacy: to say, look
in more detail at rocks."
There may never be hard evidence for Cairns-Smith's ideas. "If this were to be
a huge scientific enterprise, if there were huge technology behind it, there
would be enough resources to really push the experiments," says Braun. "But
it's really just a very small community, and this is a little bit too far out."
However, the lack of evidence will not be Cairns-Smith's real legacy. The
specific scenario he envisaged may well be completely wrong. But in terms of
inspiring people to look at the question of life's origin in new ways, his work
has punched well above its weight.