In the late 1980s, scientists at Osaka University in Japan noticed
unusual repeated DNA sequences next to a gene they were studying in a common
bacterium. They mentioned them in the final paragraph of a paper: "The biological
significance of these sequences is not known."
Now their significance is known, and it has set off a scientific frenzy.
The sequences, it turns out, are part of a sophisticated immune system
that bacteria use to fight viruses. And that system, whose very existence was
unknown until about seven years ago, may provide scientists with unprecedented
power to rewrite the code of life.
In the past year or so, researchers have discovered that the bacterial
system can be harnessed to make precise changes to the DNA of humans, as well
as other animals and plants.
This means a genome can be edited, much as a writer might change words
or fix spelling errors. It allows "customizing the genome of any cell or
any species at will," said Charles Gersbach, an assistant professor of
biomedical engineering at Duke University.
Already the molecular system, known as CRISPR, is being used to make
genetically engineered laboratory animals more easily than could be done
before, with changes in multiple genes. Scientists in China recently made
monkeys with changes in two genes.
Scientists hope CRISPR might also be used for genomic surgery, as it
were, to correct errant genes that cause disease. Working in a laboratory —
not, as yet, in actual humans — researchers at the Hubrecht Institute in the
Netherlands showed they could fix a mutation that causes cystic fibrosis.
But even as it is stirring excitement, CRISPR is raising profound
questions. Like other technologies that once wowed scientists — like gene
therapy, stem cells and RNA interference — it will undoubtedly encounter
setbacks before it can be used to help patients.
It is known, for instance, that CRISPR can sometimes change genes other
than the intended ones. That could lead to unwanted side effects.
The technique is also raising ethical issues. The ease of creating
genetically altered monkeys and rodents could lead to more animal
experimentation. And the technique of altering genes in their embryos could
conceivably work with human embryos as well, raising the specter of
"designer babies."
"It does make it easier to genetically engineer the human germ
line," said Craig C. Mello, a Nobel laureate at the University of
Massachusetts Medical School, referring to making genetic changes that could be
passed to future generations.
Still, CRISPR is moving toward commercial use. Five academic experts
recently raised $43 million to start Editas Medicine, a company in Cambridge,
Mass., that aims to treat inherited disease. Other startups include Crispr
Therapeutics, which is being formed in London, and Caribou Biosciences in
Berkeley, Calif.
Agricultural companies might use CRISPR to change genes in crops to
create new traits. That might sidestep the regulations and controversy
surrounding genetically engineered crops, which generally have foreign DNA
added.
The development of the new tool is an example of the unanticipated
benefits of basic research. About 15 years ago, after it became possible to
sequence the entire genomes of bacteria, scientists noticed that many species
had those repeated DNA sequences that were first noticed a decade earlier in
Osaka. They were called "clustered regularly interspaced short palindromic
repeats" — CRISPR for short.
But what was their purpose? In 2007, researchers at Danisco, a company
that supplies bacterial cultures used in making cheese and yogurt, confirmed
hypotheses that CRISPR protects bacteria from viruses.
It is part of an adaptive immune system — one that remembers a pathogen
so it is ready the next time that same invader appears. The human adaptive
immune system is why people get measles only once and why vaccines work. But it
was not imagined that single-cell organisms like bacteria had such systems.
Here is how it works. The repeated DNA sequences in the bacterial genome
are separated from one another by other sequences. These "spacers"
are excerpts from the sequences of viruses that have attacked the bacterium or
its ancestors. They are like genetic mug shots, telling the bacterium which bad
guys to watch for. The CRISPR defense system will slice up any DNA with that
same sequence, so if the same virus invades again, it will be destroyed.
If a previously unseen virus attacks, a new spacer, a new mug shot, is
made and put at the end of the chain.
That means the CRISPR region "is like a tape recording of exposure
to prior invaders," said Erik J. Sontheimer, a Northwestern University
professor who helped unravel the mechanism.
And it provides a way to tell two bacterial strains apart, because even
two strains from the same species are likely to have encountered different
viruses. This is already being used to identify sources of food-poisoning
outbreaks.
Cheese and yogurt companies can examine CRISPR regions to see if their
bacterial cultures are immunized against particular viruses that could slow
production.
"Now you can extend the shelf life of that great strain," said
Rodolphe Barrangou of North Carolina State University, who previously worked at
Danisco and was the lead author on the 2007 paper. "That has changed the
game quite a bit for the dairy industry."
The real frenzy started in 2012, when a team led by Emmanuelle
Charpentier, then at Umea University in Sweden, and Jennifer A. Doudna of the
University of California, Berkeley, demonstrated a way for researchers to use
CRISPR to slice up any DNA sequence they choose.
Scientists must synthesize a strand of DNA's chemical cousin RNA, part
of which matches the DNA sequence to be sliced. This "guide RNA" is
attached to a bacterial enzyme called Cas9. When the guide RNA binds to the
corresponding DNA sequence, Cas9 cuts the DNA at that site.
The cell tries to repair the cut but often does so imperfectly, which is
enough to disable, or knock out a gene. To change a gene, scientists usually
insert a patch - a bit of DNA similar to where the break occurred but
containing the desired change. That patch is sometimes incorporated into the
DNA when the cell repairs the break.
Would this work in organisms besides bacteria? "I knew it was like
firing a starting gun in a race," Doudna said, but sure enough, by early
2013 scientists had shown it would work in human cells, and those of many other
animals and plants, even though these species are not known to have
CRISPR-based immune systems.
"I don't know any species of plant or animal where it has been
tried and it failed," said George Church, a professor of genetics at
Harvard Medical School. "It allows you to do genome engineering on
organisms that are very hard to do otherwise."
In the past, making an animal with multiple genetic changes usually
required creating separate animals with single changes and then crossbreeding
them to produce offspring with multiple changes. With CRISPR, multiple genetic
changes can be made in one step, by putting multiple guide RNAs into the cell.
"It just completely changes the landscape," Doudna said.
Berkeley scientists used to farm out that work to specialized laboratories or
companies. Now, she said, "people are able to make mice in their own
labs."
There are other techniques that can do what CRISPR does, though CRISPR
is "the easiest by far," Church said.
RNA interference, for instance, can silence particular genes. It is
similar to CRISPR in that it also uses RNA that matches the gene to be
silenced.
But RNA interference works by inhibiting messenger RNA, which translates
a gene into a protein. That usually provides only a partial and temporary
disabling of the gene, because the cell can make new messenger RNA. CRISPR
disables the gene itself, potentially a more complete and permanent
inactivation.
There are also ways to change genes, namely zinc-finger nucleases and
transcription activator-like effector nucleases, or TALENs. The biotechnology
company Sangamo BioSciences is conducting a clinical trial of a treatment for
HIV that uses zinc fingers to alter patients' immune cells to make them
resistant to the virus.
Both techniques use proteins to guide where the DNA is cut; it is more difficult
to develop a protein that binds to a specific DNA sequence than it is to make a
piece of RNA with the matching sequence.
With zinc fingers "it might take you months or years to get
something to work well for one gene," said Gersbach at Duke. With CRISPR,
"it takes days to weeks."
Quick is not always accurate, however. While CRISPR is generally
precise, it can have off-target effects, cutting DNA at places where the
sequence is similar but not identical to that of the guide RNA.
CRISPR "may not yet have adequate specificity to completely
displace" the older techniques, Dana Carroll, a biochemistry professor at
the University of Utah, wrote in a commentary in Nature Biotechnology in
September.
Still, scientists are figuring out how to make CRISPR more specific.
Another obstacle for treating diseases will be the delivery of the
genetic changes to all the cells in the body that need it.
For some diseases, it may be possible to extract blood stem cells from
the body, alter them using CRISPR, and put them back. If that is not possible,
the DNA needed to make Cas9, the guide RNA and the corrective patch might be
put into a disabled virus. This technique is used for gene therapy, but does
not always work well.
It is likely to be a few years before CRISPR is tested in people. For
now, there is a lot more to learn about it.
Chase L. Beisel at North Carolina State reported that CRISPR could be
used to kill one strain of bacteria in a mixture of strains, by targeting a
sequence unique to that strain. That might one day lead to antibiotics that can
kill the bad bugs without also killing the good ones.
David S. Weiss of Emory University found that some bacteria use Cas9 to
silence one of their own genes, rather than that of a virus, to help them evade
detection by their host's immune system.
The pace of new discoveries and applications is dizzying. "All of
this has basically happened in a year," Weiss said. "It's
incredible."
SOURCE
By New York Times
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