New research could allow our physical behaviour to be used as a secure way of logging in to our computers and smartphones, a team at the University of Oxford say, claiming that they can also detect when a person is drunk or has had sex.

Researchers have identified that every individual creates a unique pattern of physical behaviour including the speed at which they type, the way they move a mouse of the way they hold a phone.

About 500 different behaviours are unique to every individual and, taken together, form what they call "eDNA", or electronically Defined Natural Attributes. Changes in this string of physical behaviour might even be able to signal when someone has taken drugs, had sex, or if they might be susceptible to a heart attack in three months’ time.

"Electronic DNA allows us to see vastly more information about you," says Adrian Neal, who developed the technology while studying for an MSc at the university and is now chief executive of Oxford BioChronometrics.

"Like DNA it is almost impossible to fake, as it is very hard to go online and not be yourself. It is as huge a jump in the amount of information that could be gathered about an individual as the jump from fingerprints to DNA. It is that order of magnitude."

Oxford BioChronometrics is a startup from Oxford University that with the help of Isis Innovation Software Incubator is being transferred into the private sector, or spun out, on 18 July in order to take the commercialisation of the technology to the next stage. Isis Innovation is the technology transfer company of Oxford University. Biochronometrics is the measurement of change in biological behaviour over time.

"It is easy to tell when someone has been taking drugs using this technology," says Neal. "But it would place us in a difficult situation if we did. So it’s best we don’t. We just want to collect the data to make sure that x is who x says they are."

This eDNA will eventually be used to allow an individual to login on any computer or mobile device, Neal explained, by confirming their identity.

David Scheckel, president of Oxford BioChronometrics, says that eDNA would be able to spot whether a click on an advert or a site is from an automated program, or so-called bot, or a real human. "We can hold companies like Google and Facebook to account ,and they know this technology is coming," he said.

Oxford BioChronometrics' own research suggests that 90-92% of clicks on adverts and 95% of logins are actually from bots. Their first product NoMoreCaptchas which stops spam bots from registering and logging on has already quietly been rolled out to 700 companies.

Adrian Neal, a former cryptographic expert, said the eDNA project has its roots in several decades' worth of research including biometrics, which can measure keystrokes or mouse movements, but these were thought to be too insecure to use as a login principle.

As computing power, along with the ability to gather large volumes of information from users, researchers were able to identify much broader and more complex patterns of interaction with their devices.

Prof Chris Mitchell of the Information Security Group at Royal Holloway, is more sceptical that eDNA will reach the mainstream. "Using different factors to prove your identity online is always good," he says, but believes consumers won't be happy to be continuously assessed in this way. "It may also add to the cost and inconvenience of business as companies’ own software will likely have to be rejigged."

"But there will also be resistance by customers if you find your behaviour monitored, a little bit of pushback," he added.

This article originally appeared on guardian.co.uk

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DALLAS (Reuters) - A 57-year-old Texas man who spent 12 years in prison for rape was exonerated on Friday, with legal experts saying his case marked the first time someone has been cleared of a crime by DNA testing that was not requested by the convicted person.

Michael Phillips was released from prison in 2002 and prosecutors said his innocence was proven through a new program by the Dallas County district attorney's office to analyze untested rape kits, even if the defendant does not make a request.

"Untested rape kits should not just sit on a shelf and collect dust. The exoneration continues to expose the past weakness in our criminal justice system,” Dallas County prosecutor Craig Watkins said in a statement.

According to the National Registry of Exonerations, Phillips' case marks the first time in the United States an exoneration of this nature has occurred. The group said the case became the 34th exoneration by the Dallas District Attorney's Conviction Integrity Unit.

Phillips was exonerated at a hearing on Friday. The actual culprit in the 1990 rape of a 16-year-old girl was identified through the DNA testing but cannot be prosecuted because the statute of limitations has expired, officials said.

The man lived in the same motel as Phillips and the victim.

Philips was identified in a lineup by the victim and said his attorney urged him to accept a plea deal because a jury likely would not side with a black man accused of raping a white teenage girl, the National Registry of Exonerations said.

After his release in 2002, he spent an additional six months in jail for failing to register as a sex offender. During that time, Philips challenged his conviction in court but when that failed, he gave up trying to clear his name.

He has been living in a nursing home, wheelchair bound from sickle-cell anemia.

"I never imagined I would live to see my name cleared. I always told everyone I was innocent and now people will finally believe me,” Phillips said in a statement.

Under Texas law, Phillips is entitled to $80,000 compensation for each year of wrongful conviction plus an additional $80,000 each year for life.

(Reporting by Jon Herskovitz; Editing by Bill Trott)

SEE ALSO: In A Record Year For Exonerations, This Bar Owner Has One Of The Most Outrageous Stories Of All

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A virus that lives in the human gut has just been discovered, and to the surprise of scientists, it can be found in about half the world's population, according to a new study.

While it's not yet clear exactly what the virus does, scientists are eager to find out whether it promotes health or influences susceptibility to certain conditions, said Robert Edwards, a bioinformatics professor at San Diego State University and one of the researchers who worked on the study.

The researchers first uncovered hints of the virus after analyzing DNA from fecal samples of 12 people. They found a cluster of viral DNA that all the samples had in common, Edwards said.

Next, the researchers searched a large database of genetic sequences in samples taken from people living on several different continents, looking for the virus's DNA sequence, and found the virus in 75 percent of samples of human feces. However, some of these samples were from the same person, Edwards said, so after taking this into account, the researchers estimated that the virus is present in about half of all people. [5 Ways Gut Bacteria Affect Your Health]

But how could such a common virus go unnoticed for so long? One of the reasons may be that previously, most researchers compared DNA from current samples only to DNA sequences already known to exist, Edwards said. But in the new study, the researchers first compared the DNA in their samples to one another, looking for common sequences.

"[We] did some different kinds of comparisons, and it jumped right out at us as being something important because it was abundant," told Edwards Live Science.

The new virus, which the researchers have named crAssphage, is a type of virus known as a bacteriophage, meaning it infects bacteria. It's likely that crAssphage infects a very common type of gut bacteria called Bacteroidetes, according to the study.

Although the researchers have shown that the virus DNA exists in nature, they have not yet been able to get the virus to replicate in the lab, or get a picture of it.

"We know it's there, but we can't capture it quite yet," Edwards said.

The researchers think the virus could be involved in controlling the number of Bacteroidetes bacteria in the gut, Edwards said.

The new finding "adds another piece to the puzzle" in helping researchers understand how microbes in the intestine affect human health, said Dr. Amesh Adalja, an infectious disease physician at the University of Pittsburgh and a representative of the Infectious Disease Society of America who was not involved in the study. Much more research will be needed to see how this virus interacts with bacteria in the gut and how it could potentially affect health, he said. "There's definitely a lot of avenues of research that the discovery of this [bacterio]phage will open up," Adalja said.

Adalja noted that just because the virus is common doesn't mean it's benign. "The fact that it's there in so many people means that whatever it's doing is not causing something rare," Adalja said. "But there are enough common conditions that affect humans, that there may be a role there," Adalja said, citing obesity and cancer as examples of such conditions.

The study was published on July 24 in the journal Nature Communications.

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In spite of its looks, this is not the lovechild of an accordion and an earthworm. It is actually a whole new material photographed in the middle of its creation process.

It's a crystalline material being soaked in a special acid solution. After some days of soaking, the pleats in this structure sloughed off. The resulting sheets were so thin, they were actually 2-dimensional—made of just one layer of atoms. They were among the first 2-dimensional polymers ever made by engineers, Chemical & Engineering News reports.

This week, two separate research teams publishedpapers announcing they had made the world's first verified 2-D polymers. The polymer sheets are akin to graphene, a material made of a single layer of carbon atoms. The difference is that polymers are made of atoms of several different elements in a repeating pattern. (In case you're curious, the two teams made polymers of slightly different atomic compositions.) A 2-D polymer has proved to be more difficult to make than sheets of graphene, which can sometimes even flake off the tips of pencils.

Both graphene and 2-D polymers are being studied for similar reasons, C&EN reports. They could do cool things in optics, and their super-tiny pores mean they could be used in high-tech filters. However, 2-D polymers still need work before they can be used in practical applications. For one thing, engineers will have to figure out how to make more of the polymers. Right now, just making a few grams of the stuff is a big feat, as it's taken the scientists years to get the process just right.

Both labs had previously made 2-D polymers, but this is the first time they've determined the exact structure of the polymers, C&EN reports. How were they able to visualize these vanishingly thin structures? They used X-ray crystallography, the same technique Rosalind Franklin used to visualize a single molecule of DNA in 1952. Franklin's X-ray image was crucial to James Watson and Francis Crick's insight into the true structure of DNA.

[Chemical & Engineering News]

This article originally appeared on Popular Science

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Chemotherapy will be obsolete within 20 years, scientists have predicted after launching a landmark project to map 100,000 genomes to find the genes responsible for cancer and rare diseases.

By the time children born today reach adulthood, invasive drugs and their devastating side-effects, will have been replaced by sophisticated medicines that can fix individual faulty genes, according to those behind the project.

Britain is the first country in the world to embark on a program to map the genomes of thousands of people in the hope of finding which genes are responsible.

In a joint £300 million project, universities across Britain are coming together, alongside the Department of Health, the Wellcome Trust, Great Ormond Street Hospital and the Medical Research Council.

David Cameron, the prime minister, said the venture would ‘unlock the power of DNA’ to deliver ‘better tests, better drugs and better care for patients.’

"As our plan becomes a reality, I believe we will be able to transform how devastating diseases are diagnosed and treated in the NHS and across the world,” he said.

The first few hundred pilot participants in London, Cambridge and Newcastle have already donated DNA samples and the project is expected to be completed 2018.

"20 years from now there will be therapies, instead of chemo, that will be a much more targeted approach to treatment,” said Prof Jeremy Farrer, head of the Wellcome Trust.

“We will look back in 20 years time and the blockbuster chemotherapy drugs that gave you all those nasty side effects will be a thing of the past and we will think ‘gosh what an era that was’.

“Understanding humanity’s genetic code is not only going to be fundamental to the medicine of the future. It is essential part of medicine today. In rare congenital disease, in cancer and in infections, genomic insights are already transforming diagnosis and treatment.”

Prof Farrer also predicted that genome sequencing to find the causes of the disease will become standard within our lifetime.

The first human genome was sequenced in 2003 following 13 years of work at a cost of £2 billion. Now it takes around two days and costs just £1,000.

A genome consists of a person’s 20,000 or so genes and the DNA in between. Each genome consists of a code of 3 billion letters.

Over the next four years, about 75,000 patients with cancer and rare diseases, plus their close relatives, will have their whole genetic codes, or genomes, sequenced.

Cancer patients will have the DNA of both healthy and tumor cells mapped, making up the 100,000 total.

Scientists expect the project to be pivotal to the development of future personalized treatments based on genetics, with the potential to revolutionize medicine.

A £78 million partnership between Genomics England, the body set up by the Department of Health to oversee the project, and the Californian DNA sequencing technology company Illumina was unveiled by Mr Cameron today.

Illumina, originally "spun out" by Cambridge University scientists, will invest around £162 million into the project over its lifetime.

By the end of next year that figure is expected to have risen to about 10,000.

Strict confidentiality rules will be enforced and under normal circumstances, patients will not be told of unforeseen surprises that might effect their health - or insurance premiums.

But helpful findings will be fed back to the doctors in charge of their treatment. In return, those consenting to having their DNA sequenced must agree to drug companies having access to the information as well as academic scientists.

One example of such a therapy that already exists is Herceptin, a drug specifically designed for women with a type of breast cancer characterized by over-activity of the Her2 gene. .

Simon Stevens, chief executive of NHS England, said: "The NHS is now set to become one of the world's 'go-to' health services for the development of innovative genomic tests and patient treatments.”

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A new site called SingldOut is taking a unique approach to matchmaking: They're going all the way to your DNA to find you your perfect match.

Jana Bayad and Elle France were tired of all the online dating solutions out there. It was time consuming and energy draining, and at the end of the day, they just weren't finding success.

"I have used probably every website out there [for online dating], and I’ve met really nice people but with no chemistry whatsover, and my goal was not to just meet nice people," Bayad told Business Insider.

So the two women started brainstorming and happened upon a company Instant Chemistry, which claims to measure two individuals' compatibility based on their DNA. Bayad and France went over the research behind Instant Chemistry and decided that it was a foolproof way to give the online dating industry a facelift.

The companies announced an official partnership in July so SingldOut could use the at-home DNA test for its dating solution.

"This science of why two people are attracted to each other is based on 20 years research on the immune system and pheromones and what attracts two people together," Bayad said. "We’re taking that data to bring it to online dating. We’re adding the biological factor because we know that we can determine whether two people wil be attracted to each other or not."

The way it works is that SingldOut users receive a DNA kit, spit in a tube, send it back to the company, and they finally receive a personality assessment. They can then view other SingldOut users' personality assessments to find their perfect match.

According to Bayad, the personality assessment is formed from two sets of genes: immune system genes, as well as the serotonin transporter gene that tells you how you'd react in different situations (whether you're emotional, calm, cool, etc.).

By looking at these specific genes, SingldOut claims to be able to predict whether or not you will have chemistry with someone else.

SingldOut only launched July 7, so they can't say how well their system is working, but they've sent out more than 200 DNA kits and processed 80 so far.

This kind of experimental dating service isn't cheap, however. For a limited time, a year-long membership at SingldOut (including the DNA kit) will cost $129, but after the promotion, six months will cost $249 and three months will cost $199. Instant Chemistry currently sells its standalone kit for $199.

"We’re just on the tip of the iceberg for what DNA can do for relationships," France told Business Insider. "It's come a long way; it’s not just for the Jerry Springer show to find out who your parent is."

SEE ALSO: How The Endless Quest For Love Is Sparking Massive Growth In Dating Apps

SEE ALSO: The CEO Of eHarmony Thinks Dating Apps Like Tinder Are Superficial And Will Never Work

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An amateur detective claims to have solved a century-long mystery with DNA evidence taken from a scarf found at a "Jack the Ripper" murder scene, NBC News reports.

Russell Edwards has a book out on Tuesday that details his findings, appropriately called "Naming Jack The Ripper." The man Edwards identifies — 23-year-old Polish immigrant Aaron Kosminski — is one of six primary suspects commonly named as Jack the Ripper, according to The Guardian.

The murderer known as Jack the Ripper allegedly killed five prostitutes in London's Whitechapel neighborhood in 1888. The murder mystery has never conclusively been solved.

But Kosminski might fit the bill of the killer. He lived in Whitechapel, had a known hostility toward women, and was locked up in an insane asylum a few years after the murders.

Edwards claims DNA on the scarf found at a Jack the Ripper murder scene matches Kominski. He bought the shawl at an auction in 2007 and had a molecular biologist analyze the DNA on it.

Here's a shot of it, via the Daily Mail:

To prove Kosminski's DNA matched that on the scarf, Edwards tracked down living relatives of Kosminski and the victim, according to The Independent. Both DNA sequences reportedly matched samples found on the scarf.

All this has to be taken with several grains of salt.

First, as a source who spoke to The Guardian points out, the scarf has been handled by many people over the years and has not been kept under seal to avoid contamination.

It's also hard to verify the scientist's claims about the DNA because his work has not been published in a peer-reviewed scientific journal, as The Independent notes.

Police never had enough evidence to bring charges against Kominski, but he was widely regarded as the most likely suspect.

SEE ALSO: Here's The Evidence That Convinced A Louisiana Man His Dad Was The Zodiac Killer

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We don't traditionally think of flushing the toilet as an action that costs money. But actually the cost of a flush comes in at about 1 cent. Imagine if sequencing a genome was that easy and cheap? Soon, that could be a reality, according to a leading genome researcher. He predicts we will be sequencing genomes for pennies as soon as 2020.

And when genomes are that cheap to come by, the information they provide will completely revolutionize medicine as we know it.

You'll be able to monitor your health, discover diseases like cancer before they became obvious, and profile your microbiome — all the microorganisms that call your body home. That will allow you to catch potential health problems much earlier than is possible right now and even before symptoms show.

"And I always like to say, also, whenever we flush one of those toilets, we're going to go ahead and analyze everything in there, there'll be a little genome sequencer sitting there," Raymond McAuley predicted in a lecture at Singularity University's Exponential Finance conference in June. And he should know: he's the Biotechnology and Bioinformatics Chair at Singularity University and an advisor to a number of biotechnology companies.

The evolution of the genome sequencer

As of January 2014, sequencing a human genome cost just under $1,000 — less than the cost of a chest X-ray, as McAuley had predicted previously. And the price is only going to fall further. McAuley points out that genome scanning is dropping in cost faster than computers can keep up.

Moore's Law observes that computing power doubles every two years, but the cost of sequencing a genome drops by 5 or 10 times per year, which you can see in the following graph.

Even now, services like 23andMe are able to offer direct-to-consumer genetic testing for $99. These aren't full genome scans, but a partial scan of genetic variations known as single nucleotide polymorphisms, or SNPs. The human genome contains more than 10 million SNPs, of which 23andMe analyzes a few hundred thousand. As technology improves, these kinds of tests should improve with them, and drop in cost. (The $99 price point for 23andMe is somewhat misleading; observers have noted that the individual testing kits are being sold at a loss so the company can amass a database of genetic information.)

Shifting to forward-looking medicine

Once the marginal cost of sequencing and analyzing the all these "omes"— the genome, the exome (the genes that are actively being expressed by any given cell), the microbiome, and so on — become negligible, the stage will be set for truly radical changes to begin.

McAuley sees a shift happening from reactive medicine — our current mode of operating, in which a person gets sick and then goes to a doctor for treatment — to predictive medicine, in which people are screened thoroughly and in advance, perhaps on the day they're born. Such a test might flag any genetic vulnerabilities to rare diseases, predispositions to cancer, provide information on expected longevity, and inform doctors about which medications to use or avoid for a given patient.

We might not even have to wait for a person to be born to screen for chromosomal disorders; invasive amniotic fluid tests, which screen the health of a fetus, will soon be supplanted by a non-invasive blood test that analyzes fetal DNA in the mother's blood.

Similarly, McAuley predicts that mammograms and colonoscopies will be replaced by blood tests powerful enough to catch microscopic tumors, well before cancer has a chance to grow, let alone metastasize. Coupled with genome analysis, this will enable doctors to choose the best form of treatment, ideally rendering long, painful struggles with cancer a thing of the past.

We can even use these tools to sequence the bacteria in and on our bodies: our microbiome. These bacteria, viruses, and fungi impact our health and may even contribute to our moods. We are still learning the roles that the microbiome plays on our health, but as the field advances being able to sequence all these bugs in and on your will be a useful tool in manipulating our health.

What's standing in our way

That all being said, a person's genetic code isn't much use without the tools to analyze it. This is the big problem in genomics right now — we don't have the processing power to deal with all the raw data we are compiling from genome sequencing. The cost of sequencing is falling more than twice as quickly as the cost of computing, so that the cost of sequencing has more to do with data analysis than data collection:You can watch McAuley's entire lecture below. In addition to cheap sequencing, he also talks briefly about the future of lab-grown food and genetic engineering.

READ MORE: What Cheap Genome Sequencing Means For The Future Of Medicine

SEE ALSO: Bacteria Could Provide A Powerful New Way To Fight Fat And Depression

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Maybe you have a fitness tracker. Maybe you've gotten your genome sequenced before. Probably your medical records are kept in electronic, instead of paper, form. Now some companies are seeking to combine all those things and more into a talking, personalized, health-advice app. Not sure when to give yourself your next insulin shot after having a croissant for breakfast? You can ask the app. How much exercise should someone with your genetic makeup be getting? The app will give you suggestions.

At least, that's the goal of the app-makers, who include developers from IBM and a startup called Pathway Genomics. If the app, called Pathway Panorama, works as expected, it will be one of the most detailed and personalized health-advice apps we've ever heard of. It will bring an unprecedented amount of information to bear on the advice it gives you.

Pathway Genomics can sequence your DNA and provide an analysis as to what what those jumbled letters mean. Meanwhile, IBM's artificial intelligence engine, Watson, will make it possible for the app to understand what users are asking it. Watson also is able to read and understand information online, so it will be able to do things like "read" published medical literature to help answer users' questions. After all, that's how Watson won Jeopardy, when IBM first introduced it.

Pathway expects to have the Panorama app ready by mid-2015, according to a blog post by Pathway chief medical officer Michael Nova. Nova didn't offer any pricing details, but said that it would entail a "small monthly fee." The app effort is being funded by IBM, which invested an "undisclosed amount" in Pathway Genomics, Wired reports. The funding is part of IBM's efforts to sell Watson as a multipurpose engine for apps and software.

When Pathway Panorama comes out, it will be interesting to see just how detailed it is. The job of combining genetic test results and a patient's history into health advice has traditionally fallen to highly-trained humans, such as doctors and genetic counselors. Even then, it's a hard job because the science linking genes and health isn't always easy to interpret. How well can a computer program do that? Even if a program is pretty savvy at that task, how much, legally, can it do?

Around this time last year, the U.S. Food and Drug Administration forced the direct-to-consumer genetics-reading company 23andMe to stop giving out health diagnoses. Pathway Genomics' tests are still legal because they require a doctor to order them; it's pretty indisputable that a doctor's office should have the power to order genetics tests. The upcoming app is a different beast, however. The FDA regulates some health apps—ones it considers as offering diagnoses or treatment advice—but it's unclear whether Panorama will fall under the FDA's purview… or what the company may leave out, if it tries to design the app not to require FDA clearance.

This article originally appeared on Popular Science

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NEW YORK (Reuters) - The Nobel Prize gold medal awarded to the U.S. scientist and co-discoverer of DNA, James Watson, sold at auction on Thursday for more than $4.7 million, smashing the world record price for any Nobel prize.

The medal, which Christie's auction house had estimated would sell for anywhere from $2.5 million to as much as $3.5 million, was the first Nobel put on sale by a living recipient.

Christie's did not disclose the buyer, who was bidding via telephone and paid $4,757,000, including commission.

The price and record "demonstrate the growing strength in the market for the iconic pieces related to the early understanding and development of the implications of DNA and its growing relevance today," said Francis Wahlgren, international director of books and manuscripts at Christie's.

Watson, along with Francis Crick and Maurice Wilkins, unraveled the double-helix structure and function of deoxyribonucleic acid (DNA) in Britain in 1953 in a discovery that heralded the modern era of biology.

The scientists received the Nobel Prize for medicine in 1962 for their groundbreaking work in genetics. Watson, 86, said he planned to donate part of the proceeds to charities and to support scientific research.

A letter by Crick to his son sold for $6 million in 2013, setting the world record for any letter sold at auction. The missive, in which Crick outlined the structure of DNA shortly before the discovery was published, sold for more than three times the estimate.

Crick's Nobel medal fetched $2.27 million when it was auctioned last year.

A 1936 Nobel Peace Prize medal sold for $1.1 million last year. It had been awarded to Carlos Saavedra Lamas, foreign minister of Argentina, for his part in ending the Chaco War between Paraguay and Bolivia, and for his work on a South American antiwar pact signed in 1933.

(Reporting by Chris Michaud; Editing by Clarence Fernandez)

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NEW YORK (Reuters) - Speed, smarts, and the heart of a champion: using genomic analysis, scientists have identified DNA changes that helped turn ancient horses such as those in prehistoric cave art into today's Secretariats and Black Beautys, researchers reported Monday.

Understanding the genetic changes involved in equine domestication, which earlier research traced to the wind-swept steppes of Eurasia 5,500 years ago, has long been high on the wish list of evolutionary geneticists because of the important role that taming wild horses played in the development of civilization.

Once merchants, soldiers and explorers could gallop rather than just walk, it revolutionized trade, warfare, the movement of people and the transmission of ideas. It also enabled the development of continent-sized empires such as the Scythians 2,500 years ago in what is now Iran.

It was all made possible by 125 genes, concluded the study in Proceedings of the National Academy of Sciences.

Related to skeletal muscles, balance, coordination, and cardiac strength, they produced traits so desirable that ancient breeders selected horses for them, said geneticist Ludovic Orlando of the Natural History Museum of Denmark, who led the study. The result was generations of horses adapted for chariotry, pulling plows, and racing.

Genes active in the brain also underwent selection. Variants linked to social behavior, learning, fear response, and agreeableness are all more abundant in domesticated horses.

The discovery of the genetic basis for horse domestication was a long time coming because no wild descendants of ancient breeds survive. The closest is the Przewalski's horse. By comparing domesticated species to their wild relatives, scientists figured out how organisms as different as rice, tomatoes and dogs became domesticated.

With no truly wild horses to study, Orlando's team examined DNA from 29 horse bones discovered in the Siberian permafrost and dating from 16,000 and 43,000 years ago, and compared it to DNA from five modern domesticated breeds.

Some genes in today's horses were absent altogether from the ancient ones, showing they arose from recent mutations. Among them: a short-distance "speed gene" that propels every Kentucky Derby winner.

Geneticists not involved in the study suggested that analyzing equine DNA from around the time of domestication, rather than millennia before, might show more clearly what genetic changes occurred as horses were tamed.

"Comparing ancient genomes to modern genomes is tricky," said Arne Ludwig of the Leibniz Institute for Zoo and Wildlife Research in Berlin.

(Reporting by Sharon Begley; Editing by Grant McCool)

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Moscow State University just received Russia's largest-ever scientific grant in a bid to create a veritable "Noah's Ark" containing the DNA of every living and extinct creature on the planet.

The concept is similar to the Svalbard Global Seed Vault in Norway, but Russia's DNA ark would become the world's first database of its kind.

The project is set to be completed by 2018 and, according to reports, it will be 430 square kilometers in size — over 40 times the size of the Svalbard seed vault.

The idea is all the more relevant and pertinent considering how close to extinction several major species are. The Western black rhino has been declared officially extinct, and the Northern white rhino exists in such low numbers that a sustainable population is no longer possible.

In a press release, MSU rector Viktor Sadivnichy said: "I call the project 'Noah’s Ark.' It will involve the creation of a depository — a databank for the storing of every living thing on earth, including not only living, but disappearing and extinct organisms. This is the challenge we have set for ourselves.

"It will enable us to cryogenically freeze and store various cellular materials, which can then reproduce. It will also contain information systems. Not everything needs to be kept in a petri dish."

Samples for this massive database will be gathered from numerous sources including the Botanical Garden, the Anthropological Museum, the Zoological Museum, and others. All of the university's departments will be involved in the research and collation of materials, which will commence straight away thanks to the record-breaking grant of over 1 billion rubles (US$194 million). "If it's realized, this will be a leap in Russian history as the first nation to create an actual Noah's Ark of sorts," the rector said.

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Hidden among all the other announcements in last week's State of the Union address by US President Barack Obama was a promise to fund a new "precision medicine initiative".

The president said it would bring Americans closer to curing illnesses such as cancer and diabetes.

Once funded, the initiative is expected to provide medical researchers with data about the genetic make-up of everyday people.

This data will allow them to undertake research into the genetic causes of common diseases and tailor medicines for them.

Tailoring medicine

Precision medicine describes a new approach to the prevention, diagnosis and treatment of diseases. It helps deliver treatment based on the particular variant of the disease by taking the genetic make-up of the ill person into account.

It's underpinned by two key areas of knowledge that have been building rapidly in the recent past. The first is our understanding of the function of human genes and their role in the development and progression of certain diseases.

And the second is the recognition that diseases characterised – and therefore diagnosed – by a particular set of signs and symptoms may arise through fundamentally different biological mechanisms.

One example of such an illness is cystic fibrosis, for which there's already a treatment based on genetic factors.

An inherited condition, cystic fibrosis results from a deficiency in the performance of an enzyme (the cystic fibrosis transmembrane conductance regulator) responsible for moving chloride into and out of the cells. To date, scientists have observed over 1,900 changes in the single gene that codes for this enzyme.

Of these genetic changes, one is very common with a frequency of 70%, while 20 are less common, with a combined frequency of 15%. The remaining genetic changes are very rare. So you can see why although cystic fibrosis is considered to be just one disease, it can be caused by many different biochemical mechanisms.

Medication developed in 2012 can effectively treat cystic fibrosis in people who have specific genetic changes. But it's estimated these changes are present in only 4% to 5% of cystic fibrosis patients. The medication is ineffective for the others.

Precision medicine is not just about new and better treatments for diseases, it can also provide guidance on how best to apply current treatments through the study of how individual genetics influence the manner in which drugs are absorbed and metabolised. This particular field of precision medicine is called pharmacogenomics.

Technology as the driving force

Precision medicine relies on having ready access to a large amount of information about genes and how they influence health. It's been driven by recent advancements in DNA sequencing technology, which have drastically increased our ability to generate the data needed to derive this information.

The first human genome to be sequenced (completed in 2003) took ten years, two large global consortia and billions of dollars. The brunt of the sequencing work in what was known as the Human Genome Project was performed using Sanger sequencing, a method that involves pushing DNA molecules of varying sizes through a gel using an electric field.

As they move through the gel, the fragments are sorted by size because smaller fragments travel faster than larger ones. The need for these gels is a major limiting factor for this method as only a small number of samples can be sequenced in parallel on any one machine.

But sequencing technology has changed markedly in 12 short years.

Beginning in 2005, new technologies that utilised a different method of DNA sequencing and did not rely on gels as separation media came to market.

Crucially, these technologies could be miniaturised and a single instrument could run multiple samples at the same time.

Instruments using these technologies can sequence between one million and 43 billion DNA fragments at a time, depending on the specific technology used.

With these technologies, the cost and time required to sequence a single genome dropped dramatically, from around US$100 million in 2011 to around US$4,000 today.

This drastic reduction in cost led to a proliferation of projects designed to sequence genomes in ever-increasing numbers.

What comes next?

Precision medicine is still a long way off being the default approach to diagnosis and treatment within regular health-care settings. We still don't know enough about the biological processes that cause disease; we know plenty about what happens when we get sick, but often not how and why.

Sequencing large numbers of genomes – as part of projects that cost millions of dollars and many years to complete – is just the first step towards precision medicine. That data needs to be analysed and compared against the sequence data of healthy and sick people.

Hypotheses need to be posed and tested through big longitudinal studies involving many people before meaningful insights can be made and translated into diagnostic tests, treatments and preventive strategies.

All this requires not just access to genomes but detailed clinical information about people that's routinely collected over time and linked to their genomic sequences.

Another issue that needs to be overcome is the cost of individualised treatments. Drug development is expensive, but the costs are usually offset by the combination of the large number of people who will purchase the new drug and some form of government subsidy.

But precision medicine is designed to develop treatments for smaller numbers of people. Not only does this mean a smaller market across which the cost of drug development needs to be spread, it also means governments may be less likely to offer subsidies. A single year's supply for the cystic fibrosis drug mentioned above, for instance, currently costs more than US$300,000, making it one of the most expensive drugs available in America.

To realise the potential of precision medicine, the driving force behind it needs to shift from technology to clinical practice and improving health service delivery.

Technology has brought us a long way, and no doubt we're not far from another paradigm shift that will allow us to sequence genomes more quickly and cheaply. But it will only ever get us so far.

Only the incorporation of genomics into health care, with robust electronic record systems, will allow for correlation of genomic data with health status. Our focus needs to be on answering real questions about real people's health. And ensuring that national health systems are capable of delivering on the promise of precision medicine.

This article was originally published on The Conversation. Read the original article.

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WASHINGTON (Reuters) - The United States has proposed analyzing genetic information from more than 1 million American volunteers as part of a new initiative to understand human disease and develop medicines targeted to an individual's genetic make-up.

At the heart of the initiative, to be announced on Friday by President Barack Obama, is the creation of a pool of people - healthy and ill, men and women, old and young - who would be studied to learn how genetic variants affect health and disease.

Officials hope genetic data from several hundred thousand participants in ongoing genetic studies would be used, and other volunteers recruited to reach the 1 million total.

The near-term goal is to create more and better treatments for cancer, Dr. Francis Collins, director of the National Institutes of Health (NIH), told reporters on a conference call on Thursday. Longer term, he said, the project would provide information on how to individualize treatment for a range of diseases.

The initial focus on cancer, he said, is due partly to the lethality of the disease and partly because targeted medicine, known also as precision medicine, has made significant advances in cancer, although much more work is needed.

The president has proposed $215 million in his 2016 budget for the initiative. Of that, $130 million would go to the NIH to fund the research cohort and $70 million to NIH's National Cancer Institute to intensify efforts to identify molecular drivers of cancer and apply that knowledge to drug development.

A further $10 million would go to the Food and Drug Administration to develop databases on which to build an appropriate regulatory structure; $5 million would go to the Office of the National Coordinator for Health Information Technology to develop privacy standards and ensure the secure exchange of data.

The effort may raise alarm bells for privacy rights advocates who in the past have questioned the government's ability to guarantee that DNA information is kept anonymous. They have expressed fear participants may become identifiable or face discrimination.

Sequencing 1 million genomes

The funding is not nearly enough to sequence 1 million genomes from scratch. Whole-genome sequencing, though plummeting in price, still costs about $1,000 per genome, Collins said, meaning this component alone would cost $1 billion.

Instead, he said, the national cohort would be assembled both from new volunteers interested in "an opportunity to take part in something historic," and existing cohorts that are already linking genomic data to medical outcomes.

The most ambitious of these is the Million Veteran Program, launched in 2011 by the Department of Veterans Affairs. Aimed at making genomic discoveries and bringing personalized medicine to veterans, it has enrolled more than 300,000 veterans and determined the DNA sequences of about 200,000.

The VA was a pioneer in electronic health records, which it will use to link the genotypes to vets' medical histories.

Academic centers have, with NIH funding, also amassed thousands of genomes and linked them to the risk of disease and other health outcomes. The Electronic Medical Records and Genomics Network, announced by NIH in 2007, aims to combine DNA information on more than 300,000 people and look for connections to diseases as varied as autism, appendicitis, cataracts, diabetes and dementia.

In 2014, Regeneron Pharmaceuticals Inc launched a collaboration with Pennsylvania-based Geisinger Health System to sequence the DNA of 100,000 Geisinger patients and, using their anonymous medical records, look for correlations between genes and disease. The company has finished 50,000 samples, spokeswoman Hala Mirza said.

Perhaps the most audacious effort is by the non-profit Human Longevity Inc, headed by Craig Venter. In 2013 it launched a project to sequence 1 million genomes by 2020. Privately funded, it will be made available to pharmaceutical companies such as Roche Holding AG, with which the institute has a research partnership.

"We're happy to work with them to help move the science," Venter said in an interview, referring to the administration's initiative.

But because of the many regulations surrounding medical privacy and human volunteers, he said, "we can't just mingle databases. It sounds like a naive assumption" if the White House expects existing cohorts to merge into its 1-million-genomes project.

Venter raced the government-funded Human Genome Project to a draw in 2000, sequencing the entire human genome using private funding in less time than it took the public effort.

Altering the regulatory landscape

Collins conceded that mingling the databases would be a challenge but insisted it is doable.

"It is something that can be achieved but obviously there is a lot that needs to be done," he said.

Collating, analyzing and applying all this data to the development of new drugs will require changes to how products are reviewed and approved by health regulators.

Dr. Margaret Hamburg, the FDA's commissioner, said on the conference call that the emerging field of precision medicine "presents a set of new issues for us at FDA." The agency is discussing new ways to approach the review process for personalized medicines and tests, she added.

(Reporting by Toni Clarke in Washington; Editing by Cynthia Osterman)

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British lawmakers in the House of Commons voted Tuesday to allow scientists to create babies from the DNA of three people — a move that could prevent some children from inheriting potentially fatal diseases from their mothers.

The vote in the House of Commons was 382-128 in favor. The bill must next be approved by the House of Lords before becoming law. If so, it would make Britain the first country in the world to allow embryos to be genetically modified.

The controversial techniques — which aim to prevent mothers from passing on inherited diseases — involve altering a human egg or embryo before transferring it into the mother. British law currently forbids any such modification and critics say approving the techniques could lead to the creation of "designer babies."

Defects in the mitochondria can result in diseases including muscular dystrophy, heart, kidney and liver failure and severe muscle weakness.

The technology is completely different from that used to create genetically modified foods, where scientists typically select individual genes to be transferred from one organism into another.

In the House of Commons, health minister Jane Ellison kicked off the debate by urging support for the change.

"This is a bold step to take, but it is a considered and informed step," she said, of the proposed technology to help women with mitochondrial diseases.

Critics, however, say the techniques cross a fundamental scientific boundary, since the changes made to the embryos will be passed on to future generations.

"(This is) about protecting children from the severe health risks of these unnecessary techniques and protecting everyone from the eugenic designer-baby future that will follow from this," said David King, director of the secular watchdog group Human Genetics Alert.

The techniques would likely only be used in about a dozen British women every year who have faulty mitochondria, the energy-producing structures outside a cell's nucleus. To fix that, scientists remove the nucleus DNA from the egg of a prospective mother and insert it into a donor egg from which the nucleus DNA has been removed. This can be done either before or after fertilization.

The resulting embryo would end up with the nucleus DNA from its parents but the mitochondrial DNA from the donor. Scientists say the DNA from the donor egg amounts to less than 1 percent of the resulting embryo's genes.

Last year, the U.S. Food and Drug Administration held a meeting to discuss the techniques and scientists warned it could take decades to determine if they are safe. Experts say the techniques are likely being used elsewhere, such as in China and Japan, but are mostly unregulated.

Rachel Kean, whose aunt suffered from mitochondrial disease and had several miscarriages and stillbirths, said she hoped British politicians would approve the techniques. Kean, an activist for the Muscular Dystrophy Campaign, said her mother is also a carrier of mitochondrial disease and that she herself would like the option one day of having children who won't be affected.

"Knowing that you could bring a child into this world for a short, painful life of suffering is not something I would want to do," she said.

A spokesman for Prime Minister David Cameron said he was a "strong supporter" of the change. Cameron had a severely disabled son, Ivan, who died at age 6 in 2009, from a rare form of epilepsy.

Lisa Jardine, who chaired a review into the techniques conducted by Britain's fertility regulator, said each case will be under close scrutiny and that doctors will track children born using this technique as well as their future offspring. She acknowledged there was still uncertainty about the safety of the novel techniques.

"Every medical procedure ultimately carries a small risk," she said, pointing out that the first baby created using in-vitro fertilization would never have been born if scientists hadn't risked experimenting with unproven methods.

Yet Kean said she understood the opposition to the new technology.

"It's everybody's prerogative to object, due to their own personal beliefs," she said. "But to me the most ethical option is stopping these devastating diseases from causing suffering in the future."

___

Associated Press Writer Jill Lawless contributed to this report.

This article was written by Maria Cheng from The Associated Press and was legally licensed through the NewsCred publisher network.

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This winter, a biotechnology company began offering a whole new service to police departments. Virginia-based Parabon NanoLabs' Snapshot service allows police to send Parabon NanoLabs DNA samples taken from crime scenes. From that DNA, the company reconstructs a guess of what the person's face looks like.

"It's giving investigators new leads," Ellen McRae Greytak, Parabon's director of bioinformatics, tells Popular Science. "The idea of Snapshot is to give investigators a new way to use DNA."

Parabon NanoLabs has worked on 10 cases, each for different U.S. police departments, Greytak says. The first department to release a face prediction publicly is the Columbia, South Carolina, police. The department published this poster made from the DNA of a "person of interest" in the unsolved murder of 25-year-old Candra Alston and her three-year-old daughter in 2011:

In the past few years, researchers have made big strides toward being able to reconstruct people's appearance from their DNA. Parabon NanoLabs isn't the first company to think to offering such services to police. Biotech companies Identitas and Illumina both offer eye and hair color guesses from DNA samples. Parabon NanoLabs seems to be unique in offering an illustrated face estimate. Outside experts say the illustrations are not likely to be accurate, however, based on the research that's been done about the genetics of human faces. Greytak counters that because of proprietary research, Snapshot illustrations are more accurate than one might think—and anyway, they need only to be close enough to jog the memory of a witness. Snapshot hasn't yet been validated by outside groups, which researchers Popular Science talked to believe should be the next step.

The most controversial aspect of Snapshot is its prediction of the shape of a face. Eye color and hair color have been scientifically shown to be fairly predictable already. However, all the scientific literature that's publicly available suggests researchers are only starting to get a handle on how to predict a person's face shape from his genetics. "Based on what the published research shows, I would be very skeptical that at this moment, someone has this knowledge," says Manfred Kayser, a biologist at the Erasmus Medical Center in the Netherlands who developed methods for guessing hair and eye color that Illuminas and other companies use.

What makes face shape much more difficult than hair and eye color? It's controlled by many more genes. Any one gene scientists find that's associated with face shape has only a small effect. Because hair and eye color are controlled by fewer genes, it's easier for scientists to find most of them. Even then, they don't know all. That's why estimates for eye and hair color from DNA come with numbers such as "90 percent confident." Meanwhile, the state of the science for predicting skin color from DNA—another aspect of Snapshot's predictions—is somewhere in between that for eyes and hair and that for face shape.

Greytak agrees Snapshot is not super-precise, nor is the science ready for it to be. "Our goal is not to produce a profile that is perfectly accurate and there is only one person you've ever seen who could match that profile," she says. "Really our goal is to produce something that will look similar enough to a person that it will jog a memory and, at the same time, make it clear which people it is not."

Parabon NanoLabs has done some research that's a bit different from other face-shape studies. For example, they've done big-data-type analyses on 1 million distinctive letters in the human genome, called single nucleotide polymorphisms, or SNPs. They searched for single SNPs, as well as combinations of up to five SNPs, that are associated with different face shapes. Many studies seeking SNPs that affect physical traits look at only single SNPs or pairs of SNPs, but it's thought that most human traits are probably controlled by numerous genes, so Parabon's methods could have a better shot at meaningful associations than similar, past studies. There's a big limitation, however. Computers simply can't test every possible combination; that's too many calculations. For example, there are 170 quadrillion possible three-SNP combinations in a set of 1 million SNPs. So Parabon uses an algorithm to choose some smaller number of combinations, which it believes are most likely to be important, to test.

It's unclear whether Parabon NanoLabs' techniques work better than what's already published, outside researchers say. The company should submit its data for outside groups to check, says Ranajit Chakraborty, a geneticist at the University of North Texas' Health Science Center who has researched DNA forensics. Otherwise, the company is selling an opaque tool that police agencies are using. "We need validation of this because this is the only information they would use to bring you or me under attention," he says.

Greytak says Parabon NanoLabs often validates Snapshot with its clients, who are federal and state law enforcement agencies. The agencies send Parabon NanoLabs DNA samples from people they know. The company generates a face illustration, then the agency sends the company photos of the actual person for comparison. It's a step many agencies go through before deciding to buy Snapshot for a case, Greytak says. Depending on how voluminous and fresh DNA samples are, a Snapshot illustration may cost up to $5,000 per suspect.

So how likely is it that police will start reverse-engineering faces for all the DNA they find on a crime scene? Will Snapshot become, as Greytak hopes, "a key step in investigations"? The answers might depend on the service's cost and how much police trust its science, but not on its legality.

Curious whether there might be restrictions on reverse-engineering suspects' faces, Popular Science contacted David Kaye, a law professor at Pennsylvania State University who specializes in scientific evidence. "Leaving aside the question of whether this can be done accurately, I don't see any issue, frankly," he says. Police are generally allowed to figure out as much as they can from a crime scene, he adds.

This article originally appeared on Popular Science

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The research is expected to fuel moves to categorise obesity as a disability and could change thinking in the UK's National Health Service about how the condition is treated.

Fat genes are to blame for more than a fifth of obesity meaning exercise and dieting are of little use to millions, a new study has found.

The landmark research, published in the journal Nature, is the most precise estimate yet for the percentage of obesity caused by DNA rather than lifestyle and is expected to fuel moves to categorise obesity as a disability.

It could change thinking in the NHS about how the condition is treated, experts suggest.

Current figures suggest about a quarter of adults and one in ten children in Britain are obese and up to £8 billion a year is spent treating obesity and related illnesses.

Researchers from the Genetic Investigation of Anthropometric Traits consortium analysed DNA from more than 300,000 people worldwide to complete the study.

Elizabeth Speliotes, of the University of Michigan, who led the research, told The Times the research clearly showed there was no single gene that drove obesity.

"The large number of genes make it less likely that one solution to beat obesity will work for all and opens the door to possible ways we could use genetic clues to help defeat obesity," she said.

Alistair Hall, professor of medicine at the University of Leeds, who contributed data to the study, added that exercising and eating healthily were still the best protection against becoming fat, but the discovery "could help many people born with a disposition to put on too much weight".

A companion paper, also published in Nature, claimed that women are much more prone than men to genetic quirks that cause fat to accumulate around the waistline rather than the hips, exposing them to a greater risk of type-2 diabetes and cardiovascular trouble.

Out of the 20 areas of DNA linked to fat distribution that affect one sex more than the other, 19 have a stronger effect on women.

The authors suggested that the disparity could be explained by sex hormones.

READ MORE: 6 Huge Health Lies We Tell Ourselves

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On a November evening last year, Jennifer Doudna put on a stylish black evening gown and headed to Hangar One, a building at NASA’s Ames Research Center that was constructed in 1932 to house dirigibles.

Under the looming arches of the hangar, Doudna mingled with celebrities like Benedict Cumberbatch, Cameron Diaz and Jon Hamm before receiving the 2015 Breakthrough Prize in life sciences, an award sponsored by Mark Zuckerberg and other tech billionaires.

Doudna, a biochemist at the University of California, Berkeley, and her collaborator, Emmanuelle Charpentier of the Helmholtz Centre for Infection Research in Germany, each received $3 million for their invention of a potentially revolutionary tool for editing DNA known as CRISPR.

Doudna was not a gray-haired emerita being celebrated for work she did back when dirigibles ruled the sky.

It was only in 2012 that Doudna, Charpentier and their colleagues offered the first demonstration of CRISPR’s potential.

They crafted molecules that could enter a microbe and precisely snip its DNA at a location of the researchers’ choosing.

In January 2013, the scientists went one step further: They cut out a particular piece of DNA in human cells and replaced it with another one.

In the same month, separate teams of scientists at Harvard University and the Broad Institute reported similar success with the gene-editing tool.

A scientific stampede commenced, and in just the past two years, researchers have performed hundreds of experiments on CRISPR. Their results hint that the technique may fundamentally change both medicine and agriculture.

Some scientists have repaired defective DNA in mice, for example, curing them of genetic disorders. Plant scientists have used CRISPR to edit genes in crops, raising hopes that they can engineer a better food supply.

Some researchers are trying to rewrite the genomes of elephants, with the ultimate goal of re-creating a woolly mammoth.

Writing last year in the journal Reproductive Biology and Endocrinology, Motoko Araki and Tetsuya Ishii of Hokkaido University in Japan predicted that doctors will be able to use CRISPR to alter the genes of human embryos "in the immediate future."

Thanks to the speed of CRISPR research, the accolades have come quickly. Last year MIT Technology Review called CRISPR "the biggest biotech discovery of the century."

The Breakthrough Prize is just one of several prominent awards Doudna has won in recent months for her work on CRISPR; National Public Radio recently reported whispers of a possible Nobel in her future.

Even the pharmaceutical industry, which is often slow to embrace new scientific advances, is rushing to get in on the act. New companies developing CRISPR-based medicine are opening their doors.

In January, the pharmaceutical giant Novartis announced that it would be using Doudna’s CRISPR technology for its research into cancer treatments. It plans to edit the genes of immune cells so that they will attack tumors.

But amid all the black-tie galas and patent filings, it’s easy to overlook the most important fact about CRISPR: Nobody actually invented it.

Doudna and other researchers did not pluck the molecules they use for gene editing from thin air. In fact, they stumbled across the CRISPR molecules in nature.

Microbes have been using them to edit their own DNA for millions of years, and today they continue to do so all over the planet, from the bottom of the sea to the recesses of our own bodies.

We’ve barely begun to understand how CRISPR works in the natural world.

Microbes use it as a sophisticated immune system, allowing them to learn to recognize their enemies. Now scientists are discovering that microbes use CRISPR for other jobs as well.

The natural history of CRISPR poses many questions to scientists, for which they don’t have very good answers yet.

But it also holds great promise. Doudna and her colleagues harnessed one type of CRISPR, but scientists are finding a vast menagerie of different types.

Tapping that diversity could lead to more effective gene editing technology, or open the way to applications no one has thought of yet.

"You can imagine that many labs — including our own — are busily looking at other variants and how they work," Doudna said. "So stay tuned."

A Repeat Mystery

The scientists who discovered CRISPR had no way of knowing that they had discovered something so revolutionary. They didn’t even understand what they had found. In 1987, Yoshizumi Ishino and colleagues at Osaka University in Japan published the sequence of a gene called iap belonging to the gut microbe E. coli.

To better understand how the gene worked, the scientists also sequenced some of the DNA surrounding it. They hoped to find spots where proteins landed, turning iap on and off. But instead of a switch, the scientists found something incomprehensible.

If you’ve eaten yogurt or cheese, chances are you’ve eaten CRISPR-ized cells.

Near the iap gene lay five identical segments of DNA. DNA is made up of building blocks called bases, and the five segments were each composed of the same 29 bases.

These repeat sequences were separated from each other by 32-base blocks of DNA, called spacers. Unlike the repeat sequences, each of the spacers had a unique sequence.

This peculiar genetic sandwich didn’t look like anything biologists had found before. When the Japanese researchers published their results, they could only shrug. "The biological significance of these sequences is not known," they wrote.

It was hard to know at the time if the sequences were unique to E. coli, because microbiologists only had crude techniques for deciphering DNA.

But in the 1990s, technological advances allowed them to speed up their sequencing. By the end of the decade, microbiologists could scoop up seawater or soil and quickly sequence much of the DNA in the sample.

This technique — called metagenomics — revealed those strange genetic sandwiches in a staggering number of species of microbes. They became so common that scientists needed a name to talk about them, even if they still didn’t know what the sequences were for.

In 2002, Ruud Jansen of Utrecht University in the Netherlands and colleagues dubbed these sandwiches "clustered regularly interspaced short palindromic repeats"— CRISPR for short.

Jansen’s team noticed something else about CRISPR sequences: They were always accompanied by a collection of genes nearby. They called these genes Cas genes, for CRISPR-associated genes. The genes encoded enzymes that could cut DNA, but no one could say why they did so, or why they always sat next to the CRISPR sequence.

Three years later, three teams of scientists independently noticed something odd about CRISPR spacers. They looked a lot like the DNA of viruses.

"And then the whole thing clicked," said Eugene Koonin.

At the time, Koonin, an evolutionary biologist at the National Center for Biotechnology Information in Bethesda, Md., had been puzzling over CRISPR and Cas genes for a few years. As soon as he learned of the discovery of bits of virus DNA in CRISPR spacers, he realized that microbes were using CRISPR as a weapon against viruses.

Koonin knew that microbes are not passive victims of virus attacks. They have several lines of defense. Koonin thought that CRISPR and Cas enzymes provide one more. In Koonin’s hypothesis, bacteria use Cas enzymes to grab fragments of viral DNA.

They then insert the virus fragments into their own CRISPR sequences. Later, when another virus comes along, the bacteria can use the CRISPR sequence as a cheat sheet to recognize the invader.

Scientists didn’t know enough about the function of CRISPR and Cas enzymes for Koonin to make a detailed hypothesis. But his thinking was provocative enough for a microbiologist named Rodolphe Barrangou to test it.

To Barrangou, Koonin’s idea was not just fascinating, but potentially a huge deal for his employer at the time, the yogurt maker Danisco.

Danisco depended on bacteria to convert milk into yogurt, and sometimes entire cultures would be lost to outbreaks of bacteria-killing viruses. Now Koonin was suggesting that bacteria could use CRISPR as a weapon against these enemies.

To test Koonin’s hypothesis, Barrangou and his colleagues infected the milk-fermenting microbe Streptococcus thermophilus with two strains of viruses.

The viruses killed many of the bacteria, but some survived. When those resistant bacteria multiplied, their descendants turned out to be resistant too. Some genetic change had occurred.

Barrangou and his colleagues found that the bacteria had stuffed DNA fragments from the two viruses into their spacers. When the scientists chopped out the new spacers, the bacteria lost their resistance.

Barrangou, now an associate professor at North Carolina State University, said that this discovery led many manufacturers to select for customized CRISPR sequences in their cultures, so that the bacteria could withstand virus outbreaks. "If you’ve eaten yogurt or cheese, chances are you’ve eaten CRISPR-ized cells," he said.

Cut and Paste

As CRISPR started to give up its secrets, Doudna got curious. She had already made a name for herself as an expert on RNA, a single-stranded cousin to DNA.

Originally, scientists had seen RNA’s main job as a messenger. Cells would make a copy of a gene using RNA, and then use that messenger RNA as a template for building a protein. But Doudna and other scientists illuminated many other jobs that RNA can do, such as acting as sensors or controlling the activity of genes.

In 2007, Blake Wiedenheft joined Doudna’s lab as a postdoctoral researcher, eager to study the structure of Cas enzymes to understand how they worked.

Doudna agreed to the plan — not because she thought CRISPR had any practical value, but just because she thought the chemistry might be cool. "You’re not trying to get to a particular goal, except understanding," she said.

As Wiedenheft, Doudna and their colleagues figured out the structure of Cas enzymes, they began to see how the molecules worked together as a system. When a virus invades a microbe, the host cell grabs a little of the virus’s genetic material, cuts open its own DNA, and inserts the piece of virus DNA into a spacer.

As the CRISPR region fills with virus DNA, it becomes a molecular most-wanted gallery, representing the enemies the microbe has encountered. The microbe can then use this viral DNA to turn Cas enzymes into precision-guided weapons.

The microbe copies the genetic material in each spacer into an RNA molecule. Cas enzymes then take up one of the RNA molecules and cradle it.

Together, the viral RNA and the Cas enzymes drift through the cell. If they encounter genetic material from a virus that matches the CRISPR RNA, the RNA latches on tightly. The Cas enzymes then chop the DNA in two, preventing the virus from replicating.

As CRISPR’s biology emerged, it began to make other microbial defenses look downright primitive. Using CRISPR, microbes could, in effect, program their enzymes to seek out any short sequence of DNA and attack it exclusively.

"Once we understood it as a programmable DNA-cutting enzyme, there was an interesting transition," Doudna said. She and her colleagues realized there might be a very practical use for CRISPR. Doudna recalls thinking, "Oh my gosh, this could be a tool."

It wasn’t the first time a scientist had borrowed a trick from microbes to build a tool. Some microbes defend themselves from invasion by using molecules known as restriction enzymes. The enzymes chop up any DNA that isn’t protected by molecular shields.

The microbes shield their own genes, and then attack the naked DNA of viruses and other parasites. In the 1970s, molecular biologists figured out how to use restriction enzymes to cut DNA, giving birth to the modern biotechnology industry.

In the decades that followed, genetic engineering improved tremendously, but it couldn’t escape a fundamental shortcoming: Restriction enzymes did not evolve to make precise cuts — only to shred foreign DNA.

As a result, scientists who used restriction enzymes for biotechnology had little control over where their enzymes cut open DNA.

The CRISPR-Cas system, Doudna and her colleagues realized, had already evolved to exert just that sort of control.

To create a DNA-cutting tool, Doudna and her colleagues picked out the CRISPR-Cas system from Streptococcus pyogenes, the bacteria that cause strep throat. It was a system they already understood fairly well, having worked out the function of its main enzyme, called Cas9.

Doudna and her colleagues figured out how to supply Cas9 with an RNA molecule that matched a sequence of DNA they wanted to cut. The RNA molecule then guided Cas9 along the DNA to the target site, and then the enzyme made its incision.

Using two Cas9 enzymes, the scientists could make a pair of snips, chopping out any segment of DNA they wanted. They could then coax a cell to stitch a new gene into the open space.

Doudna and her colleagues thus invented a biological version of find-and-replace — one that could work in virtually any species they chose to work on.

As important as these results were, microbiologists were also grappling with even more profound implications of CRISPR. It showed them that microbes had capabilities no one had imagined before.

Before the discovery of CRISPR, all the defenses that microbes were known to use against viruses were simple, one-size-fits-all strategies. Restriction enzymes, for example, will destroy any piece of unprotected DNA. Scientists refer to this style of defense as innate immunity.

We have innate immunity, too, but on top of that, we also use an entirely different immune system to fight pathogens: one that learns about our enemies.

This so-called adaptive immune system is organized around a special set of immune cells that swallow up pathogens and then present fragments of them, called antigens, to other immune cells. If an immune cell binds tightly to an antigen, the cell multiplies.

The process of division adds some random changes to the cell’s antigen receptor genes. In a few cases, the changes alter the receptor in a way that lets it grab the antigen even more tightly. Immune cells with the improved receptor then multiply even more.

This cycle results in an army of immune cells with receptors that can bind quickly and tightly to a particular type of pathogen, making them into precise assassins. Other immune cells produce antibodies that can also grab onto the antigens and help kill the pathogen.

It takes a few days for the adaptive immune system to learn to recognize the measles virus, for instance, and wipe it out. But once the infection is over, we can hold onto these immunological memories. A few immune cells tailored to measles stay with us for our lifetime, ready to attack again.

CRISPR, microbiologists realized, is also an adaptive immune system. It lets microbes learn the signatures of new viruses and remember them.

And while we need a complex network of different cell types and signals to learn to recognize pathogens, a single-celled microbe has all the equipment necessary to learn the same lesson on its own.

But how did microbes develop these abilities? Ever since microbiologists began discovering CRISPR-Cas systems in different species, Koonin and his colleagues have been reconstructing the systems’ evolution.

CRISPR-Cas systems use a huge number of different enzymes, but all of them have one enzyme in common, called Cas1. The job of this universal enzyme is to grab incoming virus DNA and insert it in CRISPR spacers. Recently, Koonin and his colleagues discovered what may be the origin of Cas1 enzymes.

Along with their own genes, microbes carry stretches of DNA called mobile elements that act like parasites. The mobile elements contain genes for enzymes that exist solely to make new copies of their own DNA, cut open their host’s genome, and insert the new copy.

Sometimes mobile elements can jump from one host to another, either by hitching a ride with a virus or by other means, and spread through their new host’s genome.

Koonin and his colleagues discovered that one group of mobile elements, called casposons, makes enzymes that are pretty much identical to Cas1.

In a new paper in Nature Reviews Genetics, Koonin and Mart Krupovic of the Pasteur Institute in Paris argue that the CRISPR-Cas system got its start when mutations transformed casposons from enemies into friends.

Their DNA-cutting enzymes became domesticated, taking on a new function: to store captured virus DNA as part of an immune defense.

While CRISPR may have had a single origin, it has blossomed into a tremendous diversity of molecules. Koonin is convinced that viruses are responsible for this. Once they faced CRISPR’s powerful, precise defense, the viruses evolved evasions.

Their genes changed sequence so that CRISPR couldn’t latch onto them easily. And the viruses also evolved molecules that could block the Cas enzymes. The microbes responded by evolving in their turn. They acquired new strategies for using CRISPR that the viruses couldn’t fight.

Over many thousands of years, in other words, evolution behaved like a natural laboratory, coming up with new recipes for altering DNA.

The Hidden Truth

To Konstantin Severinov, who holds joint appointments at Rutgers University and the Skolkovo Institute of Science and Technology in Russia, these explanations for CRISPR may turn out to be true, but they barely begin to account for its full mystery.

In fact, Severinov questions whether fighting viruses is the chief function of CRISPR. "The immune function may be a red herring," he said.

Severinov’s doubts stem from his research on the spacers of E. coli. He and other researchers have amassed a database of tens of thousands of E. coli spacers, but only a handful of them match any virus known to infect E. coli.

You can’t blame this dearth on our ignorance of E. coli or its viruses, Severinov argues, because they’ve been the workhorses of molecular biology for a century. "That’s kind of mind-boggling," he said.

It’s possible that the spacers came from viruses, but viruses that disappeared thousands of years ago. The microbes kept holding onto the spacers even when they no longer had to face these enemies. Instead, they used CRISPR for other tasks.

Severinov speculates that a CRISPR sequence might act as a kind of genetic bar code. Bacteria that shared the same bar code could recognize each other as relatives and cooperate, while fighting off unrelated populations of bacteria.

But Severinov wouldn’t be surprised if CRISPR also carries out other jobs. Recent experiments have shown that some bacteria use CRISPR to silence their own genes, instead of seeking out the genes of enemies.

By silencing their genes, the bacteria stop making molecules on their surface that are easily detected by our immune system. Without this CRISPR cloaking system, the bacteria would blow their cover and get killed.

"This is a fairly versatile system that can be used for different things," Severinov said, and the balance of all those things may differ from system to system and from species to species.

If scientists can get a better understanding of how CRISPR works in nature, they may gather more of the raw ingredients for technological innovations.

To create a new way to edit DNA, Doudna and her colleagues exploited the CRISPR-Cas system from a single species of bacteria, Streptococcus pyogenes.

There’s no reason to assume that it’s the best system for that application. At Editas, a company based in Cambridge, Massachusetts, scientists have been investigating the Cas9 enzyme made by another species of bacteria, Staphylococcus aureus.

In January, Editas scientists reported that it’s about as efficient at cutting DNA as Cas9 from Streptococcus pyogenes. But it also has some potential advantages, including its small size, which may make it easier to deliver into cells.

To Koonin, these discoveries are just baby steps into the ocean of CRISPR diversity. Scientists are now working out the structure of distantly related versions of Cas9 that seem to behave very differently from the ones we’re now familiar with. "Who knows whether this thing could become even a better tool?" Koonin said.

And as scientists discover more tasks that CRISPR accomplishes in nature, they may be able to mimic those functions, too. Doudna is curious about using CRISPR as a diagnostic tool, searching cells for cancerous mutations, for example. "It’s seek and detect, not seek and destroy," she said.

But having been surprised by CRISPR before, Doudna expects the biggest benefits from these molecules to surprise us yet again. "It makes you wonder what else is out there," she said.

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Google-backed 23andMe won U.S. approval on Thursday to market the first direct-to-consumer genetic test for a mutation that can cause children to inherit Bloom syndrome, a rare disorder that leads to short height, an increased risk of cancer and unusual facial features.

The Food and Drug Administration said it plans to issue a notice to exempt this and other carrier screening tests from the need to win FDA review before being sold. There will be a 30-day period for public comment.

"This action creates the least burdensome regulatory path for autosomal recessive carrier screening tests with similar uses to enter the market," the agency said in a statement, referring to genetic mutations carried by two unaffected parents.

The FDA previously barred Mountain View, California-based 23andMe from marketing a saliva collection kit and personal genome service designed to identify a range of health risks including cancer and heart disease, saying it had not received marketing clearance.

The current approval is for a much narrower slice of the genetic testing market.

"The FDA believes that in many circumstances it is not necessary for consumers to go through a licensed practitioner to have direct access to their personal genetic information," Alberto Gutierrez, director of the FDA's office of in vitro diagnostics and radiological health said in a statement.

"These tests have the potential to provide people with information about possible mutations in their genes that could be passed on to their children," he added.

The company conducted two studies to show that the test is accurate in detecting Bloom syndrome carrier status, the agency said. The test is intended for post-natal carrier screening in adults.

"No test is perfect," the FDA said. "Given the probability of erroneous results and the rarity of these mutations, professional societies typically recommend that only prospective parents with a family history of a genetic disorder undergo carrier screening."

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In 2009, a Maryland county court convicted Glenn Raynor of rape, the verdict hinging on a key piece of evidence: Raynor's DNA samples.

However, Raynor didn't give his DNA willingly.

After he consistently refused to provide any samples to the police, officers snagged a few samples of Raynor's sweat from a chair he had been sitting in during an interrogation session.

The DNA matched DNA found at the crime scene, and the prosecution built their case around that fact, leading to a 100-year prison sentence.

Raynor appealed the decision, saying the DNA evidence shouldn't have been used because it was collected without his consent.

The appeal made it all the way up to the Supreme Court, which on Monday, the court announced that it would not hear the case.

The Supreme Court did not comment on the denial—and to be fair, they get requests to hear a whole lot of cases every year and have to deny a majority of them—their refusal to hear the case means they stand with the lower court’s majority opinion:

We hold that DNA testing of the 13 identifying junk loci within genetic material, not obtained by means of a physical intrusion into the person’s body, is no more a search for purposes of the Fourth Amendment, than is the testing of fingerprints, or the observation of any other identifying feature revealed to the public—visage, apparent age, body type, skin color.

Shedding DNA is an inevitable part of life. Skin cells, hair, and sweat all carry a person's signature code, and they are left virtually everywhere you go.

With this decision, now anything you leave behind can be used as evidence in a court of law—whether you know about it or not.

Byron L. Warnken, who submitted the writ to the Supreme Court on behalf of Raynor, said it's important for the Supreme Court to define how emerging technology fits into the Fourth Amendment.

Warnken said in a news release from February 3: "Rejecting a reasonable expectation of privacy in free citizens' DNA will fundamentally alter the relationship between law enforcement and the general citizenry."

[H/T Ars Technica]

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