The trio developed cryo-electron microscopy, which helps see biological molecules frozen in action
Atrio of Swiss, American and British scientists won the 2017 Nobel chemistry prize on Wednesday for developing cryo-electron microscopy, allowing researchers to see biological molecules frozen inaction.
The work by Jacques Dubochet, Joachim Frank and Richard Henderson makes it possible to image proteins and other molecules after freezing them rapidly to preserve their shape, providing a powerful new tool for medical research.
“It's like frames in a movie. Each of these pictures represents a frame and they can be put together into a movie and we can see what the molecules do,“ said Peter Brzezinski, a member of the Nobel committee for chemistry.
The new approach fills a previously blank space by generating images of everything from proteins that cause antibiotic resistance to the surface of the Zika virus. The Royal Swedish Academy of Sciences, which awarded the $1.1 million prize, said the technology had moved biochemistry into a new era.
By freezing biomolecules midmovement, scientists can unravel previously unseen processes a major advance both for basic understanding and the potential development of new drugs. Scottish-born scientist Henderson used an electron microscope to generate a three-dimensional image of a protein at an atomic resolution, showing the potential of the technology. Until then, electron microscopes were only seen as suitable for imaging dead matter, because the powerful electron beam destroyed the shape of biological material.
His breakthrough was further developed by German-born scientist Frank, a US citizen, while Dubochet of Switzerland used rapidly frozen water to preserve the natural shape of the biomolecules.
Frank said cryo-electron microscopy was a boon for medical research, which is increasingly focused on processes inside cells, but it would take time for this to play out and he was taken aback by news of the award.
“The practical use is immense but there is always a long time between the results of fundamental research to make their way into general knowledge and the practice of medicine,“ he told a news briefing by telephone.
“I was overwhelmed. I thought the chances of winning a Nobel prize were miniscule.“
Mapping Zika
The mosquito-borne Zika virus, which was linked to an epidemic of brain-damaged babies in Brazil last year, exemplifies the power of the technology.
As alarm about the outbreak spread, scientists turned tocryo-electron microscopy to generate three-dimensional images of the virus at the atomic level, jump-starting the search for potential drugs and vaccines.
“The use of these methods has completely revolutionised structural biology so everyone now wants to buy this type of equipment and start this type of research, all over the world,“ Johan Aqvist, another Nobel committee member, told Reuters.
Chemistry is the third of this year's Nobel Prizes after the winners of the medicine and physics prizes were announced earlier this week.
The award passed over one of the highest-profile fields of research, the so-called CRISPR-Cas9 gene editing technology that earlier this year allowed US scientists to alter genes in a human embryo to correct a diseasecausing mutation.
The trio developed cryo-electron microscopy, which helps see biological molecules frozen in action
Atrio of Swiss, American and British scientists won the 2017 Nobel chemistry prize on Wednesday for developing cryo-electron microscopy, allowing researchers to see biological molecules frozen inaction.
The work by Jacques Dubochet, Joachim Frank and Richard Henderson makes it possible to image proteins and other molecules after freezing them rapidly to preserve their shape, providing a powerful new tool for medical research.
“It's like frames in a movie. Each of these pictures represents a frame and they can be put together into a movie and we can see what the molecules do,“ said Peter Brzezinski, a member of the Nobel committee for chemistry.
The new approach fills a previously blank space by generating images of everything from proteins that cause antibiotic resistance to the surface of the Zika virus. The Royal Swedish Academy of Sciences, which awarded the $1.1 million prize, said the technology had moved biochemistry into a new era.
By freezing biomolecules midmovement, scientists can unravel previously unseen processes a major advance both for basic understanding and the potential development of new drugs. Scottish-born scientist Henderson used an electron microscope to generate a three-dimensional image of a protein at an atomic resolution, showing the potential of the technology. Until then, electron microscopes were only seen as suitable for imaging dead matter, because the powerful electron beam destroyed the shape of biological material.
His breakthrough was further developed by German-born scientist Frank, a US citizen, while Dubochet of Switzerland used rapidly frozen water to preserve the natural shape of the biomolecules.
Frank said cryo-electron microscopy was a boon for medical research, which is increasingly focused on processes inside cells, but it would take time for this to play out and he was taken aback by news of the award.
“The practical use is immense but there is always a long time between the results of fundamental research to make their way into general knowledge and the practice of medicine,“ he told a news briefing by telephone.
“I was overwhelmed. I thought the chances of winning a Nobel prize were miniscule.“
Mapping Zika
The mosquito-borne Zika virus, which was linked to an epidemic of brain-damaged babies in Brazil last year, exemplifies the power of the technology.
As alarm about the outbreak spread, scientists turned tocryo-electron microscopy to generate three-dimensional images of the virus at the atomic level, jump-starting the search for potential drugs and vaccines.
“The use of these methods has completely revolutionised structural biology so everyone now wants to buy this type of equipment and start this type of research, all over the world,“ Johan Aqvist, another Nobel committee member, told Reuters.
Chemistry is the third of this year's Nobel Prizes after the winners of the medicine and physics prizes were announced earlier this week.
The award passed over one of the highest-profile fields of research, the so-called CRISPR-Cas9 gene editing technology that earlier this year allowed US scientists to alter genes in a human embryo to correct a diseasecausing mutation.
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