A landmark discovery about how insulin docks on cells could help in the development of improved types of insulin for treating both type 1 and type 2 diabetes.
For the first time, researchers have captured the intricate way in which insulin uses the insulin receptor to bind to the surface of cells. This binding is necessary for the cells to take up sugar from the blood as energy.
The research team was led by the Walter and Eliza Hall Institute and used the Australian Synchrotron in Melbourne, Australia. The study was published today in the journal Nature.
For more than 20 years scientists have been trying to solve the mystery of how insulin binds to the insulin receptor. A research team led by Associate Professor Mike Lawrence, Professor Colin Ward and Dr John Menting have now found the answer.
Associate Professor Lawrence from the institute's Structural Biology division said the team was excited to reveal for the first time a three-dimensional view of insulin bound to its receptor. "Understanding how insulin interacts with the insulin receptor is fundamental to the development of novel insulins for the treatment of diabetes," Associate Professor Lawrence said. "Until now we have not been able to see how these molecules interact with cells. We can now exploit this knowledge to design new insulin medications with improved properties, which is very exciting."
The Australian Synchrotron's MX2 microcrystallography beamline was critical to the project's success. "If we did not have this fantastic facility in Australia and their staff available to help us, we would simply not have been able to complete this project," Associate Professor Lawrence said.
Associate Professor Lawrence assembled an international team of project collaborators, including researchers from Case Western Reserve University, the University of Chicago, the University of York and the Institute of Organic Chemistry and Biochemistry in Prague. "Collaborations in this field are essential," he said. "No one laboratory has all the resources, expertise and experience to take on a project as difficult as this one."
"We have now found that the insulin hormone engages its receptor in a very unusual way," Associate Professor Lawrence said. "Both insulin and its receptor undergo rearrangement as they interact – a piece of insulin folds out and key pieces within the receptor move to engage the insulin hormone. You might call it a 'molecular handshake'."
Australia is facing an increasing epidemic of type 2 diabetes. There are now approximately one million Australians living with diabetes and around 100,000 new diagnoses each year.
"Insulin controls when and how glucose is used in the human body," Associate Professor Lawrence said. "The insulin receptor is a large protein on the surface of cells to which the hormone insulin binds. The generation of new types of insulin have been limited by our inability to see how insulin docks into its receptor in the body.
"Insulin is a key treatment for diabetics, but there are many ways that its properties could potentially be improved," Associate Professor Lawrence said. "This discovery could conceivably lead to new types of insulin that could be given in ways other than injection, or an insulin that has improved properties or longer activity so that it doesn't need to be taken as often. It may also have ramifications for diabetes treatment in developing nations, by creating insulin that is more stable and less likely to degrade when not kept cold, an angle being pursued by our collaborators. Our findings are a new platform for developing these kinds of medications."
Walter and Eliza Hall Institute: http://www.wehi.edu.au/
This press release was posted to serve as a topic for discussion. Please comment below. We try our best to only post press releases that are associated with peer reviewed scientific literature. Critical discussions of the research are appreciated. If you need help finding a link to the original article, please contact us on twitter or via e-mail.
Written 20 years ago, the first algorithm to tap into the ultra-fast potential of quantum computing has been run on a real machine at long last
Shirley Corriher, author of Cookwise: The Hows and Whys of Successful Cooking, has tips on taking the bitter bite out of coffee, and holding onto cabbage's red hue while it's in the pan.
Data originally taken for another reason weaken the case for "dark photons"
Kip Thorne looks into the black hole he helped create and thinks, “Why, of course. That's what it would do.” This particular black hole is a simulation of unprecedented accuracy. It appears to spin at nearly the speed of light, dragging bits of the universe along with it. (That's gravity for you; relativity is superweird.) In theory it was once a star, but instead of fading or exploding, it collapsed like a failed soufflé into a tiny point of inescapable singularity. A glowing ring orbiting the spheroidal maelstrom seems to curve over the top and below the bottom simultaneously.
Apeel Sciences hopes its products, which use natural methods to fend off pests and oxidization, can markedly reduce the amount of produce wasted because of spoilage.
Francis Halzen’s amazing experiment heralds the beginning of a new era in astronomy
First direct detection of dark matter, thought to make up most of the matter in the universe, would be a historic breakthrough
Geologists, climate scientists, ecologists and a lawyer gather in Berlin for talks on whether to rename age of human lifeHumanitys terrifying impact on Earth justifies new Anthropocene epoch
This month in Italy, three judges have a chance to undo the Kafkaesque nightmare that has ensnared some of the country’s top scientists for almost five years. So far it looks doubtful they will. In 2012, seven scientists and engineers were convicted of manslaughter for things they said and did not say in the days
Turkey's eternal fires have remained burning for thousands of years but now the source of the methane that fuels them has been found