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Fluorescent Protein Research Lands Scientists Nobel Prize

Posted by timothy on from the also-will-change-dinner-forever dept.

Iddo Genuth writes "The Royal Swedish Academy of Sciences has announced three recipients of the Nobel Prize in Chemistry award for 2008: jointly given to Osamu Shimomura, Martin Chalfie and Roger Y. Tsien 'for the discovery and development of the green fluorescent protein, GFP' — a remarkable brightly glowing green fluorescent protein first observed in the beautiful jellyfish, Aequorea victoria, in 1962."

9 of 79 comments (clear)

  1. Re:Damn! by megamerican · · Score: 3, Funny

    I thought my BBQ sauce was going to win the Nobel Prize for Chemistry :(

    Everyone knows that BBQ sauce goes under the peace category.

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  2. Re:Good for them! by virtualXTC · · Score: 3, Interesting

    ...The next prize they will receive will probably be the Ig Nobel Prize in Biology!

    Well, actually considering one of it's uses, I wouldn't be suprised: glowing cats

  3. Re:Well.... by MyLongNickName · · Score: 3, Funny

    You're not even trying, are you?

    Actually, he is very trying.

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  4. Re:Green Eggs and Ham by reverseengineer · · Score: 3, Informative

    The issue is that there is no Nobel in Biology- there are Nobels in Chemistry and in Physiology or Medicine. While there have been some fascinating experiments using GFP to illuminate (sorry) processes in human cells, what these three did probably is not best categorized as a medical advance. It's been pretty common practice, especially in the last couple decades, to consider advances in biochemistry/molecular biology as eligible for the Nobel in Chemistry.

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  5. Re:Good for them! by Anonymous Coward · · Score: 5, Informative

    GFP is without a doubt the most commonly used fluorescent tag. It's the workhorse of biological fluorescence microscopy. Given the tens of thousands of publications that have used it, the Nobel prize is certainly deserved.

    One of the great things about GFP is that it is a protein. So you can engineer an organism to express GFP. In fact you can engineer the fluorescent protein to be bound to whatever protein you want, just by splicing it into the correct place in the genome. So you can basically make any protein glow. So you can track proteins implicated in cell mobility, or vision, or signaling, or cancer, or some other disease, or whatever.

    With modern fluorescent microscopes, you can actually imagine GFP at the single-molecule level. So you can build movies where quite literally you can track individual protein molecules as they move inside a cell. This obviously gives a whole new insight into cellular machinery, and hence everything based on cells (e.g. life and death).

  6. Re:Good for them! by Hatta · · Score: 5, Informative

    It sounds silly, but this is one of the great success stories of pure research. GFP has proved to be an absolutely astounding tool for biologists, one that we'd never have if there weren't people curious enough to ask "why does that jellyfish glow?" and people willing to fund them.

    I'll cite just one example of this protein being used in a completely novel and extremely powerful way. Fluorescent proteins absorb at one wavelength and emit at another longer wavelength. They've fiddled with the GFP sequence to make yellow and red versions that have overlapping spectra. So now you can tag any two proteins of interest in a cell with GFP and YFP. Next you expose them to light that excites GFP. If the two proteins of interest are closely associated there will be an efficient transfer of energy, and you'll see lots of yellow light emitted. If the proteins of interest are not associated, you'll get mostly green light.

    That's right, you can measure the average distance between two proteins with nothing more than 2 fluorescent proteins, a laser and a spectrophotometer. Not only that, but you can do it in a living cell culture, apply pharmaceuticals to the cells and track the change in real time. That's just one of the more amazing uses of GFP, and a great example of why it's so important to fund research with no obvious practical value.

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  7. Re:Good for them! by philspear · · Score: 4, Interesting

    There was a project with the goal to make a mouse that expressed a variety of different fluorophores in it's neurons so that you could tell one neuron from another, watch active processes, and so on.

    The best part is the name: the brainbow mouse

    http://www.wired.com/science/discoveries/multimedia/2007/10/gallery_fluorescentneurons

    http://bioephemera.com/2007/11/13/the-brainbow-mouse/

    http://www.boston.com/news/globe/health_science/articles/2006/11/06/microscope_renaissance/

    I think some of Tsien's work is more interesting, I believe he's made some fluorophores that you can turn on and off, or convert to different colors to identify specific cells, in addition to some dyes which fluoresce only in the presence of calcium.

  8. don't give them the money by sgt+scrub · · Score: 4, Funny

    Hold onto the cash until they successfully splice it into the mosquito's DNA. Glowing mosquito == dead mosquito!

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  9. Re:Good for them! by camperdave · · Score: 4, Funny

    The questions remaining: Can they get blue as well as green and red? Can they be injected into skin cells? Can the glow be controlled by the nervous system? Which tattoo parlour can give me my glow in the dark thought controlled, full color tattoo?

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