Message boards : Rosetta@home Science : Design of protein-protein interfaces
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moody Volunteer moderator Project developer Project scientist Send message Joined: 8 Jun 10 Posts: 11 Credit: 88,068 RAC: 0 |
To our awesome Rosetta@Home contributors: At the beginning of 2012 we told you that it looked like eight designed proteins stuck to EED as desired. Further experiments showed us that of our eight initial hits, only two were real, and those two proteins were too weak to be improved with laboratory techniques. We've gone back to the drawing board, using more aggressive modeling techniques to design better binding proteins to mimic Ezh2. It turns out that no known protein structure is similar enough to the Ezh2 binding helix to allow us to simply transplant key amino acids from Ezh2 to a new host protein, as we tried before. What were doing now is making new proteins from scratch that have the exact shape that we need to mimic Ezh2. The "EED" runs you'll now see on Rosetta@Home are structure prediction of designs to see if they have the desired curvature when Rosetta folds them up. Thanks again for all of your donated computer time! For those new to this thread/message board, here is what I wrote previously about the EED project: The second of these interactions involve a protein called EED and another called Ezh2. If you think about DNA as a ladder, then each of our cells has about six billion rungs worth of ladder. In order to keep all of that DNA from getting hopelessly tangled, our cells keep it on little spools, called histones, when not in use. Think of this like a massive film archive. It turns out that there is a lot of DNA that never gets used, so the cells put special flags on those spools (histones) that say something like "never use this section of DNA". EED is a large protein that attaches to those flags and brings along Ezh2, a "flagging machine" for the ride. EED makes sure that Ezh2 adds flags to histones that are supposed to get them, and not to histones carrying DNA the cell actually wants to use. Some cancer cells reduce the amounts of EED or Ezh2 to prevent flagging of DNA regions that they want to use to take over our bodies. Other cancer cells expand the amounts of EED or Ezh2 to flag DNA regions that are getting in the way. Scientists are working hard to better understand how EED, Ezh2, and friends work in normal cells and what goes wrong in cancer cells. Some are trying to develop drugs that prevent Ezh2 from attaching to EED. This means that the drugs have to stick to EED more tightly than Ezh2. Although Ezh2 attaches relatively loosely to a large patch on the surface of EED, their aren't any drugs yet available that do what we want. I'm trying to make proteins that will do the same job. I used Rosetta@home to design a set of proteins that mimic Ezh2 in order to block it from attaching to EED. Just to give you a sense of how much computing I need for a project like this, I submitted just under two million work units to Rosetta@home, and donor's computers ran my protocol just under a billion times to give me about 54 designs to look at, from which fourteen were suitable for testing. This took about a month to run on Rosetta@home. From initial experiments, it looks like eight of the designs stick to EED, and one in particular sticks three times better than the Ezh2 found in our cells. Now I'm working to improve the best design at the lab bench and hope to send it to co-workers for testing in living cells. There's still a lot of work to be done to make sure that everything is working right with this design, but I want to give a big thank-you to all of you who donated your computer time to make this possible! For more information about EED, Ezh2, and related proteins, please visit: Work units for this project carried the word "EED" in their name. |
proxima Send message Joined: 9 Dec 05 Posts: 44 Credit: 4,148,186 RAC: 0 |
Thanks for this totally inspiring update (I'm a recent returnee to R@H after a spell on another project). While reading your update, my over-riding thought is how amazing it is that we (i.e. you, the scientists, or the human race in general) now know all this incredibly complex stuff, that wasn't known a few years ago. Whenever I read these updates about the mechanisms of proteins, bindings, targets, interactions, etc, I'm in awe of the scientific process - and every little new thing that is learned can never be taken away from us; it's a step on the road that will never be undone. I really believe that complete cures will be found one day, and it'll be because of work like this. Told you I found it inspiring. Thanks again for the update. Alver Valley Software Ltd - Contributing ALL our spare computing power to BOINC, 24x365. |
Tom Zolotor Send message Joined: 28 Apr 11 Posts: 11 Credit: 229,688 RAC: 0 |
To all of our wonderful Rosetta@Home contributors, They are gearing up to test MB17 in real cancer cells so we'll keep our fingers crossed. We'll keep you updated as new developments arise. Any news if the MB17 worked on the cancer cells? |
rochester new york Send message Joined: 2 Jul 06 Posts: 2842 Credit: 2,020,043 RAC: 0 |
Hello, |
IPDtechwriter Volunteer moderator Project administrator Project developer Send message Joined: 13 Feb 14 Posts: 21 Credit: 4,161 RAC: 0 |
Hi all - as the IPD/Baker lab technical writer, I will be regularly updating R@home message boards with research updates. I've created a new thread for this (R@h Research Updates) but will also be trying to update project-specific threads such as this one! Computational Design of an Enzyme-Based Protein Inhibitor Computational design of protein-protein interactions to generate new binding proteins for any specified site or surface of interest on a target protein can lead to a number of novel therapeutic and biochemical tools. As an example, in recent work by Sarel and collaborators, novel proteins have been designed to bind to a conserved epitope on influenza hemagglutinin. Computational design of a protein that binds polar surfaces, however, has not been previously accomplished. In a September 2013 paper published in the Journal of Molecular Biology, Procko et al describe the computational design of a protein-based enzyme inhibitor that binds the polar active site of hen egg lysosome (HEL). A hot spot design approach first identified key, conserved interaction residues that contribute to much of the binding energy to HEL within a large interface. Rosetta software then identified a protein scaffold that supported the hot spots while also optimizing contact with surrounding surfaces to obtain a high affinity protein binder. Follow this this link to read more about this exciting work: http://depts.washington.edu/bakerpg/drupal/Computational-design-of-a-protein-based-enzyme-inhibitor-pub |
dcdc Send message Joined: 3 Nov 05 Posts: 1831 Credit: 119,627,225 RAC: 10,243 |
Awesome news :) Does IPD = Institute for Protein Design? |
IPDtechwriter Volunteer moderator Project administrator Project developer Send message Joined: 13 Feb 14 Posts: 21 Credit: 4,161 RAC: 0 |
Awesome news :) Yes! IPD is the Institute for Protein Design. You can find more research updates in the news section of the IPD's website here: http://depts.washington.edu/ipd/ |
moody Volunteer moderator Project developer Project scientist Send message Joined: 8 Jun 10 Posts: 11 Credit: 88,068 RAC: 0 |
Tom, I apologize for the long delay in getting back to you. The top MB17 variants bind Mdm4 (Mdmx) or Mdm2 tightly enough to yank them out of human cells and trigger the self-destruction pathway (p53 apoptosis pathway) in colon cancer cells. We're now looking at other types of cancer cells. We're now working on making the MB17 variants bind more tightly to Mdm4 or Mdm2. We're also studying how the p53 pathway works using the MB17 variants. The work is on-going so we don't have the full story yet. MB17 and its variants were intended to aid as cancer research tools and we're cautiously optimistic that they'll work to that end. We're hoping that the things we learn will fuel the development of new kinds of cancer drugs and treatment strategies. You likely have recently seen Rosetta@Home jobs with either Mdm4, Mdm2, or MB17 in the name. These represent ongoing efforts to design improved Mdm4 and Mdm2 binding proteins using new tools in the Rosetta software suite. Once again I want to give a big thank-you to you and all of our Rosetta@Home contributors! _______ [quote]To all of our wonderful Rosetta@Home contributors, They are gearing up to test MB17 in real cancer cells so we'll keep our fingers crossed. We'll keep you updated as new developments arise. Any news if the MB17 worked on the cancer cells? |
John C MacAlister Send message Joined: 6 Dec 10 Posts: 16 Credit: 944,813 RAC: 0 |
Thanks for the update: always good to see our crunching has practical application. |
Doug97 Send message Joined: 19 Oct 14 Posts: 1 Credit: 15,261 RAC: 0 |
The top MB17 variants bind Mdm4 (Mdmx) or Mdm2 tightly enough to yank them out of human cells Hi moody, that sounds very exciting - can you expand a bit on how exactly this occurs? |
Rabinovitch Send message Joined: 28 Apr 07 Posts: 28 Credit: 5,439,728 RAC: 0 |
Hi all! Sorry if this is not a right thread to post it, but... Will this article be useful in rosetta's calculations methods? http://www.pnas.org/content/early/2016/07/12/1603929113.abstract From Siberia with love! |
Jim1348 Send message Joined: 19 Jan 06 Posts: 881 Credit: 52,257,545 RAC: 0 |
Will this article be useful in rosetta's calculations methods? It looks like something you might be able to do on a GPU. |
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Design of protein-protein interfaces
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