For many of the 200,000 patients diagnosed with Parkinson's disease in the United States every year, the diagnosis often occurs only after the appearance of severe symptoms such as tremors or speech difficulties. With the goal of recognizing and treating neurological diseases earlier, researchers are looking for new ways to image biological molecules that indicate disease progression before symptoms appear. One such candidate, and a known hallmark of Parkinson's disease, is the formation of clumps of alpha-synuclein protein, and, while this protein was identified more than 20 years ago, a reliable way to track alpha-synuclein aggregates in the brain has yet to be developed.
Now, a new study published in Chemical Science describes an innovative approach for identifying molecules that can help track the progression of Parkinson's disease. Conducted by researchers in the labs of E. James Petersson, Robert Mach, and Virginia Lee, this proof-of-concept study could change the paradigm for how researchers screen and test new molecules for studying a wide range of neurodegenerative diseases.
Studying these types of protein aggregates requires new tracers, radioactive molecules that clinicians use to image tissues and organs, for positron emission tomography (PET). As a senior researcher in the field of PET tracer development, Mach and his group worked for several years with the Michael J. Fox Foundation to develop an alpha-synuclein tracer, but without data on the protein's structure they were unable to find candidates that were selective enough to be used as a diagnostic tool.
Then, with the first publication of alpha-synuclein's structure and an increase in tools available from the field of computational chemistry, Mach and Petersson started collaborating on developing an alpha-synuclein PET tracer. By combining their respective expertise in radiochemistry and protein engineering, they were able to confirm experimentally where on the alpha-synuclein protein potential tracer molecules were able to bind, crucial information to help them discover and design molecules that would be specific to alpha-synuclein.
In their latest study, the researchers developed a high-throughput computational method, allowing them to screen millions of candidate molecules, to see which ones will bind to the known binding sites on alpha-synuclein. Building off a previously published method, their approach first identifies an "exemplar," a pseudo-molecule that fits perfectly into the binding site of alpha-synuclein. Then, that exemplar is compared to actual molecules that are commercially available to see which ones have a similar structure. The researchers then use other computer programs to help narrow down the list of candidates for testing in the lab.
To evaluate the performance of their screening method, the scientists identified a small subset of 20 promising candidates from the 7 million compounds that were screened and found that two had extremely high binding affinity to alpha-synuclein. The researchers also used mouse brain tissues provided by the Lee group to further validate this new method. The researchers were impressed, and pleasantly surprised, by their success rate, which they attribute to the specific nature of their search method. "There's certainly a bit of luck involved as well," Petersson adds, "Probably the biggest surprise is just how well it worked."
The idea of using the exemplar method to tackle this problem came to first author and Ph.D. graduate John "Jack" Ferrie while he was learning computational chemistry methods at the Institute for Protein Design at the University of Washington as part of a Parkinson's Foundation Summer Fellowship. "The summer fellowship is designed to train students in new methods that can be applied to Parkinson's disease research, and that's exactly what happened here," says Petersson. "The ideas that Jack came back with formed the basis of a big effort in both my lab and Bob Mach's lab to identify PET tracers computationally."
Read more at Science Daily
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