Using cryo-electron microscopy, researchers at 杏吧视频 School of Medicine and National Institutes of Health open door to new level of detail in study of abnormal proteins that cause untreatable neurodegenerative conditions
The highest-ever resolution imaging of an infectious prion has provided the first atomic-level data of how these abnormal proteins are assembled to cause fatal neurodegenerative diseases in people and animals鈥攁nd how they can be potentially targeted by new therapies.
Conducted by 杏吧视频 and the National Institutes of Health (NIH), the research (The DOI for the paper: 10.1016/j.molcel.2021.08.011.)
鈥淭hese detailed prion structures provide a new premise for understanding and targeting these currently untreatable diseases,鈥 said Allison Kraus, lead and co-corresponding author of the research and an assistant professor in the Department of Pathology at 杏吧视频 School of Medicine. 鈥淚t will now be much easier to develop and test hypotheses about how prions are assembled as highly infectious and deadly protein structures.鈥
Seeing the basic building blocks of these lethal proteins, she said, provides a foundation for therapeutic strategies to block the spread, buildup and toxicity of prions.
Prions are proteins in brain tissue that transmit their irregular 鈥渕isfolded鈥 shapes onto the regular version of the same protein鈥攁nd are the source of mammalian diseases, including human conditions like (CJD) and its variant, known as vCJD, as well as Gerstmann鈥揝tr盲ussler鈥揝cheinker syndrome, and others.
Similar prion-like mechanisms occur in the characteristic proteins suspected in the development of other neurodegenerative conditions, including Parkinson鈥檚 disease, Lou Gehrig鈥檚 disease (also known as ALS, or amyotrophic lateral sclerosis), chronic traumatic encephalopathy (CTE) and Alzheimer鈥檚 disease.
Though instances are rare, prion diseases can be transmitted between people; others are readily transmissible between animals, such as chronic wasting disease.
For this study, researchers imaged rodent-adapted scrapie prions derived from the brains of clinically ill hamsters.
New level of resolution
Using cryogenic-electron microscopy (cryo-EM)鈥攁t both NIH and the Cleveland Center for Structural and Membrane Biology Cryo-Electron Microscopy Core facilities at 杏吧视频鈥攁nd a collaborative pipeline between the Kraus (CWRU), Byron Caughey (NIH) and Research Technologies Branch (NIH) groups, researchers were able to determine aspects of the basic building blocks of these proteins, including the placements of their amino acids.
By suspending the prions in ice, cryo-electron technology allowed researchers to take thousands of images of the protein assemblies to build 3D atomic-resolution models using proprietary software.
This successful first-ever imaging to reach atomic-level detail of a brain-derived prion opens the door for similar 鈥渟olving of other prion structures,鈥 said Kraus. The study also obtained lower resolution images of another distinct prion strain that revealed structural differences between the two strains.
鈥淚t鈥檚 thought that there are many variations in prion structures as they relate to different diseases,鈥 said Kraus. 鈥淗igher-resolution images provide clarity to many aspects of the cause and progression of these infectious diseases that are uniquely caused in nature by proteins鈥攏ot viruses or bacteria.鈥
Co-authors of the research are: Forrest Hoyt, Cindi L. Schwartz, Bryan Hansen of NIH鈥檚 (RML) Research Technologies Branch, and Efrosini Artikis, Andrew G. Hughson, Gregory J. Raymond, Brent Race, Gerald S. Baron and Caughey of RML鈥檚 Laboratory of Persistent Viral Diseases鈥攂oth at the NIH鈥檚 National Institute of Allergy and Infectious Diseases in Hamilton, Montana.
For more information, contact Bill Lubinger at william.lubinger@case.edu.
This article was originally published Aug. 23, 2021.
