Diverse Variety Of Alpha-Synuclein Proteins Involved In Parkinson’s Disease And MSA
Source: Thailand Medical News Dec 09, 2019 5 years, 2 weeks, 4 days, 9 hours, 42 minutes ago
Both neurodegenerative diseases, Parkinson’s Disease and Multisystem Atrophy (MSA) are associated with the accumulation of alpha-synuclein proteins in the brain. Researchers at the German Center for Neurodegenerative Diseases (DZNE) and the Max Planck Institute for Biophysical Chemistry (MPI-BPC) have investigated the molecular makeup of these protein deposits finding structural diversity. Experts from South Korea, Australia, and Argentina were also involved in the study. The results suggest that Parkinson’s Disease might be related to diverse types of protein aggregates.
Typically, alpha-synuclein are a type of proteins that occurs naturally in the body and are assumed to be involved in signal transmission between neurons. The protein appears both at the cell membrane and solved – floating, so to speak - in the cell’s interior. In addition to these “normal” variants, there are others that manifest in brain diseases. This applies e. g. to Parkinson’s disease and MSA. Both can be associated with various neurological impairments, including movement disorders. In Parkinson’s and MSA alpha-synuclein molecules stick together. As a result, elongated aggregates arise that are deposited inside neurons and other brain cells.
Prof. Markus Zweckstetter, who heads a research group at the DZNE and the MPI-BPC told
Thailand Medical News, “These deposits successively appear in various areas of the brain. They are a disease hallmark. There is evidence that these aggregates are harmful to neurons and promote disease progression.”
These protein deposits represent a potential starting point for medicines. The idea is that drugs might prevent alpha-synuclein molecules from sticking together or dissolve existing aggregates. To identify potential docking sites for agents, data on the aggregates’ fine structure is required. Thus, the question is: What kind of shape (also known as “folding”) do the molecules adopt within the aggregates? So far, information on this topic had been limited to data from laboratory experiments. “Previous studies investigated the molecular structure of aggregates that were synthesized in a test tube. We asked ourselves how well such artificially produced specimens reflect the patient’s situation. That is why we studied aggregates generated from tissue samples from patients,” said Zweckstetter. “We collaborated closely with international partners on this project. In fact, the tissue samples originated in Australia and the aggregates were synthesized in South Korea. We then did the structural studies in Göttingen.”
Protein aggregates from brain samples taken from five deceased Parkinson’s patients and five deceased MSA patients were examined. For comparison, the researchers artificially produced different variants of alpha-synuclein aggregates. For this, they used standard procedures. To compare the structure of the different aggregates, they applied nuclear magnetic resonance spectroscopy and other methods.
Dr. Timo Strohäker, first author of the study, commented on the findings, “We found that aggregated proteins that came from the lab were structurally different to all aggregates generated from patient material. In addition, proteins of MSA patients differed from those of Parkinson’s patients. If one looks at the data more closely, yo
u notice that the proteins of the MSA patients all had a largely similar shape. The proteins of the patients with Parkinson’s were more heterogeneous. When comparing the proteins of individual Parkinson’s patients, there is a certain structural diversity.”
It was found that the alpha-synuclein proteins of all aggregates contain “beta sheets”, which is in line with previous investigations. Accordingly, the molecular backbone is twisted in a way that the proteins are largely two-dimensional. Within the aggregates, the proteins stick together in layers. However, folding does not encompass the whole protein. Each protein also contains areas that are unstructured. Besides, orientation of the beta sheets bears significance. “It is a question of how much of a protein is folded and also how it is folded,” Zweckstetter stated.
However, in the structure of the alpha-synuclein associated with Parkinson’s, there were some significant differences between patients. This might be due to the fact that the course of
Parkinson’s can vary quite considerably between individuals. “The variability of Parkinson’s disease could be related to differences in the folding of aggregated alpha-synuclein. This would be in contrast to the ‘one disease-one strain’ hypothesis, that is to say that Parkinson’s disease is associated with one, clearly defined aggregate form. However, in view of our relatively small sample of five patients, this is just a guess,” said Zweckstetter. “Yet, our results certainly prove that studies with tissue samples from patients are necessary to complement lab experiments in a sensible way.”
Reference : Strohäker et al. (2019) Structural heterogeneity of α-synuclein fibrils amplified from patient brain extracts. Nature Communications. DOI: https://doi.org/10.1038/s41467-019-13564-w