Berkeley Lab scientists have engineered a universal, highly sensitive technique for detecting misfolded proteins in biological fluids. This groundbreaking nanoscience capability could help pinpoint Alzheimer’s in its early stages and enable researchers to discover new therapies for this devastating disease.
When a protein doesn’t fold into its normal shape, it also doesn’t perform its normal functions. This disruption in behavior could lead to proteins that aggregate into plaques or deposits and become toxic to cells. In Alzheimer’s disease, aggregates of a protein called beta-amyloid form in the central nervous system, causing damage to cells in the brain and triggering dementia.
An analytical capability for measuring tiny clusters of these proteins—before irreversible damage occurs—would be a powerful tool in the early detection of Alzheimer’s and other misfolded protein diseases. However, despite significant research efforts, there are currently no diagnostic tools available to selectively detect small-scale aggregates of misfolded proteins in biological fluids, such as blood or spinal fluid.
“This collaboration illustrates how a biomedical problem can also be a nanoscience problem, in which a chemical reagent is needed to recognize partially aggregated proteins,” said Ron Zuckermann, Director of the Biological Nanostructures Facility at the Molecular Foundry, a nanoscience user facility at Berkeley Lab. “We were faced with the challenge of synthesizing a material that’s capable of specifically detecting this aggregated protein and not any of the other proteins in the blood.”