Lewy body formation in Parkinson’s disease: Scientists propose a new molecular roadmap
Proteins form the building blocks of life, but when they form unusual clumps inside the brain, they raise an alarm that something isn’t right.
A classic example is Lewy bodies (LBs), abnormal clumps composed of the protein α-synuclein, which are considered biomarkers of neurodegenerative diseases such as Parkinson’s disease (PD) and dementia.
A recent study in Communications Biology by a team of Indian researchers examined how Parkinson’s disease–specific variants of α-synuclein behave. Under normal conditions, α-synuclein is largely inert and selective because its sticky, hydrophobic core remains hidden. However, disease-related chemical changes in PD-specific αSyn variants expose the core, turning the protein reactive.
This change allows the protein to trap other cellular proteins early on, driving the formation and growth of LBs in nerve cells—a cascade of events that may trigger Parkinson’s disease.
Based on their observations of molecular pathways, the researchers suggested a new model for Lewy body formation, the Multifactorial Random Disorder Model. These new insights might inform future approaches to prevent or slow LB formation in PD.
The promiscuous protein
LBs are notorious for disrupting brain function, depending on where they appear. When found in the brainstem, they interfere with vital processes, leading to symptoms such as depression, sleep disturbances, unstable blood pressure, and bowel or bladder problems.
If they form in the substantia nigra—a key region of the midbrain—they trigger the classic movement symptoms, such as tremor at rest, slowed movement, and muscle stiffness, which are associated with Parkinson’s disease.
Almost 9 decades after LBs were first identified in 1912, researchers found that the mutations in the protein α-synuclein played a central role in their formation.
The protein is commonly found in neurons and consists of three main parts: a charged front region, a sticky middle section that can drive clumping, and a tail. The strictly middle part is responsible for unwanted protein aggregation, but under normal conditions, it’s quite choosy and doesn’t bind to every protein available.
Studies show that disease-related changes in the cellular environment—such as shifts in ion concentrations or pH—can disrupt these protective interactions, exposing the protein’s sticky core.
Even though α-synuclein is a driving force, it isn’t the only protein LBs are made of. However, most existing models focus only on how α-synuclein clumps together and fail to clarify the molecular steps by which disease-specific forms of α-synuclein drive Lewy body formation.
The researchers in this study used E. coli bacteria to produce different versions of the α-synuclein protein, including healthy and disease-linked variants, some truncated at the C-terminus and others chemically tagged at a specific position (phosphorylation at S129). They conducted a range of tests, including protein aggregation, binding interactions, and protein folding, to examine how the different variants behaved.
They found that while the healthy versions showed no interest in interacting with the 22 different cellular proteins added to the reaction mixture by the researchers, the disease-linked variants bound with high affinity to almost all of them. They behaved like molecular decoys, nonselectively capturing nearby proteins and membrane organelles.
These findings led the team to propose an alternative model for how Parkinson’s disease may progress in the brain.
The new Multifactorial Random Disorder Model suggests that highly reactive, truncated forms of α-synuclein kickstart the process by grabbing nearby cellular components and forming the dense core of a Lewy body. As the structure grows, phosphorylated forms of the protein accumulate at the periphery, helping the Lewy body grow over time.
Understanding the molecular mechanisms behind Lewy body formation can bring us closer to more effective therapies for combating Parkinson’s disease, a condition that impacts millions of lives worldwide.
