The quest to restore neuronal structure: Targeting cytoskeletal proteins in neurodegenerative diseases.
This review synthesizes evidence that cytoskeletal disruption (microtubules, actin, tau, neurofilaments, and α-synuclein) is a shared driver of neurodegeneration and surveys therapeutic approaches—cytoskeletal stabilizers, enhanced clearance, gene therapy/CRISPR, and nanodelivery—along with…
What the AI sees
This review synthesizes evidence that cytoskeletal disruption (microtubules, actin, tau, neurofilaments, and α-synuclein) is a shared driver of neurodegeneration and surveys therapeutic approaches—cytoskeletal stabilizers, enhanced clearance, gene therapy/CRISPR, and nanodelivery—along with…
Research significance
By highlighting actin and α-synuclein-linked cytoskeletal dysfunction and mapping translational strategies and biomarker needs, the chapter identifies actionable pathways and modalities that could be prioritized for Parkinson's drug discovery and combination therapies.
Source abstract
Neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease, amyotrophic lateral sclerosis (ALS), and Huntington's disease are characterized by progressive neuronal dysfunction and loss. A growing body of evidence implicates cytoskeletal disruption as a central pathological mechanism in these conditions. Cytoskeletal proteins, including microtubules, actin filaments, tau, neurofilaments, and alpha-synuclein, not only provide structural integrity but also regulate axonal transport, synaptic connectivity, and neuroplasticity. Its dysfunction will lead to impaired intracellular trafficking, protein aggregation, and neuronal degeneration. This chapter explores clearly about the specific cytoskeletal abnormalities that are evident in major neurodegenerative disorders, highlighting the biological mechanisms such as tauopathy-induced microtubule instability in Alzheimer's, actin cytoskeleton dysregulation in Parkinson's, and neurofilament aggregation in ALS. Current therapeutic strategies aimed at the stabilizing cytoskeletal components, enhancing protein clearance, and restoring transport dynamics are examined, alongside the cutting-edge approaches including the gene therapy, CRISPR/Cas9 editing, and nanotechnology-based delivery systems. Challenges such as limited blood-brain barrier penetration, off-target toxicity, and patient heterogeneity are also discussed with the focus on need for precision medicine. Additionally, we have also explored the future directions that specifically focused on the biomarker development, combination therapies, and strategies to promote neuroregeneration and structural plasticity. Targeting cytoskeletal pathways holds significant promise not only for suppressing the disease progression but also for rebuilding the structural foundation of the nervous system, potentially reversing the neurodegenerative decline.