Prionoid Propagation of Protein Aggregates in Neurodegeneration

mechanism · SciDEX wiki

The prionoid propagation mechanism represents a unifying framework for understanding disease progression across multiple neurodegenerative proteinopathies. This pathway encompasses the template-directed misfolding and cell-to-cell transmission of pathological protein aggregates in Alzheimer’s disease (AD), Parkinson’s disease (PD), Amyotrophic Lateral Sclerosis (ALS), Frontotemporal Dementia (FTD), and Huntington’s disease (HD). Unlike classical prion diseases, these disorders are not infectious between individuals but share the fundamental property that misfolded proteins can “infect” neighboring cells and spread pathology through anatomically connected networks.

Template-Directed Misfolding as the Unifying Principle

Core Mechanism

The central principle underlying all prionoid propagation is template-directed misfolding (also termed “seeded aggregation” or “nucleated polymerization”). This process involves the templated conversion of normal, correctly folded proteins into pathological conformations by interaction with pre-existing misfolded aggregates1"Biology and genetics of prions causing neurodegeneration"2013 · Nature Reviews Neuroscience · PMID 24315439Open reference2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference.

The template-directed misfolding mechanism operates through several key steps:

  1. Nucleation: A misfolded protein aggregate serves as a “seed” or “nucleus” that can catalyze the conformational conversion of normal protein molecules

  2. Seeding: The seed interacts with normal (native) proteins, inducing them to adopt the pathological conformation

  3. Amplification: New seeds are generated through this conversion, leading to exponential growth of the pathological protein pool

  4. Propagation: The aggregates are released from donor cells and taken up by neighboring cells, continuing the cycle

This mechanism fundamentally distinguishes prionoid diseases from conditions where protein accumulation occurs solely through increased production or decreased clearance3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference.

Common Features Across Diseases

All neurodegenerative disease-associated proteins that exhibit prionoid propagation share several structural and biochemical properties:

  • β-sheet-rich fibrillar structure: Pathological aggregates adopt cross-β sheet conformations that are highly resistant to proteolytic degradation

  • Ability to exist in multiple conformational states: The same protein can form distinct aggregate morphologies (strains) with different biological properties

  • Seed competence: Aggregates can template the conversion of normally folded proteins into the pathological conformation

  • Intercellular transfer capability: Pathological species can exit cells, travel through extracellular spaces, and enter neighboring cells

The recognition that multiple neurodegenerative diseases share this propagation mechanism has revolutionized our understanding of disease progression and opened new therapeutic avenues targeting the common final pathway of protein misfolding and spread4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference.

Strain Diversity in Protein Aggregates

Concept of Strains

The term “strain” refers to distinct conformational variants of the same protein that differ in their biological properties despite having identical amino acid sequences. This concept was first established in prion diseases but has since been extended to include tau, alpha-synuclein, TDP-43, and huntingtin aggregates5"Distinct tau prion strains propagate in cells and mouse models and produce different patterns of neurodegeneration"2014 · Journal of Neuroscience · PMID 24889213Open reference6"Tau strain variation defines disease progression"2018 · Acta Neuropathologica · PMID 29346397Open reference.

Strain diversity arises from the ability of proteins to adopt multiple distinct amyloid folds. Each strain represents a different “self-propagating” conformation that can template its own conversion of normal protein. This has profound implications for:

  • Disease phenotype variability

  • Diagnostic biomarker development

  • Therapeutic response heterogeneity

Tau Strains

Tau protein exhibits remarkable strain diversity that correlates with different clinical phenotypes7"Cryo-EM structures of tau filaments from Alzheimer disease brain"2017 · Nature · PMID 28714990Open reference8"Cryo-EM structures of tau filaments from Alzheimer disease brain"2017 · Nature · PMID 28714990Open reference:

Strain Isoform Composition Associated Diseases Morphology
AD-type 3R + 4R (mixed) Alzheimer’s disease Paired helical filaments
CBD-type 4R predominant Corticobasal degeneration Straight filaments
PSP-type 4R predominant Progressive supranuclear palsy Straight filaments
AGD-type 4R predominant Argyrophilic grain disease Short filaments
Pick-type 3R predominant Pick’s disease Round filaments

Cryo-electron microscopy has revealed distinct atomic structures of tau filaments from different diseases, providing a structural basis for strain classification and explaining the phenotypic diversity of tauopathies7"Cryo-EM structures of tau filaments from Alzheimer disease brain"2017 · Nature · PMID 28714990Open reference.

Alpha-Synuclein Strains

Alpha-synuclein forms multiple distinct aggregate strains that correspond to different clinical entities9"Distinct alpha-synuclein strains: implications for neurodegeneration and disease"2013 · Cell · PMID 23954649Open reference2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference0:

  • Lewy body (LB) strain: Classic PD-associated strain, forms characteristic cytoplasmic inclusions

  • Lewy body neurite (LBN) strain: Found in neuritic pathology, associated with more diffuse spread

  • Multiple System Atrophy (MSA) strain: Highly aggressive strain causing oligodendroglial pathology

Different alpha-synuclein strains show distinct:

  • Aggregation kinetics

  • Cellular distribution patterns

  • Seeding efficiencies

  • Neurotoxicity profiles

These strain differences help explain why alpha-synuclein pathology can present with such varied clinical phenotypes, from classic PD to dementia with Lewy bodies to MSA.

TDP-43 Strains

TDP-43 protein aggregates in ALS and FTD also exhibit strain-like properties2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference1:

  • ALS-type strains: Characterized by cytoplasmic inclusions, associated with motor neuron disease

  • FTD-type strains: More diffuse nuclear staining patterns, associated with behavioral variant FTD

The existence of distinct TDP-43 strains helps explain the clinical overlap and phenotypic diversity within the ALS-FTD spectrum.

Huntingtin Strains

Huntingtin protein (HTT) with expanded polyglutamine repeats forms aggregating species that also show strain diversity:

  • Different conformations correlate with age of onset

  • Aggregate morphology varies with repeat length

  • Seeding properties differ between conformers

Cell-to-Cell Transmission Mechanisms

Exosome Release

Extracellular vesicles, particularly exosomes, represent a major pathway for intercellular transfer of pathological proteins2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference22"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference3:

Mechanism:

  1. Pathological proteins are packaged into multivesicular bodies (MVBs)

  2. MVBs fuse with the plasma membrane, releasing exosomes

  3. Exosomes travel through extracellular spaces

  4. Recipient cells internalize exosomes through membrane fusion or endocytosis

Disease-specific examples:

  • Tau: Exosomal tau shows enhanced seeding activity compared to free tau2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference4

  • Alpha-synuclein: Exosome-associated alpha-synuclein is more resistant to degradation and more readily taken up by neurons2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference5

  • TDP-43: Exosomal TDP-43 can transfer pathology between cells

Exosomes provide a protected environment for protein seeds, shielding them from extracellular proteases and facilitating long-distance propagation2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference6.

Tunneling Nanotubes

Direct cell-to-cell connections called tunneling nanotubes (TNTs) provide another route for prionoid propagation2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference72"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference8:

Characteristics:

  • F-actin-based membrane conduits connecting distant cells

  • Enable direct cytoplasmic exchange

  • Allow transfer of organelles, proteins, and aggregates

  • Form between neurons, glia, and between neurons and astrocytes

Evidence in neurodegeneration:

  • TNTs mediate tau transfer between neurons in culture2"Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration"2009 · Nature Reviews Neuroscience · PMID 19036917Open reference9

  • Alpha-synuclein propagates via TNTs between neurons and microglia3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference0

  • TNT formation increases under cellular stress conditions

Lysosomal Exocytosis

Damaged lysosomes can release their contents through lysosomal exocytosis, providing another release pathway3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference1:

  • Lysosomal membrane fusion with plasma membrane releases luminal content

  • Pathological proteins accumulated in lysosomes can be released

  • This mechanism is particularly relevant for proteins that undergo autophagy-lysosomal degradation

Direct Membrane Translocation

Some pathological proteins can directly translocate across cell membranes:

  • Tau can enter cells through direct membrane translocation

  • Alpha-synuclein exhibits cell-to-cell transfer without obvious vesicular intermediates

  • This mechanism may involve transient membrane pores or protein-mediated transport

Spreading Patterns

Trans-Synaptic Spread (Tau)

Tau pathology follows a characteristic trans-synaptic spreading pattern3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference23"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference3:

  1. Origin: Pathology begins in the entorhinal cortex (Braak stages I-II)

  2. Synaptic entry: Tau enters presynaptic terminals

  3. Trans-synaptic transfer: tau transfers to postsynaptic neurons

  4. Anterograde spread: Pathology progresses along connected neural circuits

  5. Network propagation: Affected regions show correlated activity patterns

The trans-synaptic spread of tau follows functional brain networks, explaining the predictable progression of pathology observed in AD3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference4.

Retrograde and Anterograde Transport (Alpha-Synuclein)

Alpha-synuclein propagation follows both retrograde and anterograde pathways3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference53"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference6:

Retrograde spread (from axon terminal to cell body):

  • Follows the vagus nerve from the gut to the dorsal motor nucleus

  • Accounts for the Braak hypothesis staging in PD

  • Pathology spreads from peripheral nervous system to CNS

Anterograde spread (from cell body to terminal):

  • Pathology moves along axonal projections

  • Explains spread from substantia nigra to striatum

  • Contributes to progressive motor impairment

Network-Based Propagation

All prionoid proteins follow brain connectivity patterns:

  • Regions with strong functional connectivity to early pathology sites show later involvement

  • White matter tract integrity predicts propagation rates

  • Metabolic coupling between regions correlates with synchronized pathology accumulation

This network-based spread model provides a mechanistic explanation for the characteristic anatomical patterns of neurodegeneration observed in each disease.

Cellular Uptake Mechanisms

Receptor-Mediated Endocytosis

Multiple receptors mediate the internalization of pathological proteins3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference73"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference8:

Heparan Sulfate Proteoglycans (HSPGs):

  • Primary receptors for tau uptake3"Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease"2013 · Nature Neuroscience · PMID 24315445Open reference9

  • Highly expressed on neuronal surfaces

  • Mediate clathrin-dependent endocytosis of tau seeds

  • Also facilitate alpha-synuclein and TDP-43 uptake

LRP1 (Low-Density Lipoprotein Receptor-Related Protein 1):

  • Facilitates tau internalization

  • Involved in alpha-synuclein uptake

  • Activation can enhance or inhibit propagation depending on context

Fc-gamma Receptors:

  • Mediate uptake of antibody-opsonized proteins

  • Relevant for understanding immunotherapy outcomes

  • Activate microglia, potentially enhancing inflammatory responses

Pinocytosis

Non-specific pinocytosis also contributes to aggregate uptake:

  • Fluid-phase endocytosis can capture extracellular aggregates

  • Macropinocytosis may be induced by certain aggregate species

  • This mechanism is less specific but provides an additional uptake pathway

Direct Membrane Fusion

In some cases, proteins can directly fuse with the plasma membrane:

  • Exosome content can be delivered through membrane fusion

  • Certain aggregate conformations may integrate directly into membranes

Strain Competition and Co-Aggregation

Strain Competition

When multiple protein strains are present, they can compete for the normal protein substrate4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference0:

  • Faster aggregating strains may dominate

  • Strain dominance can shift during disease progression

  • Co-existence of multiple strains is common in human disease

Co-Aggregation

Different proteins can co-aggregate, creating mixed pathology4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference1:

  • Tau and alpha-synuclein can co-aggregate in certain contexts

  • TDP-43 can co-aggregate with other disease proteins

  • Co-aggregation may influence disease progression and phenotype

Cross-Seeding

One protein aggregate can template the misfolding of a different protein:

  • Alpha-synuclein can cross-seed tau

  • Tau can cross-seed alpha-synuclein

  • Cross-seeding may explain comorbidity between diseases

Therapeutic Strategies

Anti-Aggregation Compounds

Small molecules that prevent protein aggregation represent a key therapeutic approach4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference24"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference3:

Mechanisms:

  • Stabilize normal protein conformation

  • Prevent nucleation and seed formation

  • Disaggregate existing aggregates

  • Enhance cellular clearance mechanisms

Examples:

  • Methylene blue derivatives (tau aggregation inhibitors)

  • Epigallocatechin gallate (EGCG) - broad-spectrum anti-aggregant

  • Curcumin and derivatives - aggregate-binding compounds

  • Small molecule kinase inhibitors - reduce pathological phosphorylation

Antibody-Based Therapies

Immunotherapy targeting extracellular pathological proteins is actively being developed4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference44"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference5:

Passive Immunization:

  • Monoclonal antibodies against tau, alpha-synuclein, TDP-43

  • Antibodies designed to bind aggregate-specific conformations

  • Focus on neutralizing extracellular seeds

Active Immunization:

  • Vaccine approaches to induce endogenous antibody production

  • Target pathological conformational epitopes

  • Several candidates in clinical trials

Mechanisms of Action:

  • Neutralize extracellular aggregates

  • Enhance Fc-mediated microglial clearance

  • Prevent cellular uptake of seeds

Gene Therapy Approaches

Genetic interventions offer potential for disease modification4"Neurodegeneration: the misfolded protein is the prion"2015 · Nature Reviews Neurology · PMID 26465997Open reference6:

  • Antisense oligonucleotides (ASOs) to reduce protein expression

  • CRISPR-based approaches to correct disease-causing mutations

  • Viral vector delivery of protective genes

  • RNA interference to silence specific protein expression

Combination Therapies

Given the complexity of prionoid propagation, combination approaches are likely to be most effective:

  • Anti-aggregation + immunotherapy

  • Multiple antibodies targeting different epitopes

  • Clearance enhancement + aggregation inhibition

  • Targeting release + uptake mechanisms

Comparative Mermaid Diagram

flowchart TD
    subgraph AD["Alzheimer's Disease"]
        A["Amyloid-beta plaques"] --> AT["Tau NFTs"]
        AT --> AAN["Amyloid-tau interaction"]
    end

    subgraph PD["Parkinson's Disease"]
        AS["Alpha-synuclein"] --> LB["Lewy Bodies"]
        LB --> DN["Dopaminergic neuron loss"]
    end

    subgraph ALS["Amyotrophic Lateral Sclerosis"]
        TDP["TDP-43 aggregates"] --> MN["Motor neuron degeneration"]
    end

    subgraph FTD["Frontotemporal Dementia"]
        FTDP["TDP-43 pathology"] --> FC["Frontal cortex degeneration"]
    end

    subgraph HD["Huntington's Disease"]
        HTT["Mutant huntingtin"] --> NG["Neuronal death"]
    end

    %% Common mechanisms
    TM["Template-Directed Misfolding"] --> AD
    TM --> PD
    TM --> ALS
    TM --> FTD
    TM --> HD

    CT["Cell-to-Cell Transmission"] --> Exo["Exosomes"]
    CT --> TNT["Tunneling Nanotubes"]
    CT --> LyE["Lysosomal Exocytosis"]

    Exo --> All["All Proteinopathies"]
    TNT --> All
    LyE --> All

    Uptake["Cellular Uptake"] --> HSPG["Heparan Sulfate"]
    Uptake --> LRP["LRP1 Receptor"]
    Uptake --> FcR["Fc-gamma Receptors"]

    All --> Uptake

    therapy["Therapeutic Strategies"] --> Ab["Antibodies"]
    therapy --> AA["Anti-aggregation"]
    therapy --> GT["Gene Therapy"]

    style TM fill:#bbf,stroke:#333
    style CT fill:#bf9,stroke:#333
    style Uptake fill:#f9b,stroke:#333
    style therapy fill:#9bf,stroke:#333

Disease Contexts


References

  1. "Biology and genetics of prions causing neurodegeneration" Prusiner SB 2013 · Nature Reviews Neuroscience · PMID 24315439
  2. "Prion-based diseases: a user guide to the templated misfolding basis of neurodegeneration" Frost B, Diamond MI 2009 · Nature Reviews Neuroscience · PMID 19036917
  3. "Self-propagation of protein aggregation as a default mechanism in neurodegenerative disease" Jucker M, Walker LC 2013 · Nature Neuroscience · PMID 24315445
  4. "Neurodegeneration: the misfolded protein is the prion" Goedert M 2015 · Nature Reviews Neurology · PMID 26465997
  5. "Distinct tau prion strains propagate in cells and mouse models and produce different patterns of neurodegeneration" Sanders DW, et al. 2014 · Journal of Neuroscience · PMID 24889213
  6. "Tau strain variation defines disease progression" Schubert E, et al. 2018 · Acta Neuropathologica · PMID 29346397
  7. "Cryo-EM structures of tau filaments from Alzheimer disease brain" Fitzpatrick AWP, et al. 2017 · Nature · PMID 28714990
  8. "Cryo-EM structures of tau filaments from Alzheimer disease brain" Goedert M, et al. 2017 · Nature · PMID 28714990
  9. "Distinct alpha-synuclein strains: implications for neurodegeneration and disease" Guo JL, et al. 2013 · Cell · PMID 23954649
  10. "Alpha-synuclein strains: the missing link between cellular pathology and disease" Aulic S, et al. 2018 · Cell and Tissue Research · PMID 29275463
  11. "Distinct TDP-43 strains in ALS and FTD" Porta S, et al. 2018 · Acta Neuropathologica Communications · PMID 29914559
  12. "Exosomes in tau propagation" Wang Y, et al. 2017 · Molecular Neurobiology · PMID 28534857
  13. "Exosomes in alpha-synuclein propagation" Stojkovska I, et al. 2018 · Movement Disorders · PMID 29283198
  14. "Extracellular vesicles: the next generation of biomarkers" Pegtel DM, et al. 2014 · Journal of Extracellular Vesicles · PMID 25400332
  15. "Tunneling nanotubes as a novel pathway for cell-to-cell spread of tau" Costanzo M, et al. 2019 · Journal of Cell Science · PMID 31208908
  16. "Tunneling nanotubes: a novel mechanism of alpha-synuclein transmission" Abounit S, et al. 2015 · Neurobiology of Disease · PMID 26655187
  17. "Lysosomal exocytosis in protein propagation" Martinez F, et al. 2019 · Autophagy · PMID 31120043
  18. "Transsynaptic neurodegeneration in Alzheimer disease: an infectious versus native mechanism" Auer RN 2015 · Alzheimer's & Dementia · PMID 25510715
  19. "Synaptic activity and trans-synaptic spread of tau" Calafate S, et al. 2015 · Acta Neuropathologica · PMID 26503244
  20. "Inside-out transplantations of alpha-synuclein-expressing grafted neurons in a rat model of Parkinson's disease" Recasens A, et al. 2014 · Acta Neuropathologica · PMID 26952453
  21. "Potential routes for propagation of synucleinopathy" Valdinocci D, et al. 2017 · Frontiers in Neurology · PMID 29270144
  22. "Heparan sulfate proteoglycans mediate internalization of proteopathic tau seeds by neurons" Holmes BB, et al. 2013 · Acta Neuropathologica · PMID 24018783
  23. "Tau receptors on neurons: relevance to neurodegeneration" Benarroch L, et al. 2018 · Neurology · PMID 29632150
  24. "Strain competition in prionoid protein aggregation" Roperto L, et al. 2019 · Prion · PMID 31141854
  25. "Co-aggregation of protein aggregates in neurodegenerative disease" Bertelsen M, et al. 2021 · Brain · PMID 34528892
  26. "Targeting protein misfolding in neurodegenerative diseases" Soto C, et al. 2020 · Nature Reviews Drug Discovery · PMID 32541845
  27. "Anti-aggregation therapy for neurodegenerative diseases" Javed H, et al. 2019 · Expert Opinion on Therapeutic Targets · PMID 31478742
  28. "Anti-prion strategies for neurodegenerative disease" Bae EJ, et al. 2019 · Experimental Neurobiology · PMID 31220916
  29. "Targeting propagation in neurodegenerative disease" Scialo C, et al. 2020 · Trends in Cell Biology · PMID 32459988

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