This therapeutic strategy targets the prion-like propagation of pathological tau proteins between neurons, a key mechanism driving the spread of tau pathology in Progressive Supranuclear Palsy (PSP) and other 4R-tauopathies. Unlike approaches that target intracellular tau production or aggregation, tau propagation blockers focus on preventing the intercellular transfer of tau seeds that drives the characteristic subcortical progression of PSP. In PSP, tau pathology spreads through connected brainstem and basal ganglia circuits, causing the progressive oculomotor, gait, and cognitive deficits that define the disease. Blocking propagation could preserve remaining neuronal circuits and halt disease progression even if existing tau pathology is not eliminated.[@clawson2016][@goedert2015]
- Primary Target: Extracellular tau species (oligomers, fibrils, exosome-associated tau)
- Secondary Target: Cell surface tau uptake mechanisms (heparan sulfate proteoglycans, LDL receptor family)
- Target Type: Monoclonal antibodies, small molecules blocking tau uptake, exosome secretion inhibitors
- Expression: Pathological tau is expressed in neurons, astrocytes, and oligodendrocytes; misfolded 4R-tau isoforms (2N, 2NT, 2S, 1N) aggregate into PHFs and NFTs
- Localization: Primarily cytosolic in NFTs; secreted via exosomes and direct cell-to-cell transfer
Tau propagation follows a seeded aggregation model where extracellular tau seeds are taken up by recipient cells and template the conversion of normal tau into pathological tau fibrils.[@moreno2016] This prion-like mechanism explains the characteristic spread of tau pathology along connected neural circuits in PSP:
- Neurons release pathological tau via: exosomes, microvesicles, direct synaptic transfer, and necrotic cell death
- PSP tau (predominantly 4R-tau with spliced exon 10) forms distinctive straight filaments (SFs), distinct from paired helical filaments (PHFs) in AD[@goedert2015]
- Extracellular tau travels through interstitial space between neurons
- Tau can be detected in cerebrospinal fluid (CSF) - elevated total tau and phosphorylated tau (p-tau181, p-tau217) serve as biomarkers
- Extracellular tau can be internalized by adjacent neurons through multiple uptake mechanisms[@kaufman2016]
- Heparan sulfate proteoglycans (HSPGs) on neuronal surfaces mediate tau internalization
- LDL receptor-related proteins (LRP1, LRP2) contribute to tau uptake
- Macropinocytosis may also contribute to aggregate internalization
- Internalized tau seeds catalyze conversion of endogenous tau into fibrillar tau
- The conformational templating is specific to the seed's protofilament structure - 4R-tau seeds recruit 4R-tau isoforms selectively
- This explains the isoform specificity observed in different tauopathies[@song2019]
- Newly formed tau becomes available for further release and propagation
- The cycle repeats, spreading pathology through connected networks
- Mechanism: Antibodies bind extracellular tau, preventing uptake and promoting clearance
- Examples: Gosuranemab (anti-tau N-terminus), Tilavonemab (anti-tau mid-region), Semorinemab (anti-tau mid-region)
- Challenge: Antibodies must bind the specific tau conformations relevant to PSP
- Delivery: Intravenous or subcutaneous administration; blood-brain barrier penetration is critical
- Mechanism: Block heparan sulfate or LDL receptor-mediated tau internalization
- Examples: Small molecules interfering with HSPG-tau interaction
- Challenge: Achieving sufficient brain penetration and receptor specificity
- Delivery: Oral administration
- Mechanism: Reduce exosome-mediated tau release from neurons
- Examples: GW4869 (neutral sphingomyelinase inhibitor), ESV-IN-1
- Challenge: Balancing exosome inhibition with normal neuronal function
- Delivery: Potential combination with targeted brain delivery
- Mechanism: While primarily targeting intracellular aggregation, these compounds may also reduce propagation-competent tau species
- Examples: Methylthioninium chloride (TRx0237), APN-1607 (varoglutamstat)
- Challenge: Must reach therapeutic concentrations in brain
- Mechanism: Engineered proteins that bind and sequester extracellular tau
- Examples: Engineered Aβ protein scaffolds with tau-binding domains
- Challenge: Achieving adequate brain distribution
- Delivery: Gene therapy or protein administration
| Disease |
Priority |
Rationale |
| PSP |
10 |
Direct relevance - tau propagation drives subcortical spread; 4R-tauopathy with early propagation |
| CBD |
9 |
4R-tauopathy with similar propagation pattern; corticobasal degeneration |
| AD |
5 |
Tau propagation contributes to disease progression; but 3R/4R mixed tauopathy |
| FTD-tau |
8 |
MAPT mutations cause familial tauopathy; propagation model applies |
| PD |
3 |
Primarily α-synucleinopathy, but tau co-pathology affects progression |
| AGD |
7 |
3R-tauopathy with propagation; argyrophilic grains spread regionally |
Total Priority Score: 42
| Dimension |
Score |
Rationale |
| Novelty |
7 |
Multiple antibody programs in trials; but propagation-specific approaches less validated |
| Mechanistic Rationale |
8 |
Strong mechanistic basis from 15+ years of prion-like propagation research |
| Root-Cause Coverage |
7 |
Addresses propagation, not primary cause of tau misfolding |
| Delivery Feasibility |
6 |
Antibodies achieve adequate BBB penetration challenging; small molecules in development |
| Safety Plausibility |
8 |
Anti-tau antibodies have shown reasonable safety in trials to date |
| Combinability |
8 |
Synergizes with 4R-tau targeting, aggregation inhibitors, and microglia modulators |
| Biomarker Availability |
7 |
CSF p-tau181, p-tau217; PET tau ligands enable patient selection |
| De-risking Path |
7 |
Clear regulatory path with established anti-tau antibody programs |
| Multi-disease Potential |
8 |
Applies to all primary tauopathies including AD, PSP, CBD, FTD |
| Patient Impact |
8 |
Could halt progressive subcortical decline in PSP; high unmet need |
Total Score: 75/100
- Validate extracellular tau species in PSP patient CSF and plasma
- Correlate propagation biomarkers with disease progression
- Test candidate antibodies against PSP-derived tau seeds in vitro
- Select antibodies with optimal PSP tau isoform binding
- Optimize small molecule uptake inhibitors for BBB penetration
- Develop pharmacodynamic markers (extracellular tau reduction)
- Patient enrichment using CSF biomarkers and PET
- Focus on early-stage PSP patients (PSP-Ratings Scale < 40)
- Endpoint: PSP-Rating Scale progression rate
- 4R-Tau Targeting: Synergistic - reduce new tau production while blocking spread
- Aggregation Inhibitors: Additive - clear existing aggregates plus block propagation
- Microglia Modulation: Complementary - reduce inflammatory response to tau
- Neuroprotective: Synergistic when combined with synaptic protectors
| Risk |
Severity |
Likelihood |
Mitigation |
| BBB penetration |
High |
Moderate |
Engineer bispecific antibodies or use small molecules |
| Tau isoform specificity |
Moderate |
Moderate |
Develop PSP-specific antibodies |
| Off-target effects |
Low |
Low |
Local delivery or careful dosing |
| Immunogenicity |
Moderate |
Low |
Humanized antibodies |
-
Short-term (0-12 months):
- Survey current anti-tau antibody trials for PSP-specific programs
- Identify biomarkers for patient enrichment
- Assess existing tau propagation assay availability
-
Medium-term (1-3 years):
- Engage with pharmaceutical partners developing propagation blockers
- Support development of PSP-specific tau seed detection assays
- Explore academic collaborations for novel small molecule inhibitors
-
Long-term (3-5 years):
- Support clinical trial enrollment for propagation blocker trials
- Develop combination therapy protocols with 4R-tau targeting
- Establish real-world evidence registries for PSP patients
- Clavaguera et al., Genesis and spreading of pathological tau (2016)
- Goedert M, Alzheimer's and Parkinson's disease: The prion concept (2015)
- Moreno et al., Pathological tau protein in tauopathies (2016)
- Kaufman et al., Tau prion strains and Alzheimer's disease (2016)
- Sandusky-Beltran et al., Tau propagation in neurodegenerative disease (2019)
- Song et al., Exosome-mediated tau propagation (2019)