HGF / c-Met signaling

What it is

Hepatocyte growth factor (HGF) is a pleiotropic cytokine that activates the c-Met receptor tyrosine kinase — governing cell survival, proliferation, scattering, angiogenesis, and synaptogenesis. The pathway is named after its two founding members and is a recognized target in oncology (c-Met inhibitors are anti-cancer drugs) and, more controversially, in neuroplasticity (via compounds like Dihexa).

Pathway overview

1. HGF pro-protein is secreted as single-chain inactive precursor
2. HGF activation: proteolytic cleavage → two-chain active HGF (α-chain + β-chain)
3. HGF dimerization brings two c-Met receptors together (autophosphorylation)
4. c-Met activation → phosphorylation of cytoplasmic tyrosines
5. Downstream cascades:
   • PI3K/Akt → cell survival, synaptogenesis
   • MAPK/ERK → proliferation, plasticity
   • STAT → gene transcription
   • RAC1/CDC42 → cytoskeletal remodeling (cell scatter)

Why it matters for Vitals

The HGF/c-Met axis is directly relevant to structural neuroplasticity — synaptogenesis, dendritic spine formation, and neural repair. In coaching and wearables logic:

• Synaptogenesis is the structural substrate for memory consolidation
• HGF/c-Met activation may support recovery from neurotoxic insults (alcohol, stimulants)
• The pathway is also angiogenic — relevant to vascular health and tissue repair more broadly
• The oncogenic risk is the primary counterargument: chronic systemic c-Met activation is contraindicated in anyone with cancer risk

Dihexa specifically

Dihexa is not a direct c-Met agonist — this is a critical distinction:

• At 10 pM or 1 nM alone: zero c-Met activation
• Mechanism: allosteric facilitator of HGF dimerization — requires endogenous HGF present
• Kd for HGF: 65 picomolar (extremely high affinity)

This means Dihexa’s effect is conditional on existing HGF levels — not a guaranteed pharmacological effect.

Proof of mechanism (independent):

• Hinge (HGF dimerization antagonist): completely abolishes Dihexa effects
• shRNA c-Met knockdown: Dihexa loses all efficacy
• Wortmannin (PI3K inhibitor): nullified all benefits in APP/PS1 mice

Fosgonimeton (ATH-1017) — human context

• Phosphate prodrug of Dihexa; water-soluble; subcutaneous
• Designed to solve Dihexa’s 13-day half-life problem
• LIFT-AD Phase 2/3 (2024): biomarkers responded (p-tau217 ↓, P<0.01) but behavioral endpoints missed
• Proof of mechanism in humans, but behavioral efficacy not established

ATH-1105 — next generation

• Oral small molecule HGF modulator (not a peptide)
• Pivoted to ALS (after AD/PD failures)
• Phase 1 in healthy volunteers (May 2025): favorable safety signal
• Worth watching as a cleaner future HGF/c-Met option

Cancer risk — the core concern

This is the primary safety issue for any c-Met-activating strategy:

• c-Met is a recognized proto-oncogene — aberrant activation drives hepatocellular carcinoma, breast cancer, NSCLC progression and metastasis
• Oncology has spent decades developing c-Met inhibitors as anti-cancer drugs
• Dihexa activates the same pathway in the opposite direction
• Chronic systemic activation could theoretically accelerate pre-existing micrometastases

The 13-day half-life of Dihexa makes this worse: if tumor promotion is detected, the drug cannot be rapidly cleared.

BPC-157 + Dihexa stacking is particularly concerning:

• BPC-157: pro-angiogenic via VEGF + ECM remodeling → provides vascular supply to tumors
• Dihexa: c-Met “scatter factor” signaling → provides motility for tumor metastasis
• This combination simultaneously provides the two ingredients tumors need for rapid progression

Confidence level

• Mechanism biology: high (well-characterized in oncology and developmental biology)
• Dihexa as HGF facilitator: moderate (preclinical + independent replication; prodrug validated target engagement)
• Human cognitive efficacy via this pathway: low (prodrug failed behavioral endpoints)
• Safety for chronic use: very low (zero human toxicology)

Related notes

• Dihexa — primary anchor; allosteric HGF facilitator
• BPC-157 — pro-angiogenic peptide; stacking risk with c-Met activators
• TB-500 — same vascular/angiogenic concern in combination
• Noopept Semax Selank — other synaptogenesis approaches with different risk profiles