FGL Peptide
Mechanism
Research
Stacks
Protocol
Safety
References
Research & Education Only — This guide is intended for educational and research reference purposes only. It does not constitute medical advice, a treatment recommendation, or a dosing protocol. Peptides listed are research compounds not approved for human therapeutic use unless otherwise specified. Always consult a qualified healthcare professional before making changes to any health or supplementation programme. No Nonsense Fitness is an information resource, not a medical provider.

Overview

FGL is a synthetic peptide derived from the second fibronectin type III (FN3) module of the neural cell adhesion molecule (NCAM). Its name comes from the Phe-Gly-Leu sequence motif within that NCAM FN3 domain, a region important for NCAM's homophilic binding and downstream signalling. FGL and related NCAM-mimetic peptides were characterised primarily by the research group of Vladimir Berezin and Elisabeth Bock (University of Copenhagen / Protein Laboratory), with associated development work through Enkam Pharmaceuticals.

This compound sits in a fundamentally different evidence category to most others discussed on this site: human clinical data on FGL peptide specifically does not exist. The published literature is preclinical — rodent and in vitro studies concentrated around the Berezin/Bock Copenhagen research programme — rather than a broad, multi-lab, human-tested field. Nothing in this guide should be read as implying human efficacy or safety.

Clinical & Research Status

Evidence TypeStatus
Human RCTs✗ None identified — no human clinical trial data
Animal Studies✔ Rodent models (primarily memory, synaptic plasticity, neuroprotection)
In Vitro Studies✔ Cell/synaptic signalling studies underpinning proposed mechanism
Regulatory Approval✗ Not approved as a medicine anywhere; research compound only

Mechanism of Action

NCAM (neural cell adhesion molecule) normally mediates cell-cell adhesion between neurons and contributes to synaptic plasticity, neurite outgrowth, and learning and memory processes. Part of this activity occurs via NCAM's FN3 domains transactivating the fibroblast growth factor receptor FGFR1, independent of FGF ligand binding. FGL was designed as a short synthetic peptide mimic of this specific NCAM-FGFR1 interaction — the intent being to activate FGFR1-linked downstream signalling implicated in synaptic plasticity, neurite outgrowth, and neuroprotection without requiring the full NCAM protein. This is the mechanistic rationale described in the foundational preclinical literature; it has not been confirmed in human studies.

Research Areas & Reported Effects

Synaptic Plasticity & Memory (Preclinical, Rodent)

The foundational FGL paper, Cambon K et al. 2004 (Journal of Neuroscience), reported that this synthetic NCAM mimetic peptide promoted synaptogenesis, enhanced presynaptic function, and supported memory consolidation in rodent models, including performance on spatial memory tasks such as the Morris water maze. This preclinical work established FGL's central research rationale as a potential modulator of synaptic plasticity and long-term potentiation (LTP).

Neuroprotection & Neurodegeneration Models (Preclinical)

Separate preclinical work from the Berezin/Bock-affiliated research programme (including work associated with Skibo GG and colleagues) has examined FGL's potential neuroprotective effects in rodent models relevant to ischemia/stroke and neurodegenerative processes, proposing that FGFR1-linked survival signalling underlies any protective effect observed. This remains animal-model research.

Neural Injury & Regeneration (Preclinical)

FGL has also been studied preclinically for its capacity to promote neurite outgrowth, with research interest in peripheral and central nerve injury recovery models, extending from its proposed role as an NCAM-FGFR1 mimetic supporting neurotrophic signalling.

Stress & Cognitive Decline Models (Preclinical)

Klementiev B et al. 2007 examined the NCAM mimetic peptide FGL in the context of chronic stress-induced impairments in a preclinical model, part of a broader preclinical interest in whether FGL administration could ameliorate age-related or lesion-induced memory deficits in rodents.

Research Data Summary

Study / SourceFocusKey Finding
Cambon K et al. 2004, Journal of NeuroscienceSynaptogenesis and memory consolidationFGL promoted synaptogenesis, enhanced presynaptic function, and supported memory consolidation in rodent models
Klementiev B et al. 2007Chronic stress-induced impairment modelPreclinical evidence of FGL effects on stress-related cognitive outcomes in rodents
Berezin V, Bock E et al. (research programme), Journal of Neurochemistry / Neuroscience, 2000sCharacterisation of NCAM mimetic peptides including FGLEstablished structural and mechanistic basis for NCAM-FGFR1 mimetic peptide activity
Skibo GG et al. (Berezin/Bock-affiliated)Preclinical neuroprotection studiesPreliminary rodent/in vitro evidence explored for neuroprotective signalling relevant to FGL's proposed mechanism

All entries above represent preclinical (animal or in vitro) findings. No human trial data exists for FGL peptide to date.

Stack Combinations Studied

  • No stack combinations have been studied for FGL peptide in the published literature — research has used FGL as a standalone experimental compound in rodent and in vitro models

⚠️ Stack combinations listed for research reference only. Not safety or efficacy guidance.

Research Protocol Reference

experimental research protocols only — not dosing recommendations.

ContextProtocol Feature Studied
Rodent memory/plasticity studiesDirect intracerebroventricular (ICV) or intraperitoneal (IP) administration in preclinical protocols
Preclinical neuroprotection modelsPeptide administration timed relative to injury/ischemia induction in animal models

No human dosing protocol exists for FGL peptide, as no human trials have been conducted.

Observed Side Effects in Research

  • No established human safety data exists — no human trials have been conducted
  • In preclinical rodent studies, no major adverse findings have been widely reported in the literature at the doses studied

This is animal data only and cannot be extrapolated to imply human safety. The absence of reported adverse findings in a small number of preclinical studies is not equivalent to a safety profile.

Compound Data

CAS Number
Not consistently assigned in standard small-molecule CAS registries — characterised by amino acid sequence in the primary literature rather than by CAS number
Molecular Formula
14 amino acid synthetic peptide (sequence: EVYVVAENQQGKSKA) — sequence-specific, not typically reduced to a single simplified formula in the literature
Molecular Weight
Approximately 1.5–1.6 kDa (typical for a 14-mer peptide)
Half-Life
Not well characterised in humans — no human PK data exists; preclinical studies typically use direct intracerebroventricular or intraperitoneal administration in rodent models
Synonyms
FGL peptide, NCAM-FGL, FG loop peptide
Research Classification
NCAM (neural cell adhesion molecule) mimetic peptide; FGFR1 agonist/potentiator; synthetic neurotrophic peptide

Scientific References

  • Cambon K et al. 2004 — A synthetic neural cell adhesion molecule mimetic peptide promotes synaptogenesis, enhances presynaptic function, and rescues hippocampal memory consolidation. — Journal of Neuroscience — [Preclinical, rodent model]
  • Berezin V, Bock E et al. — Characterisation of NCAM mimetic peptides including FGL (research programme spanning multiple papers). — Journal of Neurochemistry / Neuroscience, 2000s — [Preclinical / in vitro]
  • Klementiev B et al. 2007 — NCAM mimetic peptide FGL and cognitive/stress-related outcomes. — [Preclinical, rodent model]
  • Skibo GG et al. (Berezin/Bock-affiliated) — Preclinical NCAM-FGL neuroprotection studies. — [Preclinical / in vitro]

The FGL literature is a relatively narrow, specialist body of preclinical work concentrated around the Berezin/Bock Copenhagen research programme, rather than a broad, multi-lab field with independent replication. Readers should weigh the evidence accordingly.

*This compliance check is automated and does not constitute legal advice. No Nonsense Fitness recommends independent legal review for all published content.*
Regulatory Note (Ireland): The Health Products Regulatory Authority (HPRA) governs medicinal products in Ireland. Research peptides are not licensed as medicines unless specifically approved. This content is provided under educational and research exemptions. Nothing on this page constitutes a product claim or therapeutic recommendation.

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