PeptidesCategoriesResearch

FGL (NCAM-Derived Peptide)

FGL (FG Loop peptide) is a synthetic peptide derived from the second fibronectin type III domain of neural cell adhesion molecule (NCAM). It activates FGFR1 to promote neuroprotection, synaptic plasticity, and cognitive function, with preclinical efficacy in Alzheimer's disease and neuroinflammation models.

FGL is a synthetic 15-amino acid peptide derived from the second fibronectin type III (FnIII-2) domain of neural cell adhesion molecule (NCAM). It encompasses the FG loop region responsible for NCAM's heterophilic interaction with fibroblast growth factor receptor 1 (FGFR1).

Overview

Neural cell adhesion molecule (NCAM) is a member of the immunoglobulin superfamily that mediates cell-cell adhesion and signaling critical for nervous system development and plasticity. Beyond homophilic NCAM-NCAM binding, NCAM engages heterophilic partners including FGFR1, FGFR2, GDNF family ligand receptors, and the prion protein. The interaction between NCAM's FnIII-2 domain and FGFR1 activates neurotrophic signaling that supports long-term potentiation (LTP), memory consolidation, and neuronal survival (Bhatt et al., 2023).

FGL was rationally designed by Kiselyov, Bhatt, and colleagues at the University of Copenhagen by identifying the minimal NCAM sequence required for FGFR1 activation. The peptide is typically synthesized as a tetramer (four copies linked to a lysine backbone) to increase avidity and receptor clustering -- critical for effective FGFR1 activation (Kiselyov et al., 2003). This dendrimeric design mimics the multivalent presentation of NCAM on the cell surface and enhances biological potency over the monomeric peptide.

Mechanism of Action

FGL activates FGFR1 by binding to the receptor's extracellular domain at a site overlapping but distinct from canonical FGF ligand binding. This triggers receptor dimerization and autophosphorylation, but with distinct kinetics compared to FGF-induced activation -- FGL produces sustained, moderate FGFR1 activation rather than the transient, high-amplitude response elicited by FGF2 (Bhatt et al., 2023).

FGFR1 activation and downstream cascades:

  • MAPK/ERK pathway: FGL-induced FGFR1 phosphorylation activates Ras-Raf-MEK-ERK1/2, promoting neuronal differentiation and survival. ERK activation peaks at 15-30 minutes and sustains for 2-4 hours (Neiiendam et al., 2004)
  • PI3K/Akt pathway: Parallel activation of PI3K leads to Akt phosphorylation at Ser473, inhibiting pro-apoptotic factors (Bad, caspase-9, GSK-3beta) and promoting cell survival
  • PLCgamma/CaMKII pathway: FGFR1-dependent PLCgamma activation elevates intracellular calcium and activates CaMKII, which is critical for LTP induction and memory consolidation (Bhatt et al., 2023)
  • CREB phosphorylation: Convergent ERK and CaMKII signaling activates CREB at Ser133, driving expression of plasticity-related genes including BDNF, Arc, and c-Fos

Anti-inflammatory mechanism: FGL suppresses microglial activation by inhibiting NF-kappaB nuclear translocation and reducing pro-inflammatory cytokine production (TNF-alpha, IL-1beta, IL-6) while increasing anti-inflammatory IL-10 in activated microglia (Downer et al., 2010).

Reconstitution Calculator

FGL (NCAM-Derived Peptide)

FGL is a synthetic 15-amino acid peptide derived from the second fibronectin typ

Draw Volume
0.400mL
Syringe Units
40units
Concentration
2,500mcg/mL
Doses / Vial
5doses
Vial Total
5mg
Waste / Vial
0mcg
Syringe Cap.
100units · 1mL
Recommended Schedule
M
T
W
T
F
S
S
FrequencyOnce daily, 5 days on 2 days off
TimingSubcutaneous injection or intranasal
Cycle4-6 weeks
How to reconstitute
Gather & prepare
1/6Gather & prepare

Set up a clean workspace with all supplies ready.

1.Wash hands thoroughly, put on disposable gloves
2.Your 5mg peptide vial (lyophilized powder)
3.Bacteriostatic water (you'll need 2mL)
4.A 3–5mL syringe with 21–25 gauge needle for reconstitution
5.Alcohol swabs (70% isopropyl)
Use bacteriostatic water (0.9% benzyl alcohol) for multi-dose vials. Sterile water is only safe for single-use.
Supply Planner

7x / week for weeks

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60%
6vials
28 doses5 days/vial2 leftover
Cost Breakdown
Vial price
$0.00per dose
$0.00 /week$0 /month
Store 2-8°C30 day shelf lifeSwirl gentlyFor research purposes only

Research

Synaptic Plasticity and Memory

FGL enhances hippocampal long-term potentiation (LTP) and improves memory in multiple behavioral paradigms. In rat hippocampal slices, FGL facilitates LTP induction at Schaffer collateral-CA1 synapses via FGFR1-dependent mechanisms (Bhatt et al., 2023). In vivo, subcutaneous FGL administration (10 mg/kg) enhances spatial memory in the Morris water maze and object recognition tasks in aged rats (Bhatt et al., 2023). The memory-enhancing effects are blocked by the FGFR inhibitor SU5402 and by MEK inhibitor PD98059, confirming dependence on FGFR1-ERK signaling.

Importantly, FGL's effects on plasticity are distinct from FGF2: while FGF2 can be excitotoxic at high concentrations, FGL's moderate FGFR1 activation profile avoids this liability, making it a safer candidate for chronic neurotrophic therapy.

Cognitive Aging

Age-related cognitive decline is associated with reduced NCAM expression and decreased FGFR1 signaling in the hippocampus. FGL treatment in aged rats (22-24 months) restores hippocampal LTP to levels comparable to young adults and improves performance in spatial navigation tasks. The peptide upregulates synaptic markers including synaptophysin and PSD-95 in the hippocampal CA1 region, suggesting structural synaptic recovery (Bhatt et al., 2023).

Neuroinflammation

FGL modulates microglial phenotype from the neurotoxic M1 state toward the neuroprotective M2 state. In lipopolysaccharide (LPS)-challenged rats, systemic FGL administration reduces hippocampal TNF-alpha and IL-1beta levels while preserving IL-10 production (Downer et al., 2010). In mixed glial cultures, FGL suppresses LPS-induced iNOS expression and nitric oxide production. The mechanism involves FGL-mediated activation of FGFR1 on microglia, which inhibits IKK-dependent NF-kappaB activation.

Peripheral Nerve Regeneration

NCAM plays established roles in peripheral nerve regeneration, and FGL retains some of this activity. In sciatic nerve crush models, FGL promotes functional recovery and increases myelinated fiber density distal to the injury site. The peptide enhances Schwann cell proliferation and migration through FGFR1/ERK-dependent mechanisms (Bhatt et al., 2023).

Alzheimer's Disease Models

FGL has shown efficacy in multiple preclinical Alzheimer's disease models:

  • APP/PS1 transgenic mice: Subcutaneous FGL administration (5.3 mg/kg, twice weekly for 3-4 weeks) reversed spatial memory deficits in the radial arm water maze and reduced hippocampal amyloid plaque-associated inflammation without affecting plaque load itself (Bhatt et al., 2023)
  • Amyloid-beta oligomer models: FGL protects hippocampal neurons from Abeta(1-42) oligomer toxicity in vitro through FGFR1-dependent Akt activation. It also reverses Abeta-induced LTP impairment in hippocampal slices
  • Neuroinflammation component: FGL reduces microglial activation surrounding amyloid plaques, decreasing the inflammatory milieu that accelerates neurodegeneration. This anti-inflammatory effect is independent of its direct neurotrophic activity (Downer et al., 2010)

The dual action of FGL -- direct neuroprotection via FGFR1 plus anti-inflammatory modulation of microglia -- positions it as a multi-target therapeutic candidate for AD, addressing both neuronal vulnerability and neuroinflammation.

Safety Profile

FGL has demonstrated a favorable preclinical safety profile across multiple rodent studies. At doses of 5-10 mg/kg administered subcutaneously 2-3 times weekly for up to 6 weeks, no significant adverse effects, organ toxicity, or behavioral abnormalities have been reported. The peptide does not appear to be immunogenic in rodent models, though the dendrimeric lysine backbone structure could theoretically elicit immune responses with chronic exposure in humans.

A key safety advantage of FGL over full FGF ligands is its inability to recruit heparan sulfate proteoglycans, which limits FGFR1 activation amplitude. This reduces the risk of mitogenic and potentially oncogenic signaling associated with sustained, high-level FGFR activation. FGL does not stimulate fibroblast or endothelial cell proliferation at neuroprotective concentrations, suggesting selectivity for neuronal and glial cell populations.

Theoretical concerns include:

  • FGFR1-related oncogenicity: FGFR1 amplification is observed in some cancers (breast, lung, bladder). However, FGL's moderate, partial agonist activity at FGFR1 is mechanistically distinct from the constitutive FGFR1 activation seen in oncogenic contexts.
  • Immune response: The tetrameric dendrimer structure could be immunogenic with repeated administration. No anti-FGL antibodies have been reported in preclinical studies, but this has not been systematically assessed.
  • Off-target FGFR effects: While FGL shows selectivity for FGFR1, residual FGFR2/3 activation cannot be excluded at supratherapeutic doses.

No human safety data exist. Formal toxicology studies required for IND filing have not been publicly reported.

Pharmacokinetic Profile

FGL (NCAM-Derived Peptide) — Pharmacokinetic Curve

Subcutaneous, intraperitoneal (preclinical)
0%25%50%75%100%0m3d5d8d10d13dTimeConcentration (% peak)T_max 19.5hT_1/2 3d
Half-life: 3dT_max: 18hDuration shown: 13d

Quick Start

Route
Subcutaneous, intraperitoneal (preclinical)

Research Protocols

oral

- Optimized NCAM mimetics: Second-generation peptides based on the FGL scaffold with improved FGFR1 selectivity, enhanced BBB penetration, and oral bioavailability are under investigation (Bhatt et al., 2023).

intraperitoneal Injection

Clinical Research Protocols - Preclinical standard dose: 5-10 mg/kg subcutaneous or intraperitoneal, administered 2-3 times weekly in rodent models.

GoalDoseFrequency
Preclinical standard dose5-10 mgOnce weekly

subcutaneous Injection

In vivo, subcutaneous FGL administration (10 mg/kg) enhances spatial memory in the Morris water maze and object recognition tasks in aged rats (Bhatt et al., 2023). Clinical Research Protocols - Preclinical standard dose: 5-10 mg/kg subcutaneous or intraperitoneal, administered 2-3 times weekly in

GoalDoseFrequency
General Research Protocol5-10 mgOnce weekly
Preclinical standard dose5-10 mgOnce weekly

Interactions

Peptide Interactions

BDNFcompatible
  • Combination neurotrophin approaches: Preclinical studies exploring FGL in combination with BDNF mimetics (e.

What to Expect

What to Expect

Initial Phase

Levels begin building after first administration; half-life of Not formally characterized.

8 minutes

Signaling kinetics: FGF2-FGFR1 signaling produces rapid, high-amplitude ERK phosphorylation (peak at 5-10 min, returning to baseline by 30 min)...

Week 1-2

Duration: Typical preclinical protocols range from 2 weeks (acute neuroprotection) to 4-6 weeks (chronic cognitive studies).

Week 4-6

At doses of 5-10 mg/kg administered subcutaneously 2-3 times weekly for up to 6 weeks, no significant adverse effects, organ toxicity, or behavioral...

Year 1-2

FGL treatment in aged rats (22-24 months) restores hippocampal LTP to levels comparable to young adults and improves performance in spatial...

Quality Indicators

What to look for

  • Human clinical trials conducted
  • Extensive peer-reviewed research base

Caution

  • Limited human data available

Frequently Asked Questions

References (15)

  1. [4]
    Downer EJ et al A synthetic NCAM-derived mimetic peptide, FGL, exerts anti-inflammatory properties via IGF-1 and interferon-gamma modulation J Neurochem (2010)
  2. [15]
    Leander et al — NCAM1 and its interacting partners in brain development and neuropsychiatric diseases Neurosci Biobehav Rev (2022)
  3. [1]
    Kiselyov VV et al Structural basis for a direct interaction between FGFR1 and NCAM and evidence for a regulatory role of ATP Structure (2003)
  4. [2]
    Neiiendam JL et al An NCAM-derived FGF-receptor agonist, the FGL peptide, induces neurite outgrowth and neuronal survival in primary rat neurons J Neurochem (2004)
  5. [3]
    Bhatt et al NCAM mimetic peptides: Old and new Neurochem Res (2023)
  6. [5]
    Cambon K et al A synthetic neural cell adhesion molecule mimetic peptide promotes synaptogenesis, enhances presynaptic function, and facilitates memory consolidation J Neurosci (2004)
  7. [7]
    Klementiev B et al A neural cell adhesion molecule-derived peptide reduces neuropathological signs and cognitive impairment induced by Abeta25-35 Neuroscience (2007)
  8. [8]
    Skibo GG et al A synthetic NCAM-derived peptide, FGL, protects hippocampal neurons from ischemic insult both in vitro and in vivo Eur J Neurosci (2005)
  9. [9]
    Dallerac G et al The neural cell adhesion molecule-derived peptide FGL facilitates long-term plasticity in the dentate gyrus in vivo Learn Mem (2011)
  10. [10]
    Ojo B et al A neural cell adhesion molecule-derived peptide, FGL, attenuates glial cell activation in the aged hippocampus Exp Neurol (2012)
  11. [11]
    Shi et al Neural cell adhesion molecule modulates mesenchymal stromal cell migration via MAPK/ERK signaling Exp Cell Res (2022)
  12. [14]
    Shi et al — Neural cell adhesion molecule modulates mesenchymal stromal cell migration and proliferation via activation of MAPK/ERK signaling Exp Cell Res (2022)
  13. [6]
    Secher T et al Analgesic effects of the NCAM-derived peptide FGL in the formalin test Brain Res (2006)
  14. [12]
    Hartz et al NCAM polysialylation in brain diseases Front Neurosci (2022)
  15. [13]
    Leander et al NCAM1 in brain development and neuropsychiatric diseases Neurosci Biobehav Rev (2022)
Updated 2026-03-08Reviewed by Tides Research Team13 citationsSources: peptide-wiki-mdx, peptide-wiki-mdx-v2

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On this page

Overview
Reconstitution Calculator
Mechanism of Action
Research
Synaptic Plasticity and Memory
Cognitive Aging
Neuroinflammation
Peripheral Nerve Regeneration
Alzheimer's Disease Models
Safety Profile
Pharmacokinetic Profile
Quick Start
Research Protocols
Interactions
What to Expect
Quality Indicators
FAQ
References
Related Peptides