GK-2
A low-molecular-weight dimeric dipeptide mimetic of nerve growth factor's fourth beta-turn loop, designed to reproduce NGF's neurotrophic effects at TrkA without the pain-sensitizing side effects of full-length NGF.
What is GK-2?
GK-2 is a synthetic dimeric dipeptide designed to mimic the fourth beta-turn loop of nerve growth factor (NGF), the region of the protein that contacts the TrkA receptor. It was developed by the medicinal chemistry group of Tatiana Gudasheva and Sergei Seredenin at the V.V. Zakusov Research Institute of Pharmacology (Russian Academy of Medical Sciences, Moscow) as part of a long-running program to build small, drug-like molecules that reproduce the neurotrophic signaling of NGF while avoiding the hyperalgesia — pain sensitization — that has limited full-length recombinant NGF as a clinical drug. In animal models, GK-2 has shown neuroprotective effects in stroke, traumatic brain injury, Parkinson's-like lesions, and depression paradigms. It remains primarily a preclinical research compound; no completed Western human clinical trials have been published.
What GK-2 Is Investigated For
GK-2 is investigated almost entirely in preclinical models for neuroprotection — stroke, traumatic brain injury, Parkinson's-like dopaminergic lesions, Alzheimer's-relevant amyloid paradigms — and for antidepressant-like effects, based on its design as a dipeptide mimetic of the TrkA-binding fourth loop of nerve growth factor. The strongest evidence is mechanistic and animal-level: multiple published papers from the Gudasheva and Seredenin group at the Zakusov Institute document TrkA phosphorylation, downstream PI3K/Akt and MAPK activation, and protective effects in rodent ischemia, MPTP, and forced-swim models. The central pharmacological selling point is that GK-2 appears to selectively engage the TrkA survival pathway without activating p75NTR to the same degree as full-length NGF, which is the signaling split most often credited with NGF's hyperalgesia problem. The honest caveats are substantial: there are no completed Western-published human clinical trials, most of the literature comes from a single Russian research program, independent replication outside that lineage is limited, and GK-2 itself is not an approved medicine in any jurisdiction despite the broader Gudasheva dipeptide-design program having produced other compounds in Russian clinical channels.
History & Discovery
GK-2 is the product of a decades-long medicinal-chemistry program at the V.V. Zakusov Research Institute of Pharmacology of the Russian Academy of Medical Sciences in Moscow, led by Tatiana Gudasheva in collaboration with institute director Sergei Seredenin. The program's central thesis is unusual and, in its own terms, elegant: take a large neurotrophic protein (NGF, BDNF, GDNF) whose clinical development has been limited by poor pharmacokinetics, blood-brain barrier exclusion, and off-target side effects, identify the short beta-turn loop of the protein that makes the critical receptor contact, and synthesize a small, drug-like peptide mimetic of just that loop. The hope is to capture the desired receptor signaling in a molecule that is orders of magnitude smaller, more stable, and more amenable to systemic dosing. GK-2 is the flagship NGF mimetic from this program. Structurally it is a dimeric dipeptide — two monosuccinyl-glutamyl-lysine fragments joined by a hexamethylenediamine linker — modeled on the fourth beta-turn loop of NGF, the region most closely associated with TrkA receptor contact. In published pharmacology it engages TrkA, activates PI3K/Akt and MAPK survival signaling, and shows neuroprotective activity in rodent stroke, Parkinson's, Alzheimer's, and depression models. The group has explicitly pointed to GK-2's TrkA bias relative to p75NTR as the reason it does not reproduce the hyperalgesia that has dogged full-length NGF in clinical development for conditions like diabetic neuropathy and Alzheimer's disease. GK-2 is the NGF analogue in a broader family of loop-mimetic dipeptides from the same group. Its BDNF-mimetic sibling, GSB-106, models a loop of brain-derived neurotrophic factor at the TrkB receptor using the same design grammar. Despite substantial preclinical literature and mechanistic detail, GK-2 itself has not reached published Western clinical trials. A few compounds from the broader Gudasheva platform have progressed into Russian clinical channels; GK-2 has not. The program is the most well-developed attempt in the Russian peptide-pharmacology tradition to bridge from large neurotrophin biology to small-molecule drug design, and the preclinical record is substantially thicker than for most Russian research peptides of comparable vintage.
How It Works
GK-2 is a small molecule designed to copy just the part of nerve growth factor (NGF) that tells brain cells to survive and grow. The idea is to keep NGF's helpful brain effects while leaving out the part of NGF signaling that causes pain sensitivity.
GK-2 is a dimeric dipeptide — two monosuccinyl-glutamyl-lysine units joined through a hexamethylenediamine linker — modeled on the fourth beta-turn loop of the NGF protein. In cell and animal studies from the Gudasheva and Seredenin laboratory, GK-2 engages the TrkA receptor, promoting its phosphorylation and activating the downstream PI3K/Akt and Ras/MAPK survival pathways characteristic of full-length NGF. A central claim in the program's literature is that GK-2 is biased toward TrkA signaling relative to p75NTR engagement. Because p75NTR activation is implicated in NGF-induced hyperalgesia, this bias is the proposed molecular basis for GK-2's ability to deliver NGF-like neuroprotection without producing the pain sensitization that has troubled clinical development of recombinant NGF. In rodent models of cerebral ischemia, MPTP-induced parkinsonism, amyloid toxicity, and behavioral despair, GK-2 has shown neuroprotective and antidepressant-like activity at low milligram-per-kilogram doses administered intraperitoneally or intravenously.
Evidence Snapshot
Human Clinical Evidence
None published in Western indexed literature. No completed Phase I, II, or III human trials of GK-2 have been reported in PubMed-indexed venues as of the latest update.
Animal / Preclinical
Moderate. Multiple published studies from the Gudasheva / Seredenin group in rodent models of stroke, parkinsonism, Alzheimer's-relevant pathology, and depression. Independent replication outside that lineage is limited.
Mechanistic Rationale
Moderate. The TrkA-biased dipeptide mimetic concept is chemically coherent and supported by in vitro receptor activation and downstream signaling data.
Research Gaps & Open Questions
What the current literature has not yet settled about GK-2:
- 01Human clinical trials — no completed Phase I, II, or III studies of GK-2 have been published in Western indexed literature; human pharmacokinetics, tolerability, and efficacy are uncharacterized.
- 02Independent replication — most of the pharmacology comes from the Gudasheva and Seredenin laboratory at the Zakusov Institute; independent reproduction in Western and non-affiliated Russian groups is limited.
- 03Receptor-selectivity confirmation — the claimed TrkA-over-p75NTR bias that underwrites the no-hyperalgesia argument needs more extensive, independent receptor pharmacology in human cells and in primate pain models.
- 04Long-duration oncology safety — TrkA signaling contributes to proliferation in several tumor types (including TrkA-expressing neuroblastoma and some adult cancers); formal carcinogenicity and tumor-promotion studies in susceptible models are absent from the public literature.
- 05Route and formulation — published animal work uses parenteral dosing; an oral, intranasal, or otherwise patient-friendly route has not been validated.
- 06Comparative effectiveness — direct comparisons of GK-2 versus Cerebrolysin, Dihexa, or other neurotrophic-mimetic strategies in shared preclinical paradigms are sparse.
- 07Program-level prioritization — the Gudasheva and Seredenin group's 2025 publication arc has shifted toward NT-3 dipeptide mimetics (GTS-301, GTS-302) for analgesia and opioid-withdrawal applications rather than additional GK-2 work, which raises the question of whether GK-2 remains an active development candidate within the originating program or has been deprioritized in favor of sister compounds.
Forms & Administration
In published animal studies, GK-2 has been administered intraperitoneally and intravenously at single-digit milligram-per-kilogram doses. There is no established human route, dose, or schedule. GK-2 is a research compound and not available as a clinician-prescribed or compounded medicine.
Common Questions
Who GK-2 Is NOT For
- •Active or recent-history cancer with TrkA-expressing tumor types — TrkA signaling drives proliferation and survival in several neoplasms (notably TrkA-expressing neuroblastoma and certain adult tumors with NTRK gene fusions or TrkA overexpression), and a TrkA-biased agonist is theoretically inappropriate in those backgrounds. Formal carcinogenicity assessment is absent from the public literature.
- •Pregnancy and lactation — no reproductive or developmental safety data exist for GK-2 in any species.
- •Pediatric use outside a clinical research setting — neurotrophin signaling is developmentally active, and the long-term consequences of exogenous TrkA-biased agonism in developing nervous systems are uncharacterized.
- •Active peripheral neuropathy or unexplained chronic pain syndromes — TrkA contributes to peripheral nociception, and even a 'biased' TrkA agonist could theoretically modulate pain pathways in unpredictable ways without controlled human data.
- •Known hypersensitivity to peptide preparations or research-chemical excipients.
- •Any clinical use outside an investigator-led protocol — GK-2 is a preclinical compound with no Western human safety data, and the honest baseline is that therapeutic use sits outside the supported evidence.
Drug & Supplement Interactions
No formal drug-interaction studies for GK-2 exist in the public literature. Theoretical considerations follow from the TrkA-biased signaling mechanism and the broader pharmacology of co-administered CNS-active medications. Concurrent use with anticancer kinase inhibitors that target Trk receptors (entrectinib, larotrectinib, repotrectinib for NTRK-fusion cancers) would be pharmacologically antagonistic and is not appropriate. Concurrent use with serotonergic antidepressants, ketamine, psychedelics, or other agents that modulate BDNF-TrkB signaling could theoretically interact at the level of overlapping neurotrophin downstream pathways (PI3K/Akt, MAPK), though no clinical data exist. Concurrent administration with the sibling BDNF-mimetic GSB-106 is common in the originating program's preclinical work but has not been characterized for safety or for additive vs antagonistic effects in any controlled setting. Patients on any chronic medication who are considering GK-2 (in a research protocol) should disclose all concurrent agents to the investigator.
Safety Profile
Common Side Effects
Cautions
- • No completed, Western-published human clinical trials
- • Most data from a single Russian research program; independent replication is limited
- • TrkA is a receptor with roles in peripheral nociception, sympathetic function, and some tumor biology — theoretical concerns warrant caution
- • Research-chemical supply is not pharmaceutical-grade
What We Don't Know
Human pharmacokinetics, dose-response, chronic safety, and efficacy in any indication are not characterized in the published literature.
Legal Status
United States
GK-2 is not FDA-approved for any indication. It is not a controlled substance. It is not recognized as a dietary supplement ingredient or as a compounded medicine in the United States. It is not available through any legitimate pharmaceutical or compounding channel and should be regarded as a preclinical research compound only.
International
GK-2 is not an approved medicine in Russia, the European Union, the United Kingdom, Canada, Australia, or any other jurisdiction for which registration records are publicly indexed. Other compounds from the broader Gudasheva dipeptide-mimetic program have moved toward Russian clinical evaluation; GK-2 itself has not been registered as a medicine.
Sports & Competition
GK-2 is not currently listed by name on the WADA Prohibited List. However, WADA's S0 category prohibits any substance 'not currently approved by any governmental regulatory health authority for human therapeutic use,' a description that applies to GK-2. Athletes subject to WADA or equivalent codes should treat it as prohibited.
Regulatory status changes over time. Verify current local rules with a qualified professional.
Myths & Misconceptions
Myth
GK-2 is a drug that has been approved for stroke or Alzheimer's treatment in Russia.
Reality
It is not. Despite a sustained preclinical record from the Gudasheva and Seredenin group at the Zakusov Institute, GK-2 has not been registered as a medicine in Russia or in any other jurisdiction. Other compounds from the broader Gudasheva dipeptide-mimetic program have advanced toward Russian clinical evaluation, but GK-2 itself remains a preclinical research compound.
Myth
Because GK-2 is a small dipeptide, it behaves like full-length NGF in the brain.
Reality
GK-2 was designed to reproduce the TrkA-binding fourth beta-turn loop of NGF, not full-length NGF activity. Native NGF is a homodimeric protein that engages both TrkA and p75NTR with complex signaling, including effects on peripheral pain pathways. GK-2 is intended to be biased toward TrkA over p75NTR — that's the entire pharmacological selling point — and accordingly does not reproduce the full NGF signaling repertoire. The 'small NGF' framing oversells the chemical equivalence.
Myth
GK-2's neuroprotective effects in rodent stroke and dementia models predict efficacy in humans.
Reality
Animal models of stroke and Alzheimer's have a poor translation record for neuroprotective agents — the cemetery of failed Phase 3 stroke neuroprotectants is one of the most-cited cases in pharmaceutical research. Preclinical efficacy in MCAO, MPTP, beta-amyloid, and behavioral despair models is encouraging signal, not predictive evidence. The absence of Western Phase 2 / 3 trials means human efficacy is genuinely unknown.
Myth
Research-chemical GK-2 is the same molecule as the Zakusov Institute's published compound.
Reality
GK-2 is a specific dimeric dipeptide — bis-(N-monosuccinyl-L-glutamyl-L-lysine) hexamethylenediamide — with a defined stereochemistry. Research-chemical-channel suppliers have no obligation to verify sequence, stereochemistry, or purity, and the identity of consumer-channel 'GK-2' cannot be assumed to match the published compound. The 'same molecule' assumption is unsupported.
Published Research
5 studiesA Nerve Growth Factor Dipeptide Mimetic Stimulates Neurogenesis and Synaptogenesis in the Hippocampus and Striatum of Adult Rats with Focal Cerebral Ischemia
Shows GK-2 drives neurogenesis and synaptogenesis after focal cerebral ischemia — a key mechanistic datapoint for the neuroregenerative claim.
Comparison of the Pharmacological Effects of Dimeric Dipeptide Nerve Growth Factor Mimetic GK-2 and Mexidol on the Model of Ischemic Stroke in Rats
Head-to-head comparison of GK-2 against Mexidol (a Russian-market neuroprotectant) in rat ischemic stroke model.
Behavioral effect of dipeptide NGF mimetic GK-2 in an in vivo model of rat traumatic brain injury and its neuroprotective and regenerative properties in vitro
Shows 1 mg/kg IP GK-2 for 5 days after TBI improves motor function in rats and stimulates neurite outgrowth in vitro.
Original Nerve Growth Factor Mimetic Dipeptide GK-2 Restores Impaired Cognitive Functions in Rat Models of Alzheimer's Disease
Demonstrates GK-2 rescues cognitive deficits in β-amyloid and scopolamine-induced rat models of Alzheimer's disease at 0.1–1.0 mg/kg IP dosing.
In vitro study of neuroprotective properties of GK-2, a new original nerve growth factor mimetic
Early Gudasheva-group paper demonstrating neuroprotective activity of GK-2 on cultured mouse hippocampal neurons at nanomolar concentrations via TrkA-mediated PI3K/Akt signaling.
Quick Facts
- Class
- NGF Mimetic Dipeptide
- Tier
- D
- Evidence
- Preliminary
- Safety
- Limited Data
- Updated
- Jun 2026
- Citations
- 5PubMed
Also known as
Tags
Related Goals
Evidence Score
Clinical Trials
View Clinical TrialsLinks to ClinicalTrials.gov for reference. Listing does not imply endorsement.