How does copper contribute to GHK-Cu's biological activity?

The copper(II) ion serves as a critical cofactor influencing the peptide's conformation and biological interactions. Copper is essential for enzymes like lysyl oxidase (collagen cross-linking) and superoxide dismutase (antioxidant defense). GHK acts as a copper delivery vehicle, transporting Cu²⁺ to tissues.

What is the molecular weight of GHK-Cu?

GHK-Cu has a molecular weight of approximately 403.93 g/mol (CAS: 49557-75-7). The molecular formula for the copper complex is C₁₄H₂₃CuN₆O₄. The free GHK peptide without copper has a molecular weight of 340.38 g/mol.

How is GHK-Cu different from other research peptides?

GHK-Cu is unique: it naturally chelates a metal ion (copper), it is a very small tripeptide (only 3 amino acids), and it affects expression of thousands of genes. Unlike most signaling peptides, GHK-Cu's activity is mediated through copper delivery and gene expression modulation.

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Research Guides • February 11, 2026 • 13 min read

GHK-Cu: Copper Peptide Research, Mechanisms & Laboratory Applications

Q: What research areas involve GHK-Cu?

GHK-Cu is studied in dermatological science (collagen synthesis, wound models), gene expression profiling (over 4,000 genes affected), antioxidant biology (SOD upregulation), extracellular matrix research, and copper biology (metalloprotein function and copper transport).

Comprehensive research overview of GHK-Cu copper peptide: molecular structure, copper-binding mechanism, gene expression modulation, and laboratory applications in tissue remodeling research.

What Is GHK-Cu?

GHK-Cu (glycyl-L-histidyl-L-lysine copper(II)) is a naturally occurring tripeptide–copper complex first isolated from human plasma in 1973 by Dr. Loren Pickart. It consists of three amino acids — glycine, histidine, and lysine — bound to a copper(II) ion through a high-affinity chelation bond.

GHK-Cu is found naturally in human plasma, saliva, and urine, with concentrations declining significantly with age. This age-related decline, combined with its broad influence on gene expression, has made it a subject of considerable research interest.

For foundational context, see our guides on what peptides are and how peptides function.

Molecular Structure & Copper Binding

GHK-Cu has a molecular weight of approximately 403.93 g/mol (CAS: 49557-75-7). The molecular formula is C₁₄H₂₃CuN₆O₄. The free peptide without copper weighs 340.38 g/mol.

Key structural features:

Histidine imidazole ring: Primary coordination site for Cu²⁺
Glycine amino group: Secondary coordination point
Square-planar geometry: Deprotonated amide nitrogens complete the copper coordination
High affinity: Binding constant log K = 16.44, ensuring tight chelation

The peptide serves as a biological copper transport vehicle, delivering Cu²⁺ to cells where it participates in enzymatic reactions and gene regulation.

Mechanism of Action

Gene Expression Modulation

Microarray studies using the Broad Institute's Connectivity Map show GHK-Cu affects expression of over 4,000 human genes (~6% of the genome). GHK-Cu tends to:

Upregulate genes for ECM production, antioxidant defense, and tissue remodeling
Downregulate genes for inflammatory signaling and tissue degradation
Reset expression patterns toward profiles associated with younger tissue

Collagen & ECM Signaling

Collagen synthesis: Stimulates type I and III collagen via copper-dependent lysyl oxidase
GAG production: Increases dermatan sulfate, chondroitin sulfate synthesis
Decorin expression: Upregulates this proteoglycan that regulates collagen assembly
MMP modulation: Balances degradation with controlled remodeling

Antioxidant & Protective Pathways

Superoxide dismutase: Copper delivery supports SOD3 antioxidant activity
Ferritin regulation: Upregulates iron storage, reducing free radical generation
Anti-inflammatory: Downregulates IL-6 and TNF-α pathways

These properties are complementary to glutathione (cellular detoxification) and NAD+ (sirtuin-mediated protective pathways).

Wound Model & Tissue Remodeling

Angiogenesis: Promotes new blood vessel formation, similar to pathways studied with BPC-157
Fibroblast recruitment: Enhanced migration to wound sites
Nerve growth factor: Upregulation in tissue cultures
Anti-scarring: TGF-β signaling modulation

Research Applications

Dermatological Research

In vitro fibroblast studies examine collagen, elastin, and ECM remodeling. GHK-Cu is a component of the GLOW research blend, combined with BPC-157 and TB-500 for multi-pathway research.

Gene Expression Profiling

Used as a model compound in transcriptomics studies, examining how a small peptide influences thousands of genes simultaneously.

Copper Biology & Metalloproteomics

Serves as a tool for studying copper homeostasis, metalloprotein function, and trace metal biology.

Aging & Longevity Research

The age-related decline in endogenous GHK-Cu, combined with its gene expression effects, positions it as a compound of interest in aging biology research.

Regenerative Medicine Research

The Wolverine blend (BPC-157 + TB-500) and GHK-Cu represent complementary tissue repair pathways — BPC-157 via nitric oxide, TB-500 via actin binding, GHK-Cu via copper-mediated ECM remodeling.

Laboratory Preparation & Handling

Appearance: Fine blue powder. Solutions have a faint blue tint — this is normal.
Solubility: Highly soluble in water and bacteriostatic water.
Reconstitution: Standard protocols. See our complete reconstitution guide.
Storage: Powder at -20°C. Reconstituted at 2–8°C, use within 3–4 weeks.
Avoid: Chelating agents (EDTA, DTPA) that strip the copper ion.

Quality Indicators

Purity: HPLC ≥98%. MS confirmation of 403.93 g/mol.
Copper content: Analytical confirmation of proper Cu²⁺ chelation.
COA: Third-party Certificate of Analysis with batch-specific testing.
Visual: Must be blue/blue-green. White powder = copper absent.

See our guide on evaluating peptide vendors for quality assessment frameworks.

Current State of Research

In vitro: Robust cell culture data on fibroblast behavior and gene expression. Connectivity Map provides genome-wide evidence.
Animal models: Preclinical wound studies showing effects on angiogenesis, collagen, nerve regeneration.
Cosmetic applications: Incorporated into commercial products based on in vitro data.
No therapeutic approval: Not approved by any regulatory body.

FAQ: What is GHK-Cu?

A naturally occurring copper-binding tripeptide (glycine-histidine-lysine + Cu²⁺) studied for gene expression modulation, ECM remodeling, and metalloprotein biology.

FAQ: How does copper contribute to GHK-Cu's activity?

Cu²⁺ is a cofactor for key enzymes (lysyl oxidase, SOD). GHK delivers copper to tissues for enzymatic processes and gene regulation.

FAQ: What is the molecular weight?

403.93 g/mol for the copper complex (CAS: 49557-75-7). Formula: C₁₄H₂₃CuN₆O₄.

FAQ: What research areas involve GHK-Cu?

Dermatological science, gene expression profiling, antioxidant biology, ECM research, copper biology, and aging/longevity studies.

FAQ: How is GHK-Cu different from other peptides?

It chelates copper, is only 3 amino acids, and affects 4,000+ genes. Its activity is mediated through copper delivery rather than receptor binding.

Research Resources

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This compound is intended for laboratory research use only. Not approved for human or veterinary use.

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