Cortagen (20mg)

Cortagen Peptide

Cortagen is posited to be a synthetic tetrapeptide with the sequence Ala–Glu–Asp–Pro, originally designed based on amino acid analysis of the polypeptide complex cortexin. It is classified among the so-called Khavinson peptides – a family of short peptide bioregulators that are proposed to modulate endogenous regulatory systems rather than acting as classical receptor agonists or enzyme inhibitors.⁽¹⁾ These are low-molecular-weight peptides that are posited to be able to penetrate cells and reach the nucleus, where they may interact directly with DNA and chromatin structures in mammalian research models.

In vitro studies suggest that AACC may be a preferred DNA-binding sequence for Cortagen, raising the hypothesis that it may selectively support transcription at gene sites containing this motif and thereby exert epigenetic-like actions on gene expression. Currently, it appears to be under investigation in laboratory settings for its potential to support stress signaling in different cell cultures, including nerve cell circuits.

Chemical Makeup

Other Known Titles: AEDP, Ala-Glu-Asp-Pro
Molecular Weight: 430.4 g/mol
Molecular Formula: C₁₇H₂₆N₄O₉

Research and Clinical Studies

Epigenetic Potential of Cortagen

Research by Lezhava et al. suggests that Cortagen may have epigenetic support for aged cells, potentially restoring the expression of genes suppressed by the aging process of the cell via condensation of the chromatin.⁽²⁾ According to the researchers, Cortagen was applied to lymphoid cell cultures exhibiting an aged chromatin profile to assess its potential. Differential scanning calorimetry suggested that chromatin was thermodynamically less stable and therefore more uncondensed following Cortagen experimentation.

These study authors proposed that Cortagen may partially unfold higher-order chromatin structures, such as loops of 30-nm fibers and even 10-nm nucleosomal filaments into more relaxed 5-nm fibers, implying that the

“Peptidebioregulator Cortagen induces unrolling deheterochromatinization (decondensation) of total heterochromatin” in both structural and facultative chromatin domains. Consequently, ribosomal gene clusters may become more transcriptionally active, potentially supporting protein synthesis capacity in these aged cells. Yet, Cortagen does not appear to remodel all constitutive blocks as pericentromeric C-heterochromatin on chromosomes analogous to 1, 9, and 16 remained structurally stable. Cortagen also appeared to increase sister chromatid exchange (SCE) frequency in some chromosome groups, which the authors viewed as a potential cytogenetic marker of facultative heterochromatin decondensation and possible re-release of previously repressed genes.

Cortagen Research into Oxidative Stress

According to the research of Kozina et al., Cortagne may support lipid peroxidation and oxidative modification of proteins in mammalian research models.⁽³⁾ According to the team of scientists, Cortagen exposure was associated with “decreased the content of LPO products and reduced oxidative modification of proteins” in both neural cells and the surrounding protein-rich medium. In the cells, the peptide also tended to lower later-stage products. In parallel, Cortagen appeared to reduce the accumulation of protein carbonyl groups, which act as markers of oxidative protein modification, and appeared to achieve a significant reduction in neural cells, and by about 15% in the extracellular fraction.

These authors suggested that Cortagen may interfere with the chain of reactions whereby reactive lipid species attack amino groups in proteins, possibly limiting downstream carbonyl formation. Yet, Cortagen’s potential was apparent only in integrated biological models, suggesting that it may not act as a simple radical scavenger, but instead possibly modulates the generation of reactive species upstream, or alters how cells handle oxidative stress. Thus, the researchers suggest that Cortagen may exert an indirect antioxidant-like action in neural systems by dampening lipid and protein oxidation.

Cortagen Research into Cellular Stress Response and Differentiation

Studies involving a transcriptome-wide analysis of Cortagen’s potential on cardiac muscle cell genes suggest that the peptide may support the cellular stress response of such cultures. Specifically, Anisimov et al. suggested that Cortagen may modulate genes related to carrier proteins and membrane transport, as well as DNA synthesis and replication involved in that response.⁽⁴⁾ This pattern of changes is interpreted as potentially supporting intracellular transport processes and proliferative or reparative programs at the transcriptional level.

Cortagen also apparently up-regulated several mitochondrial genes (16S rRNA, COX3, ND5), which may theoretically interact with bioenergetics. In parallel, transcripts linked to ionic homeostasis and Ca²⁺ handling were altered, hinting at a possible support for excitation–contraction coupling pathways. Among particularly notable targets, Cortagen increased expression of stress-response genes (Pass1, Hsc70), developmental and survival-related signals (Bmp2, Wnt4), and components of mitogenic or survival signaling (Eps15, Eps15-rs). The authors posit that these coordinated transcriptional shifts may underlie some of Cortagen’s broader biological actions and suggest that the peptide may serve as a helpful laboratory tool for exploring peptide-mediated regulation of stress-response networks in vitro.

Further research by Khavinson et al. suggested that by modifying gene expression, the peptide may also support cellular differentiation.⁽⁵⁾ Experimentally, the authors examined Cortagen in an in vitro model using pluripotent embryonic ectodermal tissue. Ectodermal explants were incubated for 1 hour in solutions of Cortagen and then cultured. In the reference medium without peptides, the pluripotent ectoderm apparently gave rise only to atypical epidermis. By contrast, exposure to Cortagen induced the same pluripotent cells to differentiate into epidermal and mesenchymal cells, suggesting that these peptides may broaden the available differentiation pathways.

Cortagen Research into Neurological Stress Signaling and Nerve Regeneration

Cortagen has been examined in laboratory studies by Adriani et al., who have been investigating the activation of arousal- and stress-linked circuits through global output patterns. The scientists observed that the peptide apparently may support output from neural networks associated with arousal and exploratory drive, without concurrently amplifying stress-linked appraisal signals. This pattern may reflect a state in which outward-oriented processing dominates over internal “risk-checking” loops, suggesting a shift in the balance of stress-signaling within the network.

The potential implications of Cortagen on nerve regeneration may better support these observations. GA group of researchers, led by Turchaninova et. al., investigated the neuroregenerative potential of Cortagen. The scientists transected sciatic nerve trunks, which were then micro-sutured and studied in vitro on a multielectrode platform. Compound action potentials (CAPs) were recorded at defined distances distal to the suture line.

Cortagen apparently increased the length of the nerve segment able to conduct impulses by 27% and better-supported conduction velocity by 40% compared to placebo. The authors also suggested that the peptide may preferentially support regeneration where baseline growth is lower, rather than extending growth beyond the usual maximal range. This faster conduction is interpreted as a potential marker of more advanced functional maturation, possibly involving better-supported myelination and fiber calibre.

Cortagen peptide is available for research and laboratory purposes only. Please review our Terms and Conditions before ordering.

References:

1. Khavinson, V. Kh, N. S. Lin’kova, and S. I. Tarnovskaya. “Short peptides regulate gene expression.” Bulletin of experimental biology and medicine 162.2 (2016): 288-292.
2. Lezhava, Teimuraz, et al. “Epigenetic Regulation of “Aged” Heterochromatin by Peptide Bioregulator Cortagen.” International Journal of Peptide Research and Therapeutics 21.1 (2015): 157-163.
3. Kozina, L. S. “Effects of bioactive tetrapeptides on free-radical processes.” Bulletin of experimental biology and medicine 143.6 (2007): 744-746.
4. Anisimov SV, Khavinson VKh, Anisimov VN. Elucidation of the effect of brain cortex tetrapeptide Cortagen on gene expression in mouse heart by microarray. Neuro Endocrinol Lett. 2004 Feb-Apr;25(1-2):87-93. PMID: 15159690.
5. Khavinson V, Linkova N, Diatlova A, Trofimova S. Peptide Regulation of Cell Differentiation. Stem Cell Rev Rep. 2020 Feb;16(1):118-125. doi: 10.1007/s12015-019-09938-8. PMID: 31808038.
6. Adriani, Walter, et al. “Modulatory effects of cortexin and cortagen on locomotor activity and anxiety-related behavior in mice.” The Open Neuropsychopharmacology Journal 2.1 (2009): 22-29.
7. Turchaninova LN, Kolosova LI, Malinin VV, Moiseeva AB, Nozdrachev AD, Khavinson VK. Effect of tetrapeptide cortagen on regeneration of sciatic nerve. Bull Exp Biol Med. 2000 Dec;130(12):1172-4. PMID: 11276314.