Catalog No.
Product Name
Application
Product Information
Citations
-
ACTH Peptide
Acetyl-ACTH (4-24) is a fragment of proopiomelanocortin (POMC) that acts primarily on the melanocortin-1 receptor (MC-1). This peptide exhibits biological activities associated with the modulation of pigmentation and adrenal function. It is suitable for research applications focusing on stress response, melanogenesis, and the physiological effects of POMC-derived peptides in human, bovine, and rat models. -
Bioactive Peptide
SRC-1 NR box peptide is a bioactive peptide derived from a 14-amino acid fragment of the steroid receptor cofactor SRC-1 NR II. This peptide plays a crucial role in modulating the activity of estrogen receptor ligands and is valuable for investigating the regulatory mechanisms involved in estrogen signaling. Its applications extend to studies focused on hormone receptor interactions and related cellular processes. -
GRP10 Receptor Ligand
Prolactin-Releasing Peptide (1-31) (rat) is a ligand for the UHR-1/GRP10 receptor. This peptide is known to modulate physiological processes by reducing fasting-induced food intake and elevating plasma levels of luteinizing hormone (LH), follicle-stimulating hormone (FSH), and testosterone in rat models. It is valuable for research applications focusing on appetite regulation and endocrine function. -
Thyroid Hormone Peptide
Calcitonin, eel is a thyroid hormone peptide known for its role in regulating calcium homeostasis. It functions by inhibiting osteoclast activity, thereby reducing bone resorption and promoting calcium deposition in bones. This compound is extensively utilized in research related to postmenopausal osteoporosis and other calcium-related disorders, providing insights into bone metabolism and potential therapeutic strategies. -
Pro-TRH Connecting Peptide
Prepro-TRH-(160-169) is a peptide derived from the pro-TRH prohormone that plays a crucial role in the release of thyrotropin (TSH) by amplifying the effects of thyrotropin-releasing hormone (TRH). This connecting peptide is instrumental in investigating the regulation of TSH secretion and the broader implications of TRH in endocrine function. Prepro-TRH-(160-169) is valuable for research into thyroid physiology, neuroendocrine signaling, and related disorders. -
Building Block in Solid-phase Peptide Synthesis
Fmoc-Trp(Me)-OH is a protected amino acid derivative that functions as a building block in solid-phase peptide synthesis. By introducing a methyl group at the nitrogen atom of the indole ring of tryptophan and utilizing the Fmoc protecting group, Fmoc-Trp(Me)-OH facilitates the assembly of peptides with enhanced stability and specificity. This reagent is widely employed in protein synthesis and various biochemical applications, enabling researchers to study protein interactions and functionalities. -
Dipeptide
Glycyl-L-tyrosine is a synthetic dipeptide that serves as a source of tyrosine, an essential amino acid involved in the synthesis of neurotransmitters such as dopamine and norepinephrine. It is commonly used in research applications related to neurobiology and nutritional studies, providing insights into amino acid supplementation's effects on cognitive function and mood regulation. -
Building Block in Solid-phase Peptide Synthesis
Fmoc-N-Me-Leu-OH is an N-Fmoc-N-methyl amino acid that serves as a crucial building block in solid-phase peptide synthesis (SPPS). This compound allows for the incorporation of N-methylleucine residues into peptide sequences, significantly improving enzymatic stability, modifying conformational flexibility, and potentially altering the biological activity of the synthesized peptides. Its use in peptide coupling reactions makes it a valuable reagent for research in peptide chemistry and drug development. -
Tumor Target Peptide
NY-ESO-1 (157-165) peptide is a tumor-associated peptide fragment derived from the NY-ESO-1 protein. This peptide is recognized by CD8+ T cells in HLA-A2 positive individuals, promoting significant immune activation and responses. Its expression in various tumors makes NY-ESO-1 (157-165) peptide a valuable candidate for research into tumor immunotherapy approaches. -
Dipeptide
Fmoc-Ala-Ala-OH is a self-assembling dipeptide featuring a fluorenylmethoxycarbonyl (Fmoc) moiety, designed for creating nanofiber networks. When exposed to conditions below pH 4, this dipeptide forms a hydrogel scaffold with over 99% water content, exhibiting fiber diameters around 22 nm that closely resemble extracellular matrix (ECM) components. Fmoc-Ala-Ala-OH facilitates cell adhesion and proliferation while preserving cellular phenotype, thereby mimicking the ECM. This reagent is particularly valuable in tissue engineering and 3D cell culture applications, making it ideal for in vitro studies of chondrocytes and other cell types. -
Dipeptide Derivative
Z-Val-Ala-OH is a dipeptide derivative primarily composed of valine and alanine. This compound is utilized in the study of peptide synthesis and enzymatic activity, providing researchers with insight into protein structure and function. Its applications extend to various fields such as drug development, molecular biology, and biochemistry, facilitating the exploration of peptide interactions and biological pathways. -
Peptide Derivative
Fmoc-N-Me-Val-OH is a modified peptide derivative that incorporates a N-methylated valine residue. This compound is primarily utilized in peptide synthesis to enhance the stability and bioactivity of peptides. Its unique structural features facilitate improved binding affinity and resistance to proteolytic degradation, making it valuable in research applications focused on drug development and therapeutic peptide engineering. -
Dipeptide
H-Ala-Ala-OH (L-Alanyl-L-alanine) is a nonpolar dipeptide that serves as a substrate for transport via the proton/amino acid symport mechanism in human intestinal Caco-2 cells. This compound facilitates the absorption of alanine, contributing to cytoplasmic acidification. H-Ala-Ala-OH is valuable in studies of peptide transport mechanisms and amino acid metabolism, offering insights into gut absorption processes and cellular pH regulation. -
Peptide Synthesis
Fmoc-N-Me-Ile-OH is an Fmoc-protected amino acid that serves as a building block in peptide synthesis. Its unique N-methyl substitution enhances the stability and bioactivity of peptides, making it useful in the development of bioactive compounds and pharmaceuticals. This reagent is particularly valuable for researchers in the fields of medicinal chemistry and peptide engineering, facilitating the creation of structurally diverse peptides for various applications. -
Polypeptide
H-Gly-Arg-Ala-Asp-Ser-Pro-OH (GRADSP) is a polypeptide designed as a negative control for the GRGDSPK peptide. This compound lacks the integrin-binding RGD motif, making it an essential tool for validating the specificity of RGD-containing peptides in cellular assays. Its use is critical in studies focusing on cell adhesion, migration, and signaling pathways affected by integrin interactions. -
Dipeptide
gamma-Glutamylisoleucine (γ-Glu-Ile) is a dipeptide formed from γ-glutamic acid and isoleucine. This compound plays a role in protein metabolism, serving as a degradation product of macromolecular proteins following proteolysis. Its study is relevant for understanding peptide signaling and protein turnover in various biological systems. -
Substrate Peptide
Hippuryl-Arg (Bz-Gly-Arg) functions as a substrate peptide and serves as a fluorescent indicator in biochemical research. It is specifically designed for the detection of enzymes that cleave peptide bonds adjacent to arginine residues. The compound's aromatic side chain enables visibility under ultraviolet light, facilitating studies on enzyme activity and substrate specificity. This reagent is essential for investigations into proteolytic processes and enzyme characterization in various biochemical applications. -
Tripeptide
Fmoc-Gly-Gly-Gly-OH is a tripeptide with Fmoc (9-fluorenylmethoxycarbonyl) as the protecting group, primarily utilized in peptide synthesis. This compound provides a versatile building block for the development of larger peptides and proteins. Its structural simplicity enables efficient incorporation into more complex sequences, facilitating research in areas such as drug development, bioconjugation, and protein engineering. -
Anti-aging Peptide
Oligopeptide-68 is a bioactive peptide specifically designed for anti-aging applications. This compound has shown efficacy in promoting skin regeneration and reducing the appearance of fine lines and wrinkles. Its use is primarily focused on cosmetic formulations aimed at enhancing skin elasticity and overall youthfulness, making it a valuable addition to research in dermatological and aesthetic studies. -
Dipeptide
Fmoc-Ala-Ser(psi(Me,Me)pro)-OH is a dipeptide designed for bioconjugation and protein engineering applications. This compound features a unique psi(Me,Me)pro moiety, which enhances stability and influences conformational properties. It serves as a valuable building block for synthesizing peptides with modified backbone structures, facilitating studies in peptide behavior, interactions, and biological activity. Researchers can utilize this reagent in drug development, therapeutic protein design, and the exploration of peptide-protein interactions. -
Peptide Substrate
(Trp4)-Kemptide is a specific peptide substrate for adenosine 3',5'-cyclic monophosphate-dependent protein kinase (PKA). This compound serves as a valuable tool for studying PKA activity and its regulatory mechanisms in signal transduction pathways. It is commonly used in biochemical assays to investigate phosphorylation events in various cellular processes, providing insights into PKA-related signaling pathways and their implications in diseases. -
Dipeptide
Gamma-Glutamylproline (γ-Glu-Pro) is a γ-glutamyl dipeptide known for its kokumi properties, which enhance the flavor profile of food. This compound exhibits potential neuroprotective effects and plays a role in modulating amino acid transport in cells. Gamma-Glutamylproline is useful in research areas focused on nutrition, sensory science, and amino acid metabolism. -
Dipeptide
Fmoc-Gln(Trt)-Thr(psi(Me,Me)pro)-OH is a dipeptide featuring Fmoc (9-fluorenylmethoxycarbonyl) protection on the amino group and Trt (trityl) protection on the side chain. This compound is useful in solid-phase peptide synthesis and can aid in the exploration of peptide structure-function relationships. Its unique threonine residue with a psi(Me,Me) proline analog may be valuable for studies involving protein folding and stability. -
Dipeptide
γ-Glu-Lys (L-γ-Glutamyl-L-lysine) is a γ-glutamyl dipeptide that serves as a substrate for various enzymes involved in metabolism and signaling pathways. This compound plays a significant role in the modulation of cellular functions and protein interactions. Its primary applications include research in peptide synthesis, drug design, and studies related to glutamate metabolism. Additionally, γ-Glu-Lys may be utilized in exploring therapeutic approaches for neurodegenerative disorders. -
Dipeptide
Gamma-Glutamylaspartic acid (γ-Glu-Asp) is a dipeptide that serves as a γ-glutamyl derivative. It exhibits kokumi activity, which is implicated in enhancing flavor profiles in food science. This compound may be useful in biochemical research focusing on taste mechanisms, neural signaling, and metabolic pathways associated with amino acids. -
Dipeptide
Ala-Ser (H-Ala-Ser-OH) is a dipeptide formed by the linkage of alanine and serine through a peptide bond. This compound has applications in biochemical research for studying protein interactions, peptide synthesis, and enzyme activity. Its structural characteristics can provide insights into protein folding and stability, making it a valuable reagent in peptide research and development. -
Dipeptide
Z-Val-Gly-OH is a dipeptide featuring a N-benzyloxycarbonyl (Z) protecting group. This compound serves as a versatile building block in peptide synthesis and offers functional insights into peptide structure-activity relationships. Its applications extend to studies involving protein folding, enzymatic activity, and pharmaceutical development, making it a valuable reagent for researchers in the life sciences. -
Tripeptide
H-Gly-Pro-Gly-OH is a tripeptide that comprises glycine and proline residues. This compound serves as a versatile building block for the synthesis of various polypeptides, including (Pro Gly Gly)n. Its applications extend to peptide synthesis and structural biology research, facilitating investigations into peptide interactions and functions. -
Dipeptide
H-Met-Val-OH is a dipeptide featuring a free N-terminal methionine. This compound demonstrates inhibitory activity against cDNA expressing Flavin-containing monooxygenase (FMO) 1 and FMO3. H-Met-Val-OH is potentially applicable in studies related to neurite outgrowth and neural regeneration. -
Dipeptide
L-Phenylalanyl-L-threonine is a dipeptide composed of phenylalanine and threonine. This compound serves as a key intermediate for synthesizing the cyclic hexapeptide Banyascyclamide A. Its unique structure makes it valuable in studies involving peptide synthesis and the exploration of peptide-based therapeutics. -
Dipeptide
Fmoc-Glu(OtBu)-Thr(psi(Me,Me)pro)-OH is a dipeptide designed for use in peptide synthesis and modification studies. This compound features fluorenylmethyloxycarbonyl (Fmoc) protection, which facilitates efficient solid-phase peptide synthesis. Its unique structure allows for investigation into peptide conformation and biological interaction, making it valuable for research in drug development and molecular biology. -
Dipeptide
Fmoc-Ile-Ser(psi(Me,Me)pro)-OH is a modified dipeptide that incorporates a psi(Me,Me)pro residue, which enhances conformational stability. This compound serves as a valuable tool for studying peptide structure-function relationships, facilitating insights into protein interactions and enzyme dynamics. Its unique properties make it relevant in the design of peptide-based therapeutics and in mechanistic studies within biochemical research. -
Dipeptide
Lys-Phe is a dipeptide that primarily targets the inhibition of cell sickling and prevents the gelation of sickle-cell hemoglobin solutions. This compound exhibits significant biological activity in the context of sickle cell disease research, contributing to studies focused on hemoglobin stabilization and cellular pathology. Its applications extend to evaluating therapeutic strategies aimed at managing the complications associated with sickle cell anemia. -
Polypeptide
Glycyllysine is a polypeptide known for its ability to facilitate the synthesis of antibodies and amino acid-based gemini surfactants. This compound exhibits potential in enhancing the transport capabilities of plasmid/gemini/lipid (P/G/L) nanoparticles, making it a valuable tool in drug delivery and nanotechnology research applications. Its unique structure and properties can be leveraged in various biochemical and pharmaceutical studies. -
Dipeptide
H-Met-Asp-OH is a dipeptide composed of methionine and aspartic acid, serving as a crucial building block for the synthesis of polypeptides. This compound is utilized in various biological research applications, particularly in the study of protein structure and function. Its unique properties facilitate investigations into peptide interactions and enzymatic activities, making it a valuable tool in peptide chemistry and related fields. -
Dipeptide
Fmoc-Gln(Trt)-Ser(psi(Me,Me)pro)-OH is a dipeptide featuring a protected glutamine and a modified serine residue. This compound is primarily utilized in peptide synthesis and research applications targeting protein interactions and modifications. Its unique structure allows for exploration of conformational dynamics and post-translational modifications, facilitating insights into biochemical pathways and therapeutic developments. -
Dipeptide
Fmoc-Ser(tBu)-Ser(psi(Me,Me)pro)-OH is a dipeptide that incorporates a modified serine moiety and a psi amino acid structure. It serves as a valuable building block in peptide synthesis and has applications in studying peptide conformation and stability. This compound can be utilized in research focused on the design of bioactive peptides and scaffolds for therapeutic development. -
Amphipathic CPP
EB1 peptide is an amphipathic cell-penetrating peptide (CPP) derived from Penetratin. It facilitates the delivery of various therapeutic agents into cells by traversing cellular membranes. This compound is valuable for research applications focused on intracellular drug delivery mechanisms and strategies for enhancing the bioavailability of macromolecules in cellular contexts. -
Oligopeptide Linker
Fmoc-Cys-Asp10 is a non-releasable oligopeptide linker designed for use in the synthesis of releasable oligopeptide linkers. This compound can facilitate the targeted delivery of therapeutic agents to bone fractures, enhancing the healing process and potentially reducing recovery times for fractured femurs. Its application in biochemical research provides valuable insights into peptide-mediated drug delivery systems. -
Dipeptide
L-Alanyl-L-tryptophan is a dipeptide composed of L-alanine and L-tryptophan, serving as a key metabolite in various biological processes. Its ability to adsorb onto gold nanoparticles enhances the Raman signal through surface-enhanced Raman scattering (SERS) technology, making it a valuable tool for advanced spectroscopic analysis. This compound is useful in research applications involving protein interactions, drug delivery systems, and nanotechnology. -
Synthetic Hexapeptide
Hexapeptide-10 is a synthetic hexapeptide that primarily targets the promotion of wound healing and tissue remodeling processes. This compound has been shown to enhance skin regeneration and improve overall skin texture, making it valuable in cosmetic and dermatological research applications. Its unique properties contribute to advancements in the development of innovative skincare treatments. -
Dipeptide
Fmoc-Asp(OtBu)-Ser(psi(Me,Me)pro)-OH is a synthetic dipeptide that serves as a key building block in peptide synthesis. This compound incorporates a protected aspartic acid and a unique serine derivative, allowing for the exploration of novel peptide structures. Its application in research includes the study of peptide interactions and modifications, contributing to advancements in drug design and protein engineering. -
Tripeptide
Enkephalin(1-3) is a tripeptide comprising L-tyrosine and two glycine residues. It primarily interacts with opioid receptors, exhibiting analgesic properties. This compound is essential for research in pain modulation, neurobiology, and the study of endogenous opioid systems. -
Dipeptide
Fmoc-Asn(Trt)-Thr(psi(Me,Me)pro)-OH is a modified dipeptide that incorporates a protected asparagine and threonine residue with a unique psi(Me,Me) proline moiety. This compound serves as a valuable building block for peptide synthesis and can be employed in the development of bioactive peptidomimetics. Its structural modifications enhance stability and conformational properties, making it suitable for various biochemical studies and drug design applications. -
Amino Acid Derivative
[3,5 Diiodo-Tyr7] Peptide T is an amino acid derivative that serves as a modified form of threonine. This compound exhibits unique biochemical properties and is employed in research focused on peptide synthesis and characterization. Its structural modifications may facilitate investigations into peptide interactions and functionality in biological systems. -
Dipeptide
H-Ser-Tyr-OH is a dipeptide comprised of serine and tyrosine residues. This compound exhibits the ability to form stable complexes with copper(II) ions, which may facilitate studies in metalloprotein interactions and bioinorganic chemistry. H-Ser-Tyr-OH serves as a useful reagent in research applications involving peptide structure-function relationships and metal ion coordination in biological systems. -
Dipeptide
Beta-Asp-His is a dipeptide composed of aspartic acid and histidine that demonstrates the ability to form amino acid derivatives through complexation with zinc. This compound is of interest in biochemical research for its potential applications in enzyme regulation and metal-ion interactions. It may be utilized in studies focusing on zinc-dependent biological processes and the development of therapeutics targeting metalloproteins. -
Tripeptide
H-Gly-Sar-Sar-OH is a tripeptide that exhibits oral bioactivity. It is efficiently transported through the peptide transporter 1 (PepT1) in Caco-2 cell models, suggesting its potential for enhanced absorption in therapeutic applications. This compound may be utilized in research focused on peptide transport mechanisms and material bioavailability. -
Dipeptide
Fmoc-Ile-Thr(psi(Me,Me)pro)-OH is a dipeptide that incorporates a constrained proline analogue. This compound is designed to serve as a building block in the synthesis of peptides and proteins, offering enhanced stability and conformational rigidity. Its unique structure makes it valuable in research applications focused on peptide design, drug discovery, and the study of protein interactions. -
Dipeptide
Fmoc-Lys(Boc)-Thr(psi(Me,Me)pro)-OH is a dipeptide that incorporates a lysine residue protected by a Boc group and a threonine analog with a modified proline structure. This compound is utilized in peptide synthesis and modifications for the exploration of peptide pharmacodynamics and structure-activity relationships. Its unique structural features enable researchers to study protein interactions and develop novel therapeutic agents.

