6665-16-3

Usage

Uses

Used in Nutritional Supplements:
SER-LEU is used as a nutritional supplement to support protein synthesis and muscle growth. The presence of both serine and leucine in this dipeptide may enhance the body's ability to build and repair muscle tissues, making it a valuable addition to the diets of athletes and individuals seeking to improve their physical performance.
Used in Pharmaceutical Applications:
In the pharmaceutical industry, SER-LEU may be used as a therapeutic agent for conditions related to muscle wasting or protein deficiency. The dipeptide's role in protein synthesis and muscle growth could potentially aid in the treatment of muscle-related disorders and support overall health.
Used in Cosmetics and Skincare:
SER-LEU is used as an ingredient in cosmetics and skincare products for its potential benefits in skin healing and regeneration. The presence of leucine, which supports skin health, may contribute to the development of products that promote skin repair and improve the appearance of damaged or aging skin.
Used in Research and Development:
In the field of research and development, SER-LEU may be utilized in studies exploring the mechanisms of protein synthesis, muscle growth, and the role of amino acids in overall health. This dipeptide could serve as a valuable tool for scientists investigating the potential therapeutic applications of amino acid combinations and their effects on various biological processes.

Upstream product

• 65519-48-4 3-hydroxymethyl-6-(2-methylpropyl)-2,5-diketopiperazine 
• 6209-12-7 N-leucyl-serine 
• 2767-17-1 N-(N-benzyloxycarbonyl-L-seryl)-L-leucine benzyl ester 
• 115220-80-9 Boc-Ser(OtBu)-Leu-OEt 
• 2768-55-0 N-Benzyloxycarbonyl-L-seryl-L-leucin 
• 61-90-5 L-leucine 
• 2743-40-0 L-leucine ethyl ester hydrochloride 

Downstream Products

• 700372-65-2 Z-Val-Ser-Leu-[methyl (3RS,4RS)-3,4-epoxypiperidine-3-carboxylate] 

Relevant academic research and scientific papers

Structure determination of lepidopteran c, self-defence substance produced by silkworm (bombyx mori)

Lepidopteran C is a minor component in a group of lepidopterans which are self-defence substances produced in haemolymph of silkworm. Its structure was determined by the Edman degradation of the whole molecule as well as the fragments obtained by digestion of Staphylococcus aureus V8 protease, proline specific endopeptidase, and trypsin. Although lepidopteran C is similar to A in amino acid sequence, 11 amino acids of A are substituted in the sequence of C.

DPP4 INHIBITOR AND PHARMACEUTICAL APPLICATION THEREOF

The present invention provides a Dpp4 inhibitor which comprises a leucine derivative of the following formula (1) or a methionine derivative of the following formula (2): wherein each R1 and R3 represents a hydrogen atom (H) and an L-amino acid residue; R2 represents a hydroxyl group (OH), alkoxy group having 1 to 6 carbon atoms, amino group (NH2), alkylamino group having 1 to 6 carbon atoms, glycine residue, β-alanine residue, L-amino acid (except for proline, alanine and phenylalanine) residue or L-amino-acid amide (except for proline amide, alanine amide and phenylalanine amide) residue; and R4 represents a hydroxyl group (OH), alkoxy group having 1 to 6 carbon atoms, amino group (NH2), alkylamino group having 1 to 6 carbon atoms, glycine residue, β-alanine residue, L-amino acid (except for proline and alanine) residue or L-amino-acid amide (except for proline amide and alanine amide) residue. These derivatives also act as autophagy regulators.

Proteasome inhibitors: Synthesis and activity of arecoline oxide tripeptide derivatives

We describe the synthesis and biological activities of a series of methyl 3,4-epoxypiperidine-3-carboxylate tripeptide derivatives that inhibit the chymotryptic and tryptic active sites of the 20S proteasome. Of the series, compound 2 which contains 3-hydroxy-2-methylbenzoyl group at its N-terminal position, displayed the greatest inhibitory potency (IC50 1 μM). All derivatives showed favourable pharmacokinetic properties.

Rates of reduction of N-chlorinated peptides by sulfite: Relevance to incomplete dechlorination of wastewaters

Biologically induced fragmentation of proteins during wastewater treatment produces peptides, which form long-lasting organic chloramines when the water is disinfected with Cl2. To protect aquatic wildlife from residual chlorine, including chloramines, wastewaters are often treated with sulfur dioxide or sulfite salts. This strategy incompletely eliminates residual chlorine species. Here we report that dechlorination rate constants of N- chloropeptides are 1-2 orders of magnitude smaller than those for NH2Cl and some aliphatic organic chloramines. Slow rates explain the prevalence of N- chloropeptides in dechlorinated wastewaters after faster reacting chlorine species have been eliminated. Dechlorination is subject to general acid catalysis. For N-chlorinated leucylalanine, the rate law above pH 6 in phosphate buffer at 25 °C and / ? 0.1 M is as follows: rate = (9.92 ± 0.41 x 103[H2PO4-] + 5.70 ± 0.52 x 108[H3O+] + 5.3 ± 0.2)[SO32-][Cl- Leu-Ala] (concentrations in M, time in s). Rate constants for other peptides appear to be of similar magnitude; variations in the acid-catalyzed terms among different hydrophobic peptides correlate with solvation energies of side chains. The kinetic data suggest that reducing N-chloropeptides in wastewaters by 75% or more will require reaction times generally >0.5 h at environmentally acceptable S(IV) doses and pH values. Biologically induced fragmentation of proteins during wastewater treatment produces peptides, which form long-lasting organic chloramines when the water is disinfected with Cl2. To protect aquatic wildlife from residual chlorine, including chloramines, wastewaters are often treated with sulfur dioxide or sulfite salts. This strategy incompletely eliminates residual chlorine species. Here we report that dechlorination rate constants of N-chloropeptides are 1-2 orders of magnitude smaller than those for NH2Cl and some aliphatic organic chloramines. Slow rates explain the prevalence of N-chloropeptides in dechlorinated wastewaters after faster reacting chlorine species have been eliminated. Dechlorination is subject to general acid catalysis. For N-chlorinated leucylalanine, the rate law above pH 6 in phosphate buffer at 25 °C and I≈0.1 M is as follows: rate = (9.92±0.41×103[H2 PO4- ]+5.70±0.52×108[ H3O+]+5.3±0.2) [SO32-][Cl-Leu-Ala] (concentrations in M, time in s). Rate constants for other peptides appear to be of similar magnitude; variations in the acid-catalyzed terms among different hydrophobic peptides correlate with solvation energies of side chains. The kinetic data suggest that reducing N-chloropeptides in wastewaters by 75% or more will require reaction times generally >0.5 h at environmentally acceptable SIV doses and pH values.