L-Asparagine methyl ester hydrochloride
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L-Asparagine methyl ester hydrochloride

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L-Asparagine methyl ester hydrochloride is a protected form of L-Asparagine. L-Asparagine was first isolated by Robiquet and Vauquelin from asparagus juice (a high source of L-asparagine). L-Asparagine is often incorporated into proteins, and is a basis for some cancer therapies as certain cancerous cells require L-asparagine for growth.

Category
L-Amino Acids
Catalog number
BAT-003964
CAS number
57461-34-4
Molecular Formula
C5H10N2O3.HCl
Molecular Weight
182.61
L-Asparagine methyl ester hydrochloride
IUPAC Name
methyl (2S)-2,4-diamino-4-oxobutanoate;hydrochloride
Synonyms
L-Asparagine, methyl ester, hydrochloride (1:1); L-Asparagine, methyl ester, monohydrochloride; Methyl L-asparaginate hydrochloride; L-Asn-OMe HCl; L-Asparagine Methyl Ester HCl; (S)-Methyl 2,4-diamino-4-oxobutanoate hydrochloride
Related CAS
6384-09-4 (free base)
Appearance
Off-white powder
Purity
≥95%
Storage
Store at 2-8°C
InChI
InChI=1S/C5H10N2O3.ClH/c1-10-5(9)3(6)2-4(7)8;/h3H,2,6H2,1H3,(H2,7,8);1H/t3-;/m0./s1
InChI Key
QOMQXHIJXUDQSS-DFWYDOINSA-N
Canonical SMILES
COC(=O)C(CC(=O)N)N.Cl

L-Asparagine methyl ester hydrochloride is a chemical compound with multiple applications in biosciences and related fields. Here are some key applications of L-Asparagine methyl ester hydrochloride:

Peptide Synthesis: L-Asparagine methyl ester hydrochloride is used as an intermediate in the synthesis of peptides and proteins. It aids in forming peptide bonds during the assembly of amino acid sequences. This is crucial for the production of synthetic peptides utilized in research, pharmaceuticals, and biotechnology.

Drug Development: This compound is employed in medicinal chemistry to develop and optimize new therapeutic agents. It can serve as a substrate for enzymatic reactions or as a chemical building block in the synthesis of drug candidates. Researchers use it to explore structure-activity relationships and enhance the efficacy of therapeutic compounds.

Nutritional Supplements: L-Asparagine methyl ester hydrochloride is also used in the formulation of nutritional supplements. As a derivative of asparagine, it can potentially improve the bioavailability of amino acids in dietary products. This helps in meeting the nutritional needs of individuals requiring amino acid supplementation.

Biochemical Research: In biochemical studies, L-Asparagine methyl ester hydrochloride serves as a tool for investigating protein and enzyme functions. By incorporating it into experimental systems, scientists can study protein folding, stability, and interactions. This provides valuable insights into molecular mechanisms and protein engineering.

1. Directed evolution of alpha-aspartyl dipeptidase from Salmonella typhimurium
X Kong, Y Liu, X Gou, S Zhu, H Zhang, X Wang, J Zhang Biochem Biophys Res Commun. 2001 Nov 23;289(1):137-42. doi: 10.1006/bbrc.2001.5937.
Model-free approaches (error-prone PCR to introduce random mutations, DNA shuffling to combine positive mutations, and screening of the resultant mutant libraries) have been used to enhance the catalytic activity and thermostability of alpha-aspartyl dipeptidase from Salmonella typhimurium, which is uniquely able to hydrolyze Asp-X dipeptides (where X is any amino acid) and one tripeptide (Asp-Gly-Gly). Under double selective pressures of activity and thermostability, through two rounds of error-prone PCR and three sequential generations of DNA shuffling, coupled with screening, a mutant pepEM3074 with approximately 47-fold increased enzyme activity compared with its wild-type parent was obtained. Moreover, the stability of pepEM3074 is increased significantly. Three amino acid substitutions (Asn89His, Gln153Glu, and Leu205Arg), two of them are near the active site and substrate binding pocket, were identified by sequencing the genes encoding this evolved enzyme. The mechanism of the enhancement of activity and stability was analyzed in this paper.
2. Peptide synthesis of aspartame precursor using organic-solvent-stable PST-01 protease in monophasic aqueous-organic solvent systems
Shotaro Tsuchiyama, Noriyuki Doukyu, Masahiro Yasuda, Kosaku Ishimi, Hiroyasu Ogino Biotechnol Prog. 2007 Jul-Aug;23(4):820-3. doi: 10.1021/bp060382y. Epub 2007 May 5.
The PST-01 protease is a metalloprotease that has zinc ion at the active center and is very stable in the presence of water-soluble organic solvents. The reaction rates and the equilibrium yields of the aspartame precursor N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester (Cbz-Asp-Phe-OMe) synthesis from N-carbobenzoxy-L-aspartic acid (Cbz-Asp) and L-phenylalanine methyl ester (Phe-OMe) in the presence of water-soluble organic solvents were investigated under various conditions. Higher reaction rate and yield of Cbz-Asp-Phe-OMe were attained by the PST-01 protease when 30 mM Cbz-Asp and 500 mM Phe-OMe were used. The maximum reaction rate was obtained pH 8.0 and 37 degrees C. In the presence of dimethylsulfoxide (DMSO), glycerol, methanol, and ethylene glycol, higher reaction rates were obtained. The equilibrium yield was the highest in the presence of DMSO. The equilibrium yield of Cbz-Asp-Phe-OMe using the PST-01 protease attained 83% in the presence of 50% (v/v) DMSO.
3. Purification of Synechocystis sp. strain PCC6308 cyanophycin synthetase and its characterization with respect to substrate and primer specificity
E Aboulmagd, F B Oppermann-Sanio, A Steinbüchel Appl Environ Microbiol. 2001 May;67(5):2176-82. doi: 10.1128/AEM.67.5.2176-2182.2001.
Synechocystis sp. strain PCC6308 cyanophycin synthetase was purified 72-fold in three steps by anion exchange chromatography on Q Sepharose, affinity chromatography on the triazine dye matrix Procion Blue HE-RD Sepharose, and gel filtration on Superdex 200 HR from recombinant cells of Escherichia coli. The native enzyme, which catalyzed the incorporation of arginine and aspartic acid into cyanophycin, has an apparent molecular mass of 240 +/- 30 kDa and consists of identical subunits of 85 +/- 5 kDa. The K(m) values for arginine (49 microM), aspartic acid (0.45 mM), and ATP (0.20 mM) indicated that the enzyme had a high affinity towards these substrates. During in vitro cyanophycin synthesis, 1.3 +/- 0.1 mol of ATP per mol of incorporated amino acid was converted to ADP. The optima for the enzyme-catalyzed reactions were pH 8.2 and 50 degrees C, respectively. Arginine methyl ester (99.5 and 97% inhibition), argininamide (99 and 96%), S-(2-aminoethyl) cysteine (43 and 42%), beta-hydroxy aspartic acid (35 and 37%), aspartic acid beta-methyl ester (38 and 40%), norvaline (0 and 3%), citrulline (9 and 7%), and asparagine (2 and 0%) exhibited an almost equal inhibitory effect on the incorporation of both arginine and aspartic acid, respectively, when these compounds were added to the complete reaction mixture. In contrast, the incorporation of arginine was diminished to a greater extent than that of aspartic acid, respectively, with canavanine (82 and 53%), lysine (36 and 19%), agmatine (33 and 25%), D-aspartic acid (37 and 30%), L-glutamic acid (13 and 5%), and ornithine (23 and 11%). On the other hand, canavanine (45% of maximum activity) and lysine (13%) stimulated the incorporation of aspartic acid, whereas aspartic acid beta-methyl ester (53%) and asparagine (9%) stimulated the incorporation of arginine. [(3)H]lysine (15% of maximum activity) and [(3)H]canavanine (13%) were incorporated into the polymer, when they were either used instead of arginine or added to the complete reaction mixture, whereas L-glutamic acid was not incorporated. No effect on arginine incorporation was obtained by the addition of other amino acids (i.e., alanine, histidine, leucine, proline, tryptophan, and glycine). Various samples of chemically synthesized poly-alpha,beta-D,L-aspartic acid served as primers for in vitro synthesis of cyanophycin, whereas poly-alpha-L-aspartic acid was almost inactive.
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