N-α-Acetyl-L-aspartic acid α,β-dimethyl ester
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N-α-Acetyl-L-aspartic acid α,β-dimethyl ester

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Category
β−Amino Acids
Catalog number
BAT-005930
CAS number
57289-64-2
Molecular Formula
C8H13NO5
Molecular Weight
203.19
N-α-Acetyl-L-aspartic acid α,β-dimethyl ester
IUPAC Name
dimethyl (2S)-2-acetamidobutanedioate
Synonyms
Ac-Asp(OMe)-OMe
InChI
InChI=1S/C8H13NO5/c1-5(10)9-6(8(12)14-3)4-7(11)13-2/h6H,4H2,1-3H3,(H,9,10)/t6-/m0/s1
InChI Key
VRPXVQSXUIFMKQ-LURJTMIESA-N
Canonical SMILES
CC(=O)NC(CC(=O)OC)C(=O)OC

N-α-Acetyl-L-aspartic acid αβ-dimethyl ester is a specialized chemical compound with applications in several fields of bioscience. Here are some noteworthy applications of N-α-Acetyl-L-aspartic acid αβ-dimethyl ester:

Neurochemistry: N-α-Acetyl-L-aspartic acid αβ-dimethyl ester is used as a precursor or intermediate in the synthesis of compounds that mimic or inhibit neurotransmitters. This allows researchers to study neurotransmitter functions and interactions within the brain. The data gathered helps in developing treatments for neurological disorders such as epilepsy and depression.

Peptide Synthesis: In the field of biochemistry, N-α-Acetyl-L-aspartic acid αβ-dimethyl ester is utilized in the synthesis of peptides. It provides a protected form of aspartic acid, facilitating the selective reaction of its functional groups. This is crucial for the production of biologically active peptides, which are used in research and therapeutic applications.

Pharmacodynamics Studies: The compound is valuable for studying pharmacodynamics, specifically how drugs interact with aspartic acid pathways in the body. By using it in various assays, researchers can measure the efficacy and potency of new drug candidates. These studies are important for the development of new medications targeting diseases linked to aspartic acid pathways.

Chemical Biology: N-α-Acetyl-L-aspartic acid αβ-dimethyl ester is used in chemical biology to create modified amino acids or peptides that can probe biological systems. These modified compounds help scientists understand cellular processes at the molecular level. The insights gained are instrumental for the discovery of new biochemical pathways and potential drug targets.

1. Correlation between serum levels of some cholesterol precursors and activity of HMG-CoA reductase in human liver
I Björkhem, T Miettinen, E Reihnér, S Ewerth, B Angelin, K Einarsson J Lipid Res. 1987 Oct;28(10):1137-43.
The possibility that the serum concentrations of various cholesterol precursors may reflect the activity of the hepatic HMG-CoA reductase was investigated in humans under different conditions. The serum levels of squalene, free and esterified lanosterol, (4 alpha, 4 beta, 14 alpha-trimethyl-5 alpha-cholest-8, 24-dien-3 beta-ol), two dimethylsterols (4 alpha, 4 beta-dimethyl-5 beta-cholest-8-en-3 beta-ol and 4 alpha, 4 beta-dimethyl-5 alpha-cholest-8, 24-dien-3 beta-ol), two methostenols (4 alpha-methyl-5 alpha-cholest-7-en-3 beta-ol and 4 alpha-methyl-5 alpha-cholest-8-en-3 beta-ol), two lathosterols (5 alpha-cholest-7-en-3 beta-ol and 5 alpha-cholest-8-en-3 beta-ol) and desmosterol (cholest-5, 24-dien-3 beta-ol) were measured in untreated patients (n = 7) and patients treated with cholestyramine (QuestranR, 8 g twice daily for 2-3 weeks, n = 5) or chenodeoxycholic acid (15 mg/kg body weight daily for 3-4 weeks, n = 8) prior to elective cholecystectomy. The activity of the hepatic microsomal HMG-CoA reductase was measured in liver biopsies taken in connection with the operation.(ABSTRACT TRUNCATED AT 250 WORDS)
2. Specificity and formation of unusual amino acids of an amide ligation strategy for unprotected peptides
J P Tam, C Rao, C F Liu, J Shao Int J Pept Protein Res. 1995 Mar;45(3):209-16. doi: 10.1111/j.1399-3011.1995.tb01482.x.
An important step in the recently developed ligation strategy known as domain ligation strategy to link unprotected peptide segments without activation is the ring formation between the C-terminal ester aldehyde and the N-terminal amino acid bearing a beta-thiol or beta-hydroxide. A new method was developed to define the specificity of this reaction using a dye-labeled alanyl ester aldehyde to react with libraries of 400 dipeptides which contained all dipeptide combinations of the 20 genetically coded amino acids. Three different ester aldehydes of the dye-labeled alanine: alpha-formylmethyl (FM), beta-formylethyl (FE), and beta,beta,beta-dimethyl and formylethyl esters (DFE), were examined. The DFE ester was overly hindered and reacted with N-terminal Cys dipeptides (Cys-X). Interestingly, it also reacted slowly with the sequences of X-Gly where Gly was the second amino acid and the X-Gly amide bond participated in the ring formation. Although the FE ester reacted similarly as the FM ester in the ring formation, the subsequent O,N-acyl transfer was at least 30-fold slower than those of the FM-ester. The FM alpha-formyl methyl ester was the most suitable ester and was reactive with dipeptides of six N-terminal amino acids: Cys, Thr, Trp, Ser, His and Asn. The order and extent of their reactivity were highly dependent on pH, solvent and neighboring participation by the adjacent amino acid. In general, they could be divided into three categories. (1) N-Terminal Cys and Thr were the most reactive.(ABSTRACT TRUNCATED AT 250 WORDS)
3. In vitro anti-leishmanial activity of Prunus armeniaca fractions on Leishmania tropica and molecular docking studies
Nargis Shaheen, Naveeda Akhter Qureshi, Asma Ashraf, Aneeqa Hamid, Attiya Iqbal, Huma Fatima J Photochem Photobiol B. 2020 Dec;213:112077. doi: 10.1016/j.jphotobiol.2020.112077. Epub 2020 Nov 3.
Prunus armeniaca (L.) is a member of the Rosaceae, subfamily Prunoideae, shows anticancer, antitubercular, antimutagenic, antimicrobial, antioxidant, and cardioprotective activities. Here we fractionated the leaves extract of this highly medicinally important plant for antileishmanial activity. In the current study, the leaves extract was fractionated and characterized using column and thin layer chromatography by n-hexane, ethyl acetate, and methanol solvents. Twelve fractions were isolated and subjected for evaluation of their cytotoxicity and in vitro antileishmanial activity against promastigotes and amastigotes of Leishmania tropica. Among all fractions used, the fraction (F7) exhibited the strongest antileishmanial activity. The bioactive fraction was further characterized by spectroscopy (FTIR, UV-Vis), and GC-MS analysis. The in silico docking was carried out to find the active site of PTR1. All derived fractions exhibited toxicity in the safety range IC50 > 100 μg/ml. The fraction (F7) showed significantly the highest antipromastigotes activity with IC5011.48 ± 0.82 μg/ml and antiamastigotes activity with IC50 21.03 ± 0.98 μg/ml compared with control i.e. 11.60 ± 0.70 and 22.03 ± 1.02 μg/ml respectively. The UV-Vis spectroscopic analysis revealed the presence of six absorption peaks and the FTIR spectrum revealed the presence of alkane, aldehyde, carboxylic acid, thiols, alkynes, and carbonyls compounds The GC-MS chromatogram exhibited the presence of nine compounds: (a) benzeneethanol, alpha, beta dimethyl, (b)carbazic acid, 3-(1 propylbutylidene)-, ethyl ester, (c)1, 2-benzenedicarboxylic acid, diisooctyl ester, (d)benzeneethanamine a-methyl, (e)2aminononadecane, (f)2-heptanamine-5-methyl, (g)cyclobutanol, (h)cyclopropyl carbine, and (i)nitric acid, nonyl ester. Among all compounds, the 1, 2-benzenedicarboxylic acid, diisooctyl ester bound well to the PTR1 receptor. Fraction (F7) showed acceptable results with no cytotoxicity. However, in vivo studies are required in the future.
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