498-18-0

Basic information

• Product Name: Δ-AMINOVALERIC ACID
• Synonyms: Δ-AMINOVALERIC ACID;Butalanine
• CAS NO: 498-18-0
• Molecular Formula: CH3(CH2)2CH(NH2)COOH
• Molecular Weight: 0
• Mol File: 498-18-0.mol
• Article Data: 90

Chemical Properties

• Appearance: /
• CAS DataBase Reference: Δ-AMINOVALERIC ACID(CAS DataBase Reference)
• NIST Chemistry Reference: Δ-AMINOVALERIC ACID(498-18-0)
• EPA Substance Registry System: Δ-AMINOVALERIC ACID(498-18-0)

Safety Data

• Hazardous Substances Data: 498-18-0(Hazardous Substances Data)

Upstream product

• 56548-09-5 2-acetylamino-2-cyano-valeric acid ethyl ester 
• 623-11-0 1-methyl-4-nitrosobenzene 
• 74-90-8 hydrogen cyanide 
• 40898-95-1 1-(-)-2-amino-1-butanol 
• 21486-54-4 2-hydroxyiminopentanoic acid 
• 6967-47-1 ethyl 2-cyanopentanoate 
• 82518-89-6 acetylamino-propyl-malonic acid diethyl ester 
• 64527-14-6 2-phenylhydrazono-valeric acid 
• 1821-02-9 2-oxopentanoic acid 
• 584-93-0 2-Bromovaleric acid 
• 7664-41-7 ammonia 
• 3209-39-0 2-amino-4-hydroxypentanoic acid 
• 5329-51-1 D-gluco-heptulose phenylosazone 
• 10034-85-2 hydrogen iodide 

Downstream Products

• 29774-87-6 4-propyl-oxazolidine-2,5-dione 
• 1176003-76-1 N-(toluene-4-sulfonyl)-norvaline 
• 21691-43-0 (R,S)-2-(N-benzyloxycarbonylamino)pentanoic acid 
• 62227-64-9 N-benzenesulfonyl-DL-norvaline 
• 65415-01-2 N-phenylacetyl-DL-norvaline 
• 96534-87-1 N-(N-acetyl-sulfanilyl)-norvaline 
• 80174-42-1 D,L-NorLeu-OBzl 
• 127862-67-3 N-benzyloxycarbonyl-DL-norvaline 2,2,2-trifluoroethyl ester 
• 95323-52-7 N-sulfanilyl-norvaline 
• 112245-05-3 D-norvaline benzyl ester 
• 56145-90-5 L-norvaline benzyl ester 
• 5632-87-1 N-benzoyl-D-norvaline 
• 5632-87-1 N-benzoyl-L-norvaline 
• 1380547-35-2 C₂₅H₃₁NO₅ 

Relevant articles and documents

Intramolecular General Base-Catalysis in Transaminations Catalyzed by Pyridoxamine Enzyme Analogues

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Biocatalysed synthesis of chiral amines: continuous colorimetric assays for mining amine-transaminases

In the course of our research aimed at the design of new biocatalytic processes for the enantioselective synthesis of chiral amines, we have developed new continuous assays for the screening of amine-transaminase collections. These assays are based on the use of hypotaurine as an irreversible amine donor. This β-aminosulfinic acid is converted upon transamination into 2-oxoethylsulfinic acid, which instantaneously decomposes into acetaldehyde and sulfite ions that can be easily detected by spectrophotometry using Ellman's reagent. Two complementary assays were developed based on this titration method. Firstly, a direct assay allowed detection of various transaminases able to use hypotaurine as an amino donor. In a second coupled assay,l-alanine is used as a generic donor substrate of amine-transaminases and is regenerated using an auxiliary hypotaurine-transaminase. The powerful and complementary nature of both assays was demonstrated through the screening of a collection of 549 amine-transaminases from biodiversity, thus allowing the discovery of a variety of valuable new biocatalysts for use in synthetic processes.

Semi-rational hinge engineering: modulating the conformational transformation of glutamate dehydrogenase for enhanced reductive amination activity towards non-natural substrates

The active site is the common hotspot for rational and semi-rational enzyme activity engineering. However, the active site represents only a small portion of the whole enzyme. Identifying more hotspots other than the active site for enzyme activity engineering should aid in the development of biocatalysts with better catalytic performance. Glutamate dehydrogenases (GluDHs) are promising and environmentally benign biocatalysts for the synthesis of valuable chirall-amino acids by asymmetric reductive amination of α-keto acids. GluDHs contain an inter-domain hinge structure that facilitates dynamic reorientations of the domains relative to each other. Such hinge-bending conformational motions of GluDHs play an important role in regulating the catalytic activity. Thus, the hinge region represents a potential hotspot for catalytic activity engineering for GluDHs. Herein, we report semi-rational activity engineering of GluDHs with the hinge region as the hotspot. Mutants exhibiting significantly improved catalytic activity toward several non-natural substrates were identified and the highest activity increase reached 104-fold. Molecular dynamics simulations revealed that enhanced catalytic activity may arise from improving the open/closed conformational transformation efficiency of the protein with hinge engineering. In the batch production of three valuablel-amino acids, the mutants exhibited significantly improved catalytic efficiency, highlighting their industrial potential. Moreover, the catalytic activity of several active site tailored GluDHs was also increased by hinge engineering, indicating that hinge and active site engineering are compatible. The results show that the hinge region is a promising hotspot for activity engineering of GluDHs and provides a potent alternative for developing high-performance biocatalysts toward chirall-amino acid production.