516-06-3

Basic information

• Product Name: DL-Valine
• Synonyms: (R,S)-2-Amino-3-methyl-butyricacid;DL-alpha-Aminoisovaleric acid;Valine, DL-;H-DL-VAL-OH;FEMA 3444;DL-VAL;DL-VALINE;DL-2-AMINO-3-METHYLBUTYRIC ACID
• CAS NO: 516-06-3
• Molecular Formula: C₅H₁₁NO₂
• Molecular Weight: 117.15
• EINECS: 208-220-0
• Product Categories: Valine [Val, V];alpha-Amino Acids;Amino Acids;Biochemistry;Amino Acids
• Mol File: 516-06-3.mol
• Article Data: 174

Chemical Properties

• Melting Point: 295 °C (dec.)(lit.)
• Boiling Point: 213.642 °C at 760 mmHg
• Flash Point: 83.008 °C
• Appearance: White/Crystalline Powder
• Density: 1.31
• Vapor Pressure: 0.0633mmHg at 25°C
• Refractive Index: 1.4650 (estimate)
• Storage Temp.: Store at RT.
• Solubility: Water (Slightly, Sonicated)
• PKA: pK1:2.32(+1);pK2:9.61(0) (25°C)
• Water Solubility: 68 g/L
• Merck: 14,9909
• BRN: 506689
• CAS DataBase Reference: DL-Valine(CAS DataBase Reference)
• NIST Chemistry Reference: DL-Valine(516-06-3)
• EPA Substance Registry System: DL-Valine(516-06-3)

Safety Data

• Hazard Codes: Xn
• Statements: 40
• Safety Statements: 22-24/25-36
• WGK Germany: 3
• RTECS: YV9355500
• TSCA: Yes
• Hazardous Substances Data: 516-06-3(Hazardous Substances Data)

Usage

Chemical Properties

Different sources of media describe the Chemical Properties of 516-06-3 differently. You can refer to the following data:
1. White crystalline powder
2. dl-Valine is odorless.

Occurrence

Reported found in many fruits, plants and animal tissues; in milk and dairy products.

Preparation

By the action of ammonia on α-bromoisovaleric acid; also through a hydantoin intermediate.

Definition

ChEBI: A branched-chain amino acid that consists of glycine in which one of the hydrogens attached to the alpha-carbon is substituted by an isopropyl group.

InChI:InChI=1/C5H11NO2/c1-3(2)4(6)5(7)8/h3-4H,6H2,1-2H3,(H,7,8)

Upstream product

• 412011-37-1 4-isopropylidene-2-thioxo-thiazolidin-5-one 
• 10323-40-7 2-bromoisovaleric acid 
• 3213-49-8 ethyl 2-isopropylcyanoacetate 
• 130030-02-3 α-acetylamino-α-cyano-isovaleric acid ethyl ester 
• 64724-68-1 diethyl 2-N-acetylamino-2-isopropylmalonate 
• 36963-34-5 α-phenylhydrazono-isovaleric acid 
• 78-84-2 isobutyraldehyde 
• 495-69-2 Hippuric Acid 
• 67-64-1 acetone 
• 1522-46-9 ethyl 2-isopropylacetoacetate 
• 72-18-4 L-valine 
• 759-05-7 3-methyl-2-ketobutanoic acid 
• 1197040-29-1 phenyl isocyanate 
• 60930-32-7 N-benzylidene-α-valine ethylester 

Downstream Products

• 78-84-2 isobutyraldehyde 
• 99977-10-3 N-[2]piperidylidene-valine 
• 2816-12-8 4-isopropyl-2,5-oxazolidinedione 
• 854007-21-9 (+/-)-N-(2-Thenyl)valin 
• 2325-17-9 Glycylvaline 
• 4289-97-8 N-formylvaline 
• 5625-50-3 cyclo-(Leu-Val) 
• 100402-24-2 N-(2-chloro-4-methyl-valeryl)-valine 
• 876858-57-0 N-(2-chloro-hexanoyl)-valine 
• 100483-40-7 N-[(2,4,5-trichloro-phenoxy)-acetyl]-DL-valine 
• 15985-67-8 N-phenylthioacetyl-valine 
• 139037-04-0 N-mesitylacetyl-valine 
• 121449-39-6 N-(N-benzoyl-glycyl)-valine 

Relevant articles and documents

Rational engineering ofAcinetobacter tandoiiglutamate dehydrogenase for asymmetric synthesis ofl-homoalanine through biocatalytic cascades

l-Homoalanine, a useful building block for the synthesis of several chiral drugs, is generally synthesized through biocascades using natural amino acids as cheap starting reactants. However, the addition of expensive external cofactors and the low efficiency of leucine dehydrogenases towards the intermediate 2-ketobutyric acid are two major challenges in industrial applications. Herein, a dual cofactor-dependent glutamate dehydrogenase fromAcinetobacter tandoii(AtGluDH) was identified to help make full use of the intracellular pool of cofactors when using whole-cell catalysis. Through reconstruction of the hydrophobic network between the enzyme and the terminal methyl group of the substrate 2-ketobutyric acid, the strict substrate specificity ofAtGluDH towards α-ketoglutarate was successfully changed, and the activity obtained by the most effective mutant (K76L/T180C) was 17.2 times higher than that of the wild-type protein. A three-enzyme co-expression system was successfully constructed in order to help release the mass transfer restriction. Using 1 Ml-threonine, which is close to the solubility limit, we obtained a 99.9% yield ofl-homoalanine in only 3.5 h without adding external coenzymes to the cascade, giving 99.9% ee and a 29.2 g L?1h?1space-time yield. Additionally, the activities of the engineeredAtGluDH towards some other hydrophobic amino acids were also improved to 1.1-11.2 fold. Therefore, the engineering design of some dual cofactor-dependent GluDHs could not only eliminate the low catalytic activity of unnatural substrates but also enhance the cofactor utilization efficiency of these enzymes in industrial applications.

Organocatalytic Enantioselective Addition of α-Aminoalkyl Radicals to Isoquinolines

With a dual organocatalytic system involving a chiral phosphoric acid and a dicyanopyrazine-derived chromophore (DPZ) photosensitizer and under the irradiation with visible light, an enantioselective Minisci-type addition of α-amino acid-derived redox-active esters (RAEs) to isoquinolines has been developed. A variety of prochiral α-aminoalkyl radicals generated from RAEs were successfully introduced on isoquinolines, providing a range of valuable α-isoquinoline-substituted chiral secondary amines in high yields with good to excellent enantioselectivities.

Catalytic Conversion of Alcohols to Carboxylic Acid Salts and Hydrogen with Alkaline Water

A [RuH(CO)(py-NP)(PPh3)2]Cl (1) catalyst is found to be effective for catalytic transformation of primary alcohols, including amino alcohols, to the corresponding carboxylic acid salts and two molecules of hydrogen with alkaline water. The reaction proceeds via acceptorless dehydrogenation of alcohol, followed by a fast hydroxide/water attack to the metal-bound aldehyde. A pyridyl-type nitrogen in the ligand architecture seems to accelerate the reaction.