2013-12-9

Basic information

• Product Name: D(-)-Norvaline
• Synonyms: H-D-NVA-OH;H-D-NHCH[CH3(CH2)2]-COOH;H-D-NORVALINE;H-D-APE(2)-OH;D(-)-NORVALINE;D-NORVALINE;D(-)-2-AMINOVALERIC ACID;D-2-AMINOVALERIC ACID
• CAS NO: 2013-12-9
• Molecular Formula: C₅H₁₁NO₂
• Molecular Weight: 117.15
• EINECS: 217-936-2
• Product Categories: Norvaline [Nva];Amino Acids;Peptide
• Mol File: 2013-12-9.mol

Chemical Properties

• Melting Point: >300 °C(lit.)
• Boiling Point: 222.9 °C at 760 mmHg
• Flash Point: 88.6 °C
• Appearance: white to off-white crystals or crystalline powder
• Density: 1.2000 (estimate)
• Vapor Pressure: 0.0366mmHg at 25°C
• Refractive Index: -25 ° (C=10, 6mol/L HCl)
• Storage Temp.: Store at RT.
• Solubility: Aqueous Acid (Slightly), Water (Slightly)
• PKA: 2.54±0.20(Predicted)
• Water Solubility: SOLUBLE
• Merck: 14,6716
• BRN: 1721161
• CAS DataBase Reference: D(-)-Norvaline(CAS DataBase Reference)
• NIST Chemistry Reference: D(-)-Norvaline(2013-12-9)
• EPA Substance Registry System: D(-)-Norvaline(2013-12-9)

Safety Data

• Hazard Codes: Xn
• Statements: 20/21/22-36/37/38
• Safety Statements: 22-24/25-37/39-26
• WGK Germany: 3
• Hazardous Substances Data: 2013-12-9(Hazardous Substances Data)

Usage

Uses

Used in Chemical Synthesis:
D(-)-Norvaline is used as a catalyst in the enantioselective α-bromination of carbonyl and 1,3-dicarbonyl compounds. Its chiral nature allows for the selective formation of desired enantiomers, which is crucial in the synthesis of biologically active compounds.
Used in Pharmaceutical Industry:
D(-)-Norvaline is incorporated into jadomycins, a group of compounds widely used as antibiotics. The incorporation of D(-)-Norvaline into these compounds enhances their antimicrobial properties, making them more effective against a range of bacterial infections.
Used in Anticancer Research:
D(-)-Norvaline is also used in the development of compounds with potential antiproliferative and anti-cancer properties. Its unique structure allows for the design of novel therapeutic agents that can target and inhibit the growth of cancer cells, offering new treatment options for various types of cancer.

InChI:InChI=1/C5H11NO2/c1-2-3-4(6)5(7)8/h4H,2-3,6H2,1H3,(H,7,8)/t4-/m1/s1

Upstream product

• 1116-19-4 DL-α-alanyl-DL-norvaline 
• 206068-37-3 (R)-2-((R)-2-Oxo-4-phenyl-oxazolidin-3-yl)-pentanoic acid 
• 1821-02-9 2-oxopentanoic acid 
• 108341-16-8 D,L-norvaline benzyl ester hydrochloride 
• 6600-40-4 L-Norvaline 
• 328-50-7 α-ketoglutaric acid 
• 760-78-1 2-aminopentanoic acid 
• 700-63-0 (R)-phenylglycine amide 
• 338-69-2 D-Alanine 
• 13893-43-1 ethyl 2-aminopentanoate 
• 6940-47-2 N-Chloroacetyl norvaline 
• 105763-28-8 (2R,3R)-1,2-O-isopropylidene-3-phthalimidohexane-1,2-diol 
• 105763-35-7 (2R,3R)-3-phthalimidohexane-1,2-diol 
• 105763-38-0 (2R)-phthalimdopentanal 

Downstream Products

• 96382-73-9 (S)-2-((S)-2-{(R)-2-[(S)-2-Amino-3-(4-hydroxy-phenyl)-propionylamino]-pentanoylamino}-3-phenyl-propionylamino)-succinamide 
• 6155-96-0 (2R)-2-Chloropentanoic acid 
• 21685-17-6 (R)-(-)-norvaline methyl ester 
• 144701-24-6 (R)-2-(((9H-fluoren-9-yl)methoxy)carbonylamino)pentanoic acid 
• 23358-62-5 (S) norvaline ethyl ester hydrochloride 
• 108340-61-0 (R)-1,2-pentanediol 
• 319-78-8 D-Isoleucine 
• 350-21-0 (R)-2-(2,2,2-trifluoroacetamido)pentanoic acid 
• 116611-58-6 (R)-2-tert-butoxycarbonylaminopentanoic acid methyl ester 
• 2025376-01-4 (R)-2-aminopentan-1-ol hydrochloric acid salt 
• 6600-40-4 L-Norvaline 
• 928025-41-6 (R)-1-benzyl-3-propylpiperazine 

Relevant articles and documents

Enantioselective synthesis of α-alkenyl α-amino acids via N-H insertion reactions

A new highly enantioselective route to α-alkenyl α-amino acid derivatives, which are important naturally occurring compounds with attractive bioactivity and synthetic utility, was developed using a N-H insertion reaction of vinyldiazoacetates and tert-butyl carbamate cooperatively catalyzed by achiral dirhodium(ii) carboxylates and chiral spiro phosphoric acids under mild, neutral conditions. This reaction has a broad substrate scope, a fast reaction rate (turnover frequency > 6000 h-1), a high yield (61-99%), and excellent enantioselectivity (83-98% ee). The chiral spiro phosphoric acid, which is proposed to realize the enantioselectivity of the insertion reaction by promoting the proton transfer of a ylide intermediate by acting as a chiral proton shuttle catalyst, can suppress several usual side reactions of vinyldiazoacetates and broaden the applications of these versatile carbene precursors in organic synthesis. To our knowledge, it is the first highly enantioselective carbene insertion reaction of vinyldiazoacetates with heteroatom-hydrogen bonds in which the heteroatom has lone-pair electrons.

A green and expedient synthesis of enantiopure diketopiperazines via enzymatic resolution of unnatural amino acids

Dipeptides comprising a d-phenylglycyl moiety coupled to the l-enantiomer of 2-amino butyric acid, norvaline, norleucine, and homocysteine were successfully synthesized from d-phenylglycine amide and the racemate of the corresponding unnatural amino acid.

Stereodivergent addition of allylmetal reagents to imines derived from (R)2,3-Di-O-benzylglyceraldehyde by appropriate selection of metal and double stereodifferentiation

The addition of allylmetal reagents to N-benzylimines derived from (R)-2,3-di-O-benzylglyceraldehyde has been achieved with high yields and diastereoselectivities. Homoallylamine 2a of syn configuration is obtained preferentially with allylmagnesium bromide, whereas homoallylamine 2a of anti configuration is obtained as the major reaction product with allyl-9-borabicyclo[3.3.1]nonane. Appropriate combinations of the allylmetal reagent and imines derived from (R)-2,3-di-O-benzylglyceraldehyde and (S)- or (R)-1-phenylethylamine afforded syn or anti homoallylamines with total stereocontrol through double stereodifferentiation processes. Wiley-VCH Verlag GmbH, 69451 Weinheim, Germany, 2002.

Highly selective synthesis of d-amino acids from readily available l-amino acids by a one-pot biocatalytic stereoinversion cascade

d-Amino acids are key intermediates required for the synthesis of important pharmaceuticals. However, establishing a universal enzymatic method for the general synthesis of d-amino acids from cheap and readily available precursors with few by-products is challenging. In this study, we constructed and optimized a cascade enzymatic route involving l-amino acid deaminase and d-amino acid dehydrogenase for the biocatalytic stereoinversions of l-amino acids into d-amino acids. Using l-phenylalanine (l-Phe) as a model substrate, this artificial biocatalytic cascade stereoinversion route first deaminates l-Phe to phenylpyruvic acid (PPA) through catalysis involving recombinant Escherichia coli cells that express l-amino acid deaminase from Proteus mirabilis (PmLAAD), followed by stereoselective reductive amination with recombinant meso-diaminopimelate dehydrogenase from Symbiobacterium thermophilum (StDAPDH) to produce d-phenylalanine (d-Phe). By incorporating a formate dehydrogenase-based NADPH-recycling system, d-Phe was obtained in quantitative yield with an enantiomeric excess greater than 99%. In addition, the cascade reaction system was also used to stereoinvert a variety of aromatic and aliphatic l-amino acids to the corresponding d-amino acids by combining the PmLAAD whole-cell biocatalyst with the StDAPDH variant. Hence, this method represents a concise and efficient route for the asymmetric synthesis of d-amino acids from the corresponding l-amino acids.

One-Pot Preparation of d-Amino Acids Through Biocatalytic Deracemization Using Alanine Dehydrogenase and Ω-Transaminase

d-Amino acids are pharmaceutically important building blocks, leading to a great deal of research efforts to develop cost-effective synthetic methods. Preparation of d-amino acids by deracemization has been conceptually attractive owing to facile synthesis of racemic amino acids by Strecker synthesis. Here, we demonstrated biocatalytic deracemization of aliphatic amino acids into d-enantiomers by running cascade reactions; (1) stereoinversion of l-amino acid to a d-form by amino acid dehydrogenase and ω-transaminase and (2) regeneration of NAD+ by NADH oxidase. Under the cascade reaction conditions containing 100?mM isopropylamine and 1?mM NAD+, complete deracemization of 100?mM dl-alanine was achieved after 24?h with 95% reaction yield of d-alanine (> 99% eeD, 52% isolation yield). Graphical Abstract: [Figure not available: see fulltext.].

Structure-guided engineering of: Meso -diaminopimelate dehydrogenase for enantioselective reductive amination of sterically bulky 2-keto acids

meso-Diaminopimelate dehydrogenase (DAPDH) and mutant enzymes are an excellent choice of biocatalysts for the conversion of 2-keto acids to the corresponding d-amino acids. However, their application in the enantioselective reductive amination of bulky 2-keto acids, such as phenylglyoxylic acid, 2-oxo-4-phenylbutyric acid, and indole-3-pyruvic acid, is still challenging. In this study, the structure-guided site-saturation mutagenesis of a Symbiobacterium thermophilum DAPDH (StDAPDH) gave rise to a double-site mutant W121L/H227I, which showed dramatically improved enzyme activities towards various 2-keto acids including these sterically bulky substrates. Several d-amino acids were prepared in optically pure form. The molecular docking of substrates into the active sites of wild-type and mutant W121L/H227I enzymes revealed that the substrate binding cavity of the mutant enzyme was reshaped to accommodate these bulky substrates, thus leading to higher enzyme activity. These results lay a foundation for further shaping the substrate binding pocket and manipulating the interactions between the substrate and binding sites to access highly active d-amino acid dehydrogenases for the preparation of synthetically challenging d-amino acids.

Asymmetric Transamination of α-Keto Acids Catalyzed by Chiral Pyridoxamines

A new type of novel chiral pyridoxamines 3a-g containing a side chain has been developed. The pyridoxamines displayed catalytic activity and promising enantioselectivity in biomimetic asymmetric transamination of α-keto acids, to give various α-amino acids in 47-90% yields with up to 87% ee's under very mild conditions. An interesting effect of the side chain on enantioselectivity was observed in the reaction.

Deracemization of amino acids by coupling transaminases of opposite stereoselectivity

Biocatalytic deracemization of amino acids without relying on oxidase-based deamination of an unwanted enantiomer was demonstrated by coupling a-and w-transaminases displaying opposite stereoselectivity. This strategy employs isopropylamine and a keto acid as cosubstrates and is free of generation of hydrogen peroxide which is troublesome in the conventional oxidase-based methods.

Biocatalytic asymmetric synthesis of unnatural amino acids through the cascade transfer of amino groups from primary amines onto keto acids

Flee to the hills: An unfavorable equilibrium in the amino group transfer between amino acids and keto acids catalyzed by α-transaminases was successfully overcome by coupling with a ω-transaminase reaction as an equilibrium shifter, leading to efficient asymmetric synthesis of diverse unnatural amino acids, including L-tert-leucine and D-phenylglycine. Copyright

Characterization of d-amino acid aminotransferase from Lactobacillus salivarius

We searched a UniProt database of lactic acid bacteria in an effort to identify d-amino acid metabolizing enzymes other than alanine racemase. We found a d-amino acid aminotransferase (d-AAT) homologous gene (UniProt ID: Q1WRM6) in the genome of Lactobacillus salivarius. The gene was then expressed in Escherichia coli, and its product exhibited transaminase activity between d-alanine and α-ketoglutarate. This is the first characterization of a d-AAT from a lactic acid bacterium. L. salivarius d-AAT is a homodimer that uses pyridoxal-5′-phosphate (PLP) as a cofactor; it contains 0.91 molecules of PLP per subunit. Maximum activity was seen at a temperature of 60 °C and a pH of 6.0. However, the enzyme lost no activity when incubated for 30 min at 30 °C and pH 5.5 to 9.5, and retained half its activity when incubated at pH 4.5 or 11.0 under the same conditions. Double reciprocal plots of the initial velocity and d-alanine concentrations in the presence of several fixed concentrations of α-ketoglutarate gave a series of parallel lines, which is consistent with a Ping-Pong mechanism. The Km values for d-alanine and α-ketoglutarate were 1.05 and 3.78 mM, respectively. With this enzyme, d-allo-isoleucine exhibited greater relative activity than d-alanine as the amino donor, while α-ketobutylate, glyoxylate and indole-3-pyruvate were all more preferable amino acceptors than α-ketoglutarate. The substrate specificity of L. salivarius d-AAT thus differs greatly from those of the other d-AATs so far reported.