56613-61-7

Basic information

• Product Name: 4-Nitro-D-phenylalanine hydrate
• Synonyms: (2S)-2-Amino-3-(4-nitrophenyl)propanoic acid hydrate;3-(4-NITROPHENYL)-D-ALANINE;4-NITRO-D-PHENYLALANINE;D-4-NITROPHE;D-4-NITROPHENYLALANINE;D-(P-NO2)PHE-OH;H-P-NITRO-D-PHE-OH;H-D-PHE(4-NO2)-OH
• CAS NO: 56613-61-7
• Molecular Formula: C₉H₁₀N₂O₄
• Molecular Weight: 210.19
• EINECS: 213-446-8
• Product Categories: Amino Acids;Phenylalanine analogs and other aromatic alpha amino acids;Phenylalanine [Phe, F];Unusual Amino Acids;Amino Acids 13C, 2H, 15N;Amino Acids & Derivatives;Peptide Synthesis;Phenylalanine Derivatives;Unnatural Amino Acid Derivatives
• Mol File: 56613-61-7.mol

Chemical Properties

• Melting Point: 238-240 °C (decomp)
• Boiling Point: 414.1 °C at 760 mmHg
• Flash Point: 204.2 °C
• Appearance: Off-white powder
• Density: 1.408 g/cm³
• Storage Temp.: 2-8°C
• PKA: 2.12±0.10(Predicted)
• BRN: 3205966
• CAS DataBase Reference: 4-Nitro-D-phenylalanine hydrate(CAS DataBase Reference)
• NIST Chemistry Reference: 4-Nitro-D-phenylalanine hydrate(56613-61-7)
• EPA Substance Registry System: 4-Nitro-D-phenylalanine hydrate(56613-61-7)

Safety Data

• Hazard Codes: Xi,C,F
• Statements: 11-34
• Safety Statements: 22-24/25-45-36/37/39-26-16
• WGK Germany: 3
• Hazardous Substances Data: 56613-61-7(Hazardous Substances Data)

Usage

Uses

Used in Organic Synthesis:
4-Nitro-D-phenylalanine hydrate is used as a synthetic building block for the creation of various organic compounds. Its unique structure allows for the development of novel molecules with potential applications in different industries, such as pharmaceuticals, agrochemicals, and materials science.
Used in Pharmaceutical Industry:
In the pharmaceutical industry, 4-Nitro-D-phenylalanine hydrate is used as an intermediate in the synthesis of drugs targeting specific biological pathways. Its incorporation into drug molecules can lead to the development of new therapeutic agents with improved efficacy and selectivity.
Used in Research and Development:
4-Nitro-D-phenylalanine hydrate is also utilized in research and development settings to study the effects of nitro substitution on the properties and reactivity of D-phenylalanine derivatives. This knowledge can be applied to design and optimize new molecules with desired biological activities.
Used in Chemical Education:
As a compound with distinct chemical properties, 4-Nitro-D-phenylalanine hydrate can be employed in educational settings to demonstrate the principles of organic chemistry, stereochemistry, and functional group transformations.

Upstream product

• 63-91-2 L-phenylalanine 
• 673-06-3 D-(R)-phenylalanine 
• 1991-83-9 4-nitrophenylalanine 
• 619-89-6 p-nitrocinnamic acid 
• 949-99-5 4-nitro-3-phenyl-L-alanine 
• 882-06-4 4-nitro-trans-cinnamic acid 
• 150-30-1 Phenylalanine 
• 38335-24-9 3-(4-nitrophenyl)-2-oxopropanoic acid 
• 1627100-31-5 (S)-2-acetamido-3-[²H]-3(4-nitrophenyl)propanoic acid 
• 1627100-30-4 (R)-2-amino-3[(S)-²H]-3(4-nitrophenyl)propanoic acid hydrochloride 
• 1627099-66-4 (S)-methyl 2-acetamido-3-[2H]-3(4-nitrophenyl)propanoate 
• 1627099-40-4 (R)-methyl 2-acetamido-3[2H]-3(4-nitrophenyl)propanoate 
• 1627098-43-4 [4-²H]-methyl 2-acetamido-3(4-nitrophenyl)acrylate 
• 1627096-62-1 [4-²H]-4(4-nitrobenzylidene)-2-methyloxazol-5(4H)-one 

Downstream Products

• 99984-07-3 N-dichloroacetyl-4-nitro-phenylalanine 
• 82611-60-7 2-benzyloxycarbonylamino-3-(4-nitrophenyl)propionic acid 
• 85317-52-8 methyl 2-amino-3-(4-nitrophenyl)propionate 
• 86937-80-6 2-tert-butoxycarbonylamino-3-(4-nitro-phenyl)-propionic acid 
• 2922-41-0 (p-aminophenyl)alanine 
• 7664-41-7 ammonia 
• 144-62-7 oxalic acid 
• 62-23-7 4-nitro-benzoic acid 
• 59515-83-2 4-amino-3,5-diiodo-phenylalanine 
• 29553-99-9 N-acetyl-4-acetylamino-phenylalanine 
• 68319-36-8 N-acetyl-4-amino-phenylalanine 
• 99861-15-1 N-acetyl-4-amino-3,5-diiodo-phenylalanine 
• 89288-22-2 2-amino-3-(4-nitrophenyl)propan-1-ol 
• 326019-69-6 dichloroacetic acid-[(R or S)-1-hydroxymethyl-2-(4-nitro-phenyl)-ethylamide] 

Relevant articles and documents

Equilibrium of chiral extraction of 4-nitro-d,l-phenylalanine with BINAP metal complexes

The enantioselective extraction of 4-nitro-phenylalanine (Nphy) was studied with metal-2,2′-bis(diphenylphosphino)-1,1′-binaphthyl (BINAP) complexes as the chiral selector. The complex with palladium (BINAP-Pd) exhibits the highest selectivity out of the selectors studied, which is solubilised in the organic phase and preferentially extracts d-Nphy from the aqueous phase. Efficiency of extraction depends, often substantially, on a number of process variables, including types of organic solvents and metal precursors, concentration of ligand, pH, and temperature. A reactive extraction model was established to interpret the experimental data. The equilibrium formation constants and other important parameters required by the model were determined experimentally. The equilibrium formation constants were 6.73 and 1.93 for d-Nphy and l-Nphy. By way of modelling and experiment, an optimal extraction condition with pH of 7 and BINAP-Pd concentration of 1 mmol L-1 was obtained with enantioselectivity (α) of 3.37, which was close to the maximum of 3.48, and a performance factor (pf) of 0.195. The model was verified experimentally with excellent results.

A novel phenylalanine ammonia-lyase from Pseudozyma antarctica for stereoselective biotransformations of unnatural amino acids

A novel phenylalanine ammonia-lyase of the psychrophilic yeast Pseudozyma antarctica (PzaPAL) was identified by screening microbial genomes against known PAL sequences. PzaPAL has a significantly different substrate binding pocket with an extended loop (26 aa long) connected to the aromatic ring binding region of the active site as compared to the known PALs from eukaryotes. The general properties of recombinant PzaPAL expressed in E. coli were characterized including kinetic features of this novel PAL with L-phenylalanine (S)-1a and further racemic substituted phenylalanines rac-1b-g,k. In most cases, PzaPAL revealed significantly higher turnover numbers than the PAL from Petroselinum crispum (PcPAL). Finally, the biocatalytic performance of PzaPAL and PcPAL was compared in the kinetic resolutions of racemic phenylalanine derivatives (rac-1a-s) by enzymatic ammonia elimination and also in the enantiotope selective ammonia addition reactions to cinnamic acid derivatives (2a-s). The enantiotope selectivity of PzaPAL with o-, m-, p-fluoro-, o-, p-chloro- and o-, m-bromo-substituted cinnamic acids proved to be higher than that of PcPAL.

Investigation of Taniaphos as a chiral selector in chiral extraction of amino acid enantiomers

Finding chiral selector with high stereoselectivity to a variety of amino acid enantiomers remains a challenge and warrants further research. In this work, Taniaphos, a chiral ligand with rotatable spatial configuration, was employed as a chiral extractant to enantioseparate various amino acid enantiomers. Phenylalanine (Phe), homophenylalanine (Hphe), 4-nitrophenylalanine (Nphe), and 3-chloro-phenylglycine (Cpheg) were used as substrates to evaluate the extraction efficiency. The results revealed that Taniaphos-Cu exhibited good abilities to enantioseparate Phe, Hphe, Nphe, and Cpheg with the highest separation factors (α) of 3.13, 2.10, 2.32, and 2.14, respectively. Taniaphos-Cu is more conducive to combine with D-amino acid in extraction. The influences of pH, Taniaphos-Cu, and concentration and extraction temperature on extraction were comprehensively evaluated. The highest performance factors (pf) for Phe, Hphe, Nphe, and Cpheg at optimal extraction conditions were 0.08892, 0.1250, 0.09621, and 0.08021, respectively. The recognition mechanism between Taniaphos-Cu and amino acid enantiomers was discussed. The coordination interaction between Taniaphos-Cu and -COO?, π-π interaction between Taniaphos-Cu and amino acid enantiomers are important acting forces in chiral extraction. The steric-hindrance between -NH2 and -OH lead to Taniaphos-Cu-D-Phe is more stable than Taniaphos-Cu-L-Phe. This work provided a chiral extractant that has good abilities to enantioseparate various amino acid enantiomers.

Reconstruction of Hyper-Thermostable Ancestral L-Amino Acid Oxidase to Perform Deracemization to D-Amino Acids

L-amino acid oxidases (LAAOs) with broad substrate specificity can be used in the deracemization of D,L-amino acids (D,L-AAs) to their D-enantiomers. Hyper-thermostable LAAO (HTAncLAAO) was designed through a combination of manual sequence data mining and ancestral sequence reconstruction. Soluble expression of HTAncLAAO (>50 mg/L) can be achieved using an E. coli system. HTAncLAAO, which recognizes seven L-AAs as substrates, exhibits extremely high thermal stability and long-term stability; the t1/2 value was 95 °C and 99 % ee, D-enantiomer). These results suggest that HTAncLAAO is an excellent biocatalyst to perform this deracemization.

Self-assembling behaviour of a modified aromatic amino acid in competitive medium

Aromatic amino acid, specifically phenylalanine (Phe), is one of the most studied building blocks in peptide synthesis due to its importance in biology. It is reported in the literature that Phe-containing peptides have a high tendency to form different self-assembled materials due to efficient aromatic-aromatic interactions. In this article, we have tuned the supramolecular interactions of phenylalanine by making it electron-deficient upon introduction of the nitro group in the ring. The presence of the nitro group has a profound influence on the self-assembly process. It has been observed that 4-nitrophenylalanine (4NP) is a highly efficient gelator compared with the native phenylalanine in DMSO solvent in terms of minimum gelation concentration and it forms hydrogen bonding mediated crystals in water. The change of self-assembling patterns of 4NP in these solvents was studied using X-ray diffraction, UV-Vis spectroscopy, FE-SEM and other techniques. With the help of different experimental data and density functional theory (DFT), we have simulated the theoretical structure of 4NP in DMSO. The theoretical structure of 4NP in DMSO is different compared with that of crystals in water. We then studied the self-assembly process of 4NP in the mixed solvent of DMSO (polar aprotic) and water (polar protic). Different competitive non-covalent interactions of solvents as well as the ratio of the solvent mixture guide the final self-assembly state of 4NP. This journal is

Bi-enzymatic Conversion of Cinnamic Acids to 2-Arylethylamines

The conversion of carboxylic acids, such as acrylic acids, to amines is a transformation that remains challenging in synthetic organic chemistry. Despite the ubiquity of similar moieties in natural metabolic pathways, biocatalytic routes seem to have been overlooked for this purpose. Herein we present the conception and optimisation of a two-enzyme system, allowing the synthesis of β-phenylethylamine derivatives from readily-available ring-substituted cinnamic acids. After characterisation of both parts of the reaction in a two-step approach, a set of conditions allowing the one-pot biotransformation was optimised. This combination of a reversible deaminating and irreversible decarboxylating enzyme, both specific for the amino acid intermediate in tandem, represents a general method by which new strategies for the conversion of carboxylic acids to amines could be designed.

Deracemization and stereoinversion to aromatic d-amino acid derivatives with ancestral l-amino acid oxidase

Enantiomerically pure amino acid derivatives could be foundational compounds for peptide drugs. Deracemization of racemates to l-amino acid derivatives can be achieved through the reaction of evolved d-amino acid oxidase and chemical reductants, whereas deracemization to d-amino acid derivatives has not progressed due to the difficulty associated with the heterologous expression of l-amino acid oxidase (LAAO). In this study, we succeeded in developing an ancestral LAAO (AncLAAO) bearing broad substrate selectivity (13 l-amino acids) and high productivity through an Escherichia coli expression system (50.7 mg/L). AncLAAO can be applied to perform deracemization to d-amino acids in a similar way to deracemization to l-amino acids. In fact, full conversion (>99% ee, d-form) could be achieved for 16 racemates, including nine d,l-Phe derivatives, six d,l-Trp derivatives, and a d,l-phenylglycine. Taken together, we believe that AncLAAO could be a key enzyme to obtain optically pure d-amino acid derivatives in the future.

Nitration of Tyrosine in the Mucin Glycoprotein of Edible Bird's Nest Changes Its Color from White to Red

The edible bird's nest (EBN) of the swiftlet Aerodramus fuciphagus, a mucin glycoprotein, is usually white in color, but there also exist the more desirable red or "blood" EBN. The basis of the red color has been a puzzle for a long time. Here, we show that the nitration of the tyrosyl residue to the 3-nitrotyrosyl (3-NTyr) residue in the glycoprotein is the cause of the red color. Evidence for the 3-NTyr residue comes from (a) the quantitative analysis of 3-NTyr in EBN by enzyme-linked immunosorbent assay, (b) the ultraviolet-visible absorption spectra of red EBN as a function of pH being similar to 3-nitrotyrosine (3-NT), (c) the change in the color of red EBN from yellow at low pH to red at high pH just like 3-NT, and (d) strong Raman nitro bands at 1330 cm-1 (symmetric -NO2 stretch) and 825 cm-1 (-NO2 scissoring bend) for red EBN. The high concentrations of nitrite and nitrate in red EBN are also explained.

Evaluation of the Edman degradation product of vancomycin bonded to core-shell particles as a new HPLC chiral stationary phase

A modified macrocyclic glycopeptide-based chiral stationary phase (CSP), prepared via Edman degradation of vancomycin, was evaluated as a chiral selector for the first time. Its applicability was compared with other macrocyclic glycopeptide-based CSPs: TeicoShell and VancoShell. In addition, another modified macrocyclic glycopeptide-based CSP, NicoShell, was further examined. Initial evaluation was focused on the complementary behavior with these glycopeptides. A screening procedure was used based on previous work for the enantiomeric separation of 50 chiral compounds including amino acids, pesticides, stimulants, and a variety of pharmaceuticals. Fast and efficient chiral separations resulted by using superficially porous (core-shell) particle supports. Overall, the vancomycin Edman degradation product (EDP) resembled TeicoShell with high enantioselectivity for acidic compounds in the polar ionic mode. The simultaneous enantiomeric separation of 5 racemic profens using liquid chromatography-mass spectrometry with EDP was performed in approximately 3?minutes. Other highlights include simultaneous liquid chromatography separations of rac-amphetamine and rac-methamphetamine with VancoShell, rac-pseudoephedrine and rac-ephedrine with NicoShell, and rac-dichlorprop and rac-haloxyfop with TeicoShell.

One-Pot Enzymatic Synthesis of d-Arylalanines Using Phenylalanine Ammonia Lyase and l-Amino Acid Deaminase

The phenylalanine ammonia-lyase (AvPAL) from Anabaena variabilis catalyzes the amination of substituent trans-cinnamic acid (t-CA) to produce racemic d,l-enantiomer arylalanine mixture owing to its low stereoselectivity. To produce high optically pure d-arylalanine, a modified AvPAL with high d-selectivity is expected. Based on the analyses of catalytic mechanism and structure, the Asn347 residue in the active site was proposed to control stereoselectivity. Therefore, Asn347 was mutated to construct mutant AvPAL-N347A, the stereoselectivity of AvPAL-N347A for d-enantiomer arylalanine was 2.3-fold higher than that of wild-type AvPAL (WtPAL). Furthermore, the residual l-enantiomer product in reaction solution could be converted into the d-enantiomer product through stereoselective oxidation by PmLAAD and nonselective reduction by reducing agent NH3BH3. At optimal conditions, the conversion rate of t-CA and optical purity (enantiomeric excess (eeD)) of d-phenylalanine reached 82% and exceeded 99%, respectively. The two enzymes displayed activity toward a broad range of substrate and could be used to efficiently synthesize d-arylalanine with different groups on the phenyl ring. Among these d-arylalanines, the yield of m-nitro-d-phenylalanine was highest and reached 96%, and the eeD exceeded 99%. This one-pot synthesis using AvPAL and PmLAAD has prospects for industrial application.