73-22-3

Basic information

• Product Name: L-Tryptophane
• Synonyms: L(-)-Tryptophan;EH 121;l-alpha-Aminoindole-3-propionic acid;(S)-alpha-Amino-beta-(3-indolyl)-propionic acid;Sedanoct;L-Tryptophan (JP14);L-Trp;(S)-alpha-Amino-beta-indolepropionic acid;NCI-C01729;(S)-2-Amino-3-(3-indolyl)propionic acid;(-)-Tryptophan;(S)-alpha-Aminoindole-3-propionic acid;(2S)-2-azaniumyl-3-(1H-indol-3-yl)propanoate;Tryptophan, L-;2-Amino-3-indolylpropanoic acid;WV;Pacitron;Indole-3-alanine;1H-Indole-3-propanoic acid, alpha-amino-, (S)-;(S)-Tryptophan;Alanine, 3-indol-3-yl;L-(-)-Tryptophan;Triptofano [Spanish];3-Indol-3-ylalanine;Ardeytropin;L-alpha-Amino-3-indolepropionic acid;(S)-alpha-Amino-1H-indole-3-propanoic acid;Tryptophan (VAN);alpha-Amino-3-indolepropionic acid, L-;Tryptophanum [Latin];L-Alanine, 3-(1H-indol-3-yl)-;L-Tryptophan (9CI)
• CAS NO: 73-22-3
• Molecular Formula: C₁₁H₁₂N₂O₂
• Molecular Weight: 204.22518
• EINECS: 200-795-6
• Mol File: 73-22-3.mol

Chemical Properties

• Melting Point: 280-285℃
• Boiling Point: 447.908 °C at 760 mmHg
• Flash Point: 224.687 °C
• Appearance: White to off-white crystalline powder
• Density: 1.363 g/cm³
• Vapor Pressure: 8.3E-09mmHg at 25°C
• Refractive Index: 1.697
• Water Solubility: 11.4 g/L (25℃)
• CAS DataBase Reference: L-Tryptophane(CAS DataBase Reference)
• NIST Chemistry Reference: L-Tryptophane(73-22-3)
• EPA Substance Registry System: L-Tryptophane(73-22-3)

Safety Data

• Statements: R33:有累积作用的危险‖R40
• Safety Statements: S24/25:
• Hazardous Substances Data: 73-22-3(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Industry:
L-Tryptophane is used as a therapeutic agent for treating depression, anxiety, and sleep disorders due to its role in the synthesis of mood-regulating neurotransmitters like serotonin and sleep-promoting hormone melatonin.
Used in Dietary Supplements:
L-Tryptophane is used as a dietary supplement to support individuals with inadequate dietary intake of protein-rich foods, helping to maintain optimal levels of serotonin and melatonin for mood and sleep regulation.
Used in Immune Function Support:
L-Tryptophane is used as an immune function supporter, as it has been studied for its potential role in enhancing immune response and overall immune system health.
Used in Digestive Health Promotion:
L-Tryptophane is used as a promoter of healthy digestion, as it has been investigated for its role in supporting gastrointestinal function and maintaining a balanced gut microbiome.

InChI:InChI=1/C11H12N2O2/c12-9(11(14)15)5-7-6-13-10-4-2-1-3-8(7)10/h1-4,6,9,13H,5,12H2,(H,14,15)/t9-/m0/s1

Upstream product

• 120-72-9 indole 
• 56-45-1 L-serin 
• 56-84-8 L-Aspartic acid 
• 392-12-1 Indole-3-pyruvic acid 
• 6720-02-1 DL-tryptophanamide 
• 4299-70-1 L-tryptophan methyl ester 
• 7303-49-3 DL-tryptophan methyl ester 
• 7479-05-2 L-tryptophan ethyl ester 
• 16108-03-5 n-formyl-tryptophan 
• 1218-34-4 N-AcTrp 
• 1218-34-4 N-acetyl-DL-tryptophan 
• 79189-76-7 N²-(chloroacetyl)-DL-tryptophan 
• 113-24-6 sodium pyruvate 
• 57-60-3 piruvate 

Downstream Products

• 31528-64-0 [5']adenylic acid L-tryptophan anhydride 
• 4299-70-1 L-tryptophan methyl ester 
• 42438-90-4 3-carboxy-1,2,3,4-tetrahydro-2-carboline 
• 57105-53-0 (2S)-3-(1H-indol-3-yl)-2-[(1H-indol-3-ylacetyl)amino]propanoic acid 
• 7479-05-2 L-tryptophan ethyl ester 
• 486-84-0 harmane 
• 5419-44-3 N^α-iodoacetyl-tryptophan 
• 95817-05-3 N^α-(4-Phenylazo-benzyloxycarbonyl)-L-tryptophan 
• 3262-57-5 [(benzyloxy)carbonyl]glycyl-L-tryptophan 
• 13139-14-5 Boc-Trp-OH 
• 131828-11-0 N^α-(2-Benzyloxyimino-4-methyl-valeryl)-L-tryptophan 
• 1218-34-4 N-AcTrp 
• 1218-34-4 N-acetyl-DL-tryptophan 
• 38453-61-1 N^α-trityl-L-tryptophan; diethylamine 

Relevant articles and documents

Recreating the natural evolutionary trend in key microdomains provides an effective strategy for engineering of a thermomicrobial N-demethylase

N-demethylases have been reported to remove the methyl groups on primary or secondary amines, which could further affect the properties and functions of biomacromolecules or chemical compounds; however, the substrate scope and the robustness of N-demethylases have not been systematically investigated. Here we report the recreation of natural evolution in key microdomains of the Thermomicrobium roseum sarcosine oxidase (TrSOX), an N-demethylase with marked stability (melting temperature over 100 C) and enantioselectivity, for enhanced substrate scope and catalytic efficiency on -C-N-bonds. We obtained the structure of TrSOX by crystallization and X-ray diffraction (XRD) for the initial framework. The natural evolution in the nonconserved residues of key microdomains—including the catalytic loop, coenzyme pocket, substrate pocket, and entrance site—was then identified using ancestral sequence reconstruction (ASR), and the substitutions that accrued during natural evolution were recreated by site-directed mutagenesis. The single and double substitution variants catalyzed the N-demethylation of N-methyl-L-amino acids up to 1800- and 6000-fold faster than the wild type, respectively. Additionally, these single substitution variants catalyzed the terminal N-demethylation of non-amino-acid compounds and the oxidation of the main chain -C-N- bond to a -C=N- bond in the nitrogen-containing heterocycle. Notably, these variants retained the enantioselectivity and stability of the initial framework. We conclude that the variants of TrSOX are of great potential use in N-methyl enantiomer resolution, main-chain Schiff base synthesis, and alkaloid modification or degradation.

Biocatalysts from cyanobacterial hapalindole pathway afford antivirulent isonitriles against MRSA

Abstract: The emergence of resistance to frontline antibiotics has called for novel strategies to combat serious pathogenic infections. Methicillin-resistant Staphylococcus aureus [MRSA] is one such pathogen. As opposed to traditional antibiotics, bacteriostatic anti-virulent agents disarm MRSA, without exerting pressure, that cause resistance. Herein, we employed a thermophilic Thermotoga maritima tryptophan synthase (TmTrpB1) enzyme followed by an isonitrile synthase and Fe(II)-α-ketoglutarate-dependent oxygenase, in sequence as biocatalysts to produce antivirulent indole vinyl isonitriles. We report on conversion of simple derivatives of indoles to their C3-vinyl isonitriles, as the enzymes employed here demonstrated broader substrate tolerance. In toto, eight distinct L-Tryptophan derived α-amino acids (7) were converted to their bioactive vinyl isonitriles (3) by action of an isonitrile synthase (WelI1) and an Fe(II)-α-ketoglutarate-dependent oxygenase (WelI3) yielding structural variants possessing antivirulence against MRSA. These indole vinyl isonitriles at 10 μg/mL are effective as antivirulent compounds against MRSA, as evidenced through analysis of rabbit blood hemolysis assay. Based on a homology modelling exercise, of enzyme-substrate complexes, we deduced potential three dimensional alignments of active sites and glean mechanistic insights into the substrate tolerance of the Fe(II)-α-ketoglutarate-dependent oxygenase. Graphic abstract: [Figure not available: see fulltext.]

Motobamide, an Antitrypanosomal Cyclic Peptide from a Leptolyngbya sp. Marine Cyanobacterium

Motobamide (1), a new cyclic peptide containing a C-prenylated cyclotryptophan residue, was isolated from a marine Leptolyngbya sp. cyanobacterium. Its planar structure was established by spectroscopic and MS/MS analyses. The absolute configuration was elucidated based on a combination of chemical degradations, chiral-phase HPLC analyses, spectroscopic analyses, and computational chemistry. Motobamide (1) moderately inhibited the growth of bloodstream forms of Trypanosoma brucei rhodesiense (IC50 2.3 μM). However, it exhibited a weaker cytotoxicity against normal human cells (IC50 55 μM).

Method for photolysis of amido bonds

The invention discloses a method for photo-splitting amido bonds, wherein the method is mild in reaction condition and can realize splitting of amido bonds by using illumination. The method for photo-splitting the amido bonds comprises the following steps: reacting 2,4-dinitrofluorobenzene with an amino group of a substance which contains alpha amino acid at the tail end and is shown as a structural formula I to generate a compound 1 represented by a structural formula II; and under light irradiation, carrying out amido bond cleavage reaction on the compound 1, wherein R1 is a side chain group of alpha-amino acid, and R2 is aryl, aliphatic hydrocarbon, -CH(R)-COOH or polypeptide.

Highly Stable Zr(IV)-Based Metal-Organic Frameworks for Chiral Separation in Reversed-Phase Liquid Chromatography

Separation of racemic mixtures is of great importance and interest in chemistry and pharmacology. Porous materials including metal-organic frameworks (MOFs) have been widely explored as chiral stationary phases (CSPs) in chiral resolution. However, it remains a challenge to develop new CSPs for reversed-phase high-performance liquid chromatography (RP-HPLC), which is the most popular chromatographic mode and accounts for over 90% of all separations. Here we demonstrated for the first time that highly stable Zr-based MOFs can be efficient CSPs for RP-HPLC. By elaborately designing and synthesizing three tetracarboxylate ligands of enantiopure 1,1′-biphenyl-20-crown-6, we prepared three chiral porous Zr(IV)-MOFs with the framework formula [Zr6O4(OH)8(H2O)4(L)2]. They share the same flu topological structure but channels of different sizes and display excellent tolerance to water, acid, and base. Chiral crown ether moieties are periodically aligned within the framework channels, allowing for stereoselective recognition of guest molecules via supramolecular interactions. Under acidic aqueous eluent conditions, the Zr-MOF-packed HPLC columns provide high resolution, selectivity, and durability for the separation of a variety of model racemates, including unprotected and protected amino acids and N-containing drugs, which are comparable to or even superior to several commercial chiral columns for HPLC separation. DFT calculations suggest that the Zr-MOF provides a confined microenvironment for chiral crown ethers that dictates the separation selectivity.

COMPOUNDS AND METHODS FOR SELECTIVE C-TERMINAL LABELING

The present disclosure relates to compounds and methods for selective C-terminal functionalization of peptides. In certain embodiments, the compounds have improved water-solubility, and are suitable for use in connection with peptide sequencing methodologies.

Three diketomorpholines from a Penicillium sp. (strain G1071)

Three previously undescribed diketomorpholine natural products, along with the known phenalenones, herqueinone and norherqueinone, were isolated from the mycoparasitic fungal strain G1071, which was identified as a Penicillium sp. in the section Sclerotiora. The structures were established by analyzing NMR data and mass spectrometry fragmentation patterns. The absolute configurations of deacetyl-javanicunine A, javanicunine C, and javanicunine D, were assigned by examining ECD spectra and Marfey's analysis. The structural diversity generated by this fungal strain was interesting, as only a few diketomorpholines (~17) have been reported from nature.

Mild deprotection of the: N-tert -butyloxycarbonyl (N -Boc) group using oxalyl chloride

We report a mild method for the selective deprotection of the N-Boc group from a structurally diverse set of compounds, encompassing aliphatic, aromatic, and heterocyclic substrates by using oxalyl chloride in methanol. The reactions take place under room temperature conditions for 1-4 h with yields up to 90percent. This mild procedure was applied to a hybrid, medicinally active compound FC1, which is a novel dual inhibitor of IDO1 and DNA Pol gamma. A broader mechanism involving the electrophilic character of oxalyl chloride is postulated for this deprotection strategy. This journal is

Modular control ofl-tryptophan isotopic substitutionviaan efficient biosynthetic cascade

Isotopologs are powerful tools for investigating biological systems. We report a biosynthetic-cascade synthesis of Trp isotopologs starting from indole, glycine, and formaldehyde using the enzymesl-threonine aldolase and an engineered β-subunit of tryptop

Optogenetic Modulation of a Catalytic Biofilm for the Biotransformation of Indole into Tryptophan

In green chemical synthesis, biofilms as biocatalysts have shown great promise. Efficient biofilm-mediated biocatalysis requires the modulation of biofilm formation. Optogenetic tools are ideal to control biofilms because light is noninvasive, easily controllable, and cost-efficient. In this study, a gene circuit responsive to near-infrared (NIR) light was used to modulate the cellular level of bis-(3′-5′) cyclic dimeric guanosine monophosphate (c-di-GMP), a central regulator of the prokaryote biofilm lifestyle, which allowed the regulation of biofilm formation by using NIR light. The engineered biofilm was applied to catalyze the biotransformation of indole into tryptophan in submerged biofilm reactors and NIR-light-enhanced biofilm formation resulted in an approximately 30 % increase in tryptophan yield, which demonstrates the feasibility of the application of light to modulate the formation and performance of catalytic biofilms for chemical production. The c-di-GMP-targeted optogenetic approach to modulate catalytic biofilms showcases applications for biofilm-mediated biocatalysis.