110221-04-0

Basic information

• Product Name: 4-FLUORO-D-TRYPTOPHAN
• Synonyms: 4-FLUORO-D-TRYPTOPHAN;D-Tryptophan, 4-fluoro-
• CAS NO: 110221-04-0
• Molecular Formula: C11H11FN2O2
• Molecular Weight: 222.22
• Mol File: 110221-04-0.mol
• Article Data: 11

Chemical Properties

• Boiling Point: 450.7±45.0 °C(Predicted)
• Appearance: /
• Density: 1.442±0.06 g/cm3(Predicted)
• Storage Temp.: 2-8°C
• PKA: 2.19±0.10(Predicted)
• CAS DataBase Reference: 4-FLUORO-D-TRYPTOPHAN(CAS DataBase Reference)
• NIST Chemistry Reference: 4-FLUORO-D-TRYPTOPHAN(110221-04-0)
• EPA Substance Registry System: 4-FLUORO-D-TRYPTOPHAN(110221-04-0)

Safety Data

• Hazardous Substances Data: 110221-04-0(Hazardous Substances Data)

Usage

General Description

4-Fluoro-D-tryptophan is a derivative of the essential amino acid tryptophan. The presence of the fluorine atom at the 4th position of the indole ring differentiates it from regular tryptophan. This modification often enables the substance to be used as a probe in biochemical research, particularly in studies involving protein structure and function. It is commonly used because of its ability to mimic the behavior of the original molecule while offering the advantage of being detectable using techniques such as 19F NMR spectroscopy. It's also used in enzyme studies to examine reaction mechanisms and molecular behaviors. However, like many chemical compounds, it needs to be handled with care due to its potential health hazards.

Upstream product

• 387-43-9 4-fluoroindole 
• 56-45-1 L-serin 
• 863407-42-5 [4-fluoro-1-(4-toluenesulfonyl)indol-3-yl]carboxaldehyde 
• 1369571-01-6 (S)-1-tosyl-4-fluorotryptophan methyl ester 
• 1369570-94-4 4-fluoro-3-hydroxymethyl-1-tosylindole 
• 1369570-96-6 3-bromomethyl-4-fluoro-1-tosylindole 
• 23073-31-6 (4-fluoroindol-3-yl)carboxaldehyde 
• 25631-05-4 4-fluoro-DL-tryptophan 

Downstream Products

• 110221-04-0 C₁₁H₁₁FN₂O₂ 

Relevant articles and documents

Unlocking Reactivity of TrpB: A General Biocatalytic Platform for Synthesis of Tryptophan Analogues

Derivatives of the amino acid tryptophan (Trp) serve as precursors for the chemical and biological synthesis of complex molecules with a wide range of biological properties. Trp analogues are also valuable as building blocks for medicinal chemistry and as tools for chemical biology. While the enantioselective synthesis of Trp analogues is often lengthy and requires the use of protecting groups, enzymes have the potential to synthesize such products in fewer steps and with the pristine chemo- and stereoselectivity that is a hallmark of biocatalysis. The enzyme TrpB is especially attractive because it can form Trp analogues directly from serine (Ser) and the corresponding indole analogue. However, many potentially useful substrates, including bulky or electron-deficient indoles, are poorly accepted. We have applied directed evolution to TrpB from Pyrococcus furiosus and Thermotoga maritima to generate a suite of catalysts for the synthesis of previously intractable Trp analogues. For the most challenging substrates, such as nitroindoles, the key to improving activity lay in the mutation of a universally conserved and mechanistically important residue, E104. The new catalysts express at high levels (>200 mg/L of Escherichia coli culture) and can be purified by heat treatment; they can operate up to 75 °C (where solubility is enhanced) and can synthesize enantiopure Trp analogues substituted at the 4-, 5-, 6-, and 7-positions, using Ser and readily available indole analogues as starting materials. Spectroscopic analysis shows that many of the activating mutations suppress the decomposition of the active electrophilic intermediate, an amino-acrylate, which AIDS in unlocking the synthetic potential of TrpB.

Natural and directed biosynthesis of communesin alkaloids

A role for tryptophan, acetate, mevalonate and methionine in the biosynthesis of communesins A and B, novel structurally-related and biologically-active Penicillium metabolites, has been established by isotopic labelling techniques. The incorporation of 14C-tryptamine has also been demonstrated. dl-2-13C-tryptophan specifically enriched two carbon atoms in the 13C NMR spectrum, thereby defining the intra-molecular arrangement of the two tryptophan-derived moieties. Feeding differentially labelled precursors during communesin production showed that tryptophan and methionine are involved early in the biosynthesis and that mevalonate provides an isoprene which is added later. A biosynthetic pathway involving an early precursor based on tryptophan is proposed. Indole-N-( 13C-methyl) tryptophan was not incorporated into communesins implying that N-methylation of tryptophan is not the first step of the communesin biosynthetic pathway. During deamination of indole-N-(13C-methyl) tryptophan to 1-13C-methylindole-3-carboxylic acid communesin biosynthesis was inhibited. Of several halogenated indoles tested for directed biosynthesis, only dl-6-fluoro-tryptophan and 6-fluoro-tryptamine caused accumulation of the corresponding monofluoro-analogues of communesins A and B.

METHODS FOR PRODUCING D-TRYPTOPHAN AND SUBSTITUTED D-TRYPTOPHANS

Single-module nonribosomal peptide synthetases (NRPSs) and NRPS-like enzymes activate and transform carboxylic acids in both primary and secondary metabolism; and are of great interest due to their biocatalytic potentials. The single-module NRPS IvoA is essential for fungal pigment biosynthesis. As disclosed herein, we show that IvoA catalyzes ATP-dependent unidirectional stereoinversion of L-tryptophan to D-tryptophan with complete conversion. While the stereoinversion is catalyzed by the epimerization (E) domain, the terminal condensation (C) domain stereoselectively hydrolyzes D-tryptophanyl-S-phosphopantetheine thioester and thus represents a noncanonical C domain function. Using IvoA, we demonstrate a biocatalytic stereoinversion/deracemization route to access a variety of substituted D-tryptophan analogs in high enantiomeric excess.

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.