1202-66-0

Basic information

• Product Name: N-Acetyltyramine
• Synonyms: N-ACETYLTYRAMINE;Acetamide, N-[2-(4-hydroxyphenyl)ethyl]-;N-[2-(4-Hydroxyphenyl)ethyl]acetamide;N-(2-(4-HYDROXYPHENYL)ETHYL)-;4-(2-Acetylaminoethyl)phenol;N-(4-Hydroxyphenethyl)acetamide;N-Acetyl-2-(4-hydroxyphenyl)ethaneamine;N-(p-Hydroxyphenethyl)acetamide
• CAS NO: 1202-66-0
• Molecular Formula: C₁₀H₁₃NO₂
• Molecular Weight: 179.22
• Mol File: 1202-66-0.mol
• Article Data: 24

Chemical Properties

• Melting Point: 169 °C
• Boiling Point: 424.1 °C at 760 mmHg
• Flash Point: 210.3 °C
• Appearance: Off-White
• Density: 1.122 g/cm³
• Vapor Pressure: 8.62E-08mmHg at 25°C
• Refractive Index: 1.546
• Storage Temp.: ?20°C
• PKA: 10.01±0.15(Predicted)
• CAS DataBase Reference: N-Acetyltyramine(CAS DataBase Reference)
• NIST Chemistry Reference: N-Acetyltyramine(1202-66-0)
• EPA Substance Registry System: N-Acetyltyramine(1202-66-0)

Safety Data

• Hazard Codes: Xi
• Statements: 41
• Safety Statements: 26-39
• WGK Germany: 3
• Hazardous Substances Data: 1202-66-0(Hazardous Substances Data)

Usage

Uses

N-[2-(4-Hydroxyphenyl)ethyl]acetamide maintains anti-tumor properties and is derived from a marine bacterium named Streptoverticillium. Cytotoxin.

InChI:InChI=1/C10H13NO2/c1-8(12)11-7-6-9-2-4-10(13)5-3-9/h2-5,13H,6-7H2,1H3,(H,11,12)

Upstream product

• 51-67-2 tyrosamine 
• 108-24-7 acetic anhydride 
• 141-78-6 ethyl acetate 
• 1694-31-1 tert-butyl acetoacetate 
• 64318-28-1 N-t-butoxycarbonyl-tyramine 
• 72-89-9 acetylcoenzyme A 
• 75-36-5 acetyl chloride 
• 72131-33-0 sulotroban 
• 14383-56-3 4-[2-(acetylamino)ethyl]phenyl acetate 
• 58484-75-6 (E)-4-(4-hydroxyphenyl)butan-2-one oxime 
• 60759-49-1 N-acetyl-1,3-oxazol-2-one 
• 64-19-7 acetic acid 
• 75178-12-0 2,2'-bipyridyl-6-yl acetate 
• 128459-09-6 N-acetyl-N-methoxyacetamide 

Downstream Products

• 55458-55-4 ethyl 2-[4-(2-acetaminoethyl)-phenoxy]-2-methyl-propionate 
• 130699-32-0 4-(2'-(acetylamino)ethyl)-4-isopropoxy-2,5-cyclohexadienone 
• 437712-24-8 N-[2-(3,5-dichloro-4-hydroxyphenyl)ethyl]acetamide 
• 40377-41-1 4-(2-(((methyl)carbonyl)amino)ethyl)aniline 
• 643086-86-6 2-(3,5-dichloro-4-hydroxyphenyl)ethylamine hydrochloride 
• 51-67-2 tyrosamine 
• 1204482-86-9 N-{2-[4-(5-cyclopentyloxypyridin-2-yloxy)phenyl]ethyl}acetamide 
• 1187488-16-9 N-(3-((dimethylamino)methyl)-4-hydroxyphenethyl)acetamide 
• 54815-19-9 N-(4-methoxyphenylethyl)acetamide 
• 72131-59-0 ethyl 2-{4-[2-(benzenesulphonylamino)-ethyl]-phenoxy}-2-methylpropionate 
• 55458-78-1 2-<4-(2-aminoethyl)phenoxy>-2-methylpropionic acid 

Relevant articles and documents

Evidence of a coupled mechanism between monoamine oxidase and peroxidase in the metabolism of tyramine by rat intestinal mitochondria

The relationship between monoamine oxidase (EC 1.4.3.4; MAO) and peroxidase (EC 1.11.1.7; POD) in the metabolism of tyramine was investigated using the crude mitochondrial fraction of rat intestine. When tyramine was incubated with mitochondria, the formation of the peroxidase-catalysed oxidation product, 2,2'-dihydroxy-5,5'-bis(ethylamino)diphenyl (dityramine), identified by mass spectrometric analysis, was monitored spectrophotometrically. After an initial lag time, the formation rate of dityramine was linear up to 2 hr, amounting to 17 nmol x hr-1 x mg protein-1. A similar value was found for the oxidative deamination of tyramine catalysed by intestinal MAO. Either 10-3 M clorgyline or 10-3 M NaCN suppressed this reaction by completely inhibiting MAO or POD, respectively. In the former case, however, addition of H2O2 to the incubation mixture promptly started the reaction. Selective inhibition of MAO-A and MAO-B was achieved with 3 x 10-7 M clorgyline and 3 x 10-7 M deprenyl, respectively, and the formation rate of dityramine decreased in a corresponding manner. Preincubation with histamine or spermidine reduced the lag time without affecting the steady-state reaction rate. Higher levels of dityramine were also detected in vivo in rat intestine after oral administration of tyramine. These results indicate that the peroxidase-dependent metabolism of tyramine in the gut may be driven by H2O2 produced by MAO activities and that MAO-A is mainly responsible for this process, as well as for the oxidative deamination of tyramine.

Characterization of arylalkylamine n-acyltransferase from tribolium castaneum: an investigation into a potential next-generation insecticide target

The growing issue of insecticide resistance has meant the identification of novel insecticide targets has never been more important. Arylalkylamine N-acyltransferases (AANATs) have been suggested as a potential new target. These promiscuous enzymes are involved in the N-acylation of biogenic amines to form N-acylamides. In insects, this process is a key step in melanism, hardening of the cuticle, removal of biogenic amines, and in the biosynthesis of fatty acid amides. The unique nature of each AANAT isoform characterized indicates each organism accommodates an assembly of discrete AANATs relatively exclusive to that organism. This implies a high potential for selectivity in insecticide design, while also maintaining polypharmacology. Presented here is a thorough kinetic and structural analysis of AANAT found in one of the most common secondary pests of all plant commodities in the world, Tribolium castaneum. The enzyme, named TcAANAT0, catalyzes the formation of short-chain N-acylarylalkylamines, with short-chain acyl-CoAs (C2-C10), benzoyl-CoA, and succinyl-CoA functioning in the role of acyl donor. Recombinant TcAANAT0 was expressed and purified from E. coli and was used to investigate the kinetic and chemical mechanism of catalysis. The kinetic mechanism is an ordered sequential mechanism with the acyl-CoA binding first. pH-rate profiles and site-directed mutagenesis studies identified amino acids critical to catalysis, providing insights about the chemical mechanism of TcAANAT0. A crystal structure was obtained for TcAANAT0 bound to acetyl-CoA, revealing valuable information about its active site. This combination of kinetic analysis and crystallography alongside mutagenesis and sequence analysis shines light on some approaches possible for targeting TcAANAT0 and other AANATs for novel insecticide design.

New enzymatic and mass spectrometric methodology for the selective investigation of gut microbiota-derived metabolites

Gut microbiota significantly impact human physiology through metabolic interaction. Selective investigation of the co-metabolism of bacteria and their human host is a challenging task and methods for their analysis are limited. One class of metabolites associated with this co-metabolism are O-sulfated compounds. Herein, we describe the development of a new enzymatic assay for the selective mass spectrometric investigation of this phase II modification class. Analysis of human urine and fecal samples resulted in the detection of 206 sulfated metabolites, which is three times more than reported in the Human Metabolome Database. We confirmed the chemical structure of 36 sulfated metabolites including unknown and commonly reported microbiota-derived sulfated metabolites using synthesized internal standards and mass spectrometric fragmentation experiments. Our findings demonstrate that enzymatic sample pre-treatment combined with state-of-the-art metabolomics analysis represents a new and efficient strategy for the discovery of unknown microbiota-derived metabolites in human samples. Our described approach can be adapted for the targeted investigation of other metabolite classes as well as the discovery of biomarkers for diseases affected by microbiota.

Chemoselective N-acetylation of primary aliphatic amines promoted by pivalic or acetic acid using ethyl acetate as an acetyl donor

The combination of pivalic or acetic acid as a promoter and EtOAc as a solvent and acetyl donor proved to be efficient for the chemoselective N-acetylation of primary aliphatic amines to afford the corresponding acetamides. We developed a simple and convenient approach, which requires mild reaction conditions. Competitive inter- and intramolecular reactions between aliphatic amines, alcohols, and aromatic amines were examined, and chemoselectivity was achieved by adjusting the conditions of the reaction.