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Related Concept Videos

Electrophilic Aromatic Substitution: Nitration of Benzene01:20

Electrophilic Aromatic Substitution: Nitration of Benzene

The nitration of benzene is an example of an electrophilic aromatic substitution reaction. It involves the formation of a very powerful electrophile, the nitronium ion, which is linear in shape. The reaction occurs through the interaction of two strong acids, sulfuric and nitric acid.
Preparation of Nitriles01:12

Preparation of Nitriles

One of the common methods to prepare nitriles is the dehydration of amides. This method requires strong dehydrating agents like phosphorous pentoxide or boiling acetic anhydride for converting amides to nitriles. Another reagent namely, thionyl chloride also accomplishes the dehydration of amides, where amide acts as a nucleophile. The first step of the mechanism involves the nucleophilic attack by the amide on the thionyl chloride to form an intermediate. In the next step, the electron pairs...
Nucleophilic Aromatic Substitution of Aryldiazonium Salts: Aromatic SN101:14

Nucleophilic Aromatic Substitution of Aryldiazonium Salts: Aromatic SN1

Treating arylamines with nitrous acid gives aryldiazonium salts that are effective substrates in nucleophilic aromatic substitution reactions. The diazonio group in these salts can be easily displaced by different nucleophiles, yielding a wide variety of substituted benzenes. The leaving group departs as nitrogen gas, and this easy elimination is the driving force for the substitution reaction.
In the Sandmeyer reaction, for example, the diazonio group is replaced by a chloro, bromo, or cyano...
2° Amines to N-Nitrosamines: Reaction with NaNO201:20

2° Amines to N-Nitrosamines: Reaction with NaNO2

Secondary amines react with nitrous acid to form N-nitrosamines, as depicted in Figure 1. Nitrous acid, a weak and unstable acid, is formed in situ from an aqueous solution of sodium nitrite and strong acids, such as hydrochloric acid or sulfuric acid, in cold conditions. In the presence of an acid, the nitrous acid gets protonated. The subsequent loss of water results in the formation of the electrophile known as nitrosonium ion.
Rate-Determining Steps03:08

Rate-Determining Steps

Relating Reaction Mechanisms
In a multistep reaction mechanism, one of the elementary steps progresses significantly slower than the others. This slowest step is called the rate-limiting step (or rate-determining step). A reaction cannot proceed faster than its slowest step, and hence, the rate-determining step limits the overall reaction rate.
The concept of rate-determining step can be understood from the analogy of a 4-lane freeway with a short-stretch of traffic-bottleneck caused due to...
1° Amines to Diazonium or Aryldiazonium Salts: Diazotization with NaNO2 Mechanism01:37

1° Amines to Diazonium or Aryldiazonium Salts: Diazotization with NaNO2 Mechanism

Nitrous acid is a relatively weak and unstable acid prepared in situ by the reaction of sodium nitrite and cold, dilute hydrochloric acid. In an acidic solution, the nitrous acid undergoes protonation when it loses water to form a nitrosonium ion—an electrophile. Nitrous acid reacts with primary amines to give diazonium salts. The reaction is called diazotization of primary amines.

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Updated: May 28, 2026

Nitropeptide Profiling and Identification Illustrated by Angiotensin II
07:31

Nitropeptide Profiling and Identification Illustrated by Angiotensin II

Published on: June 16, 2019

Copper-catalyzed tyrosine nitration.

Liang Qiao1, Yu Lu, Baohong Liu

  • 1Laboratoire d'Electrochimie Physique et Analytique, Ecole Polytechnique Fédérale de Lausanne, Station 6, CH-1015 Lausanne, Switzerland.

Journal of the American Chemical Society
|November 4, 2011
PubMed
Summary
This summary is machine-generated.

Cupric ions catalyze tyrosine nitration via a Fenton-like mechanism, mimicking enzymatic pathways. This research reveals copper

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[(DPEPhos)(bcp)Cu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst
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[(DPEPhos)(bcp)Cu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst

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A Direct, Regioselective and Atom-Economical Synthesis of 3-Aroyl-N-hydroxy-5-nitroindoles by Cycloaddition of 4-Nitronitrosobenzene with Alkynones
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[(DPEPhos)(bcp)Cu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst
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[(DPEPhos)(bcp)Cu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst

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A Direct, Regioselective and Atom-Economical Synthesis of 3-Aroyl-N-hydroxy-5-nitroindoles by Cycloaddition of 4-Nitronitrosobenzene with Alkynones
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A Direct, Regioselective and Atom-Economical Synthesis of 3-Aroyl-N-hydroxy-5-nitroindoles by Cycloaddition of 4-Nitronitrosobenzene with Alkynones

Published on: January 21, 2020

Area of Science:

  • Biochemistry
  • Chemical Biology
  • Neuroscience

Background:

  • Tyrosine nitration is a marker of nitrative stress in neurodegenerative diseases.
  • It is typically induced chemically by reactive nitrogen species or enzymatically by peroxidases.
  • The precise catalytic mechanisms, especially involving metal ions, require further elucidation.

Purpose of the Study:

  • To investigate the role of cupric ions in catalyzing tyrosine nitration.
  • To explore the chemical mechanisms of copper-catalyzed nitration, particularly in relation to enzymatic pathways.
  • To develop a microreactor system for studying tyrosine nitration and its analysis via mass spectrometry.

Main Methods:

  • Development of a microreactor coupled with electrospray ionization mass spectrometry.
  • Investigation of tyrosine nitration in the presence of cupric ions, hydrogen peroxide, and nitrite.
  • Analysis of radical formation and scavenging mechanisms involving copper ions, nitrite, and tyrosine.

Main Results:

  • Cupric ions and their complexes act as potent Fenton catalysts, generating hydroxyl radicals.
  • These radicals lead to tyrosine nitration in polypeptides through reactions with nitrite and tyrosine.
  • Copper also catalyzes nitration involving nitric oxide, oxygen, and hydrogen peroxide, highlighting its polyvalent role.

Conclusions:

  • Copper ions play a multifaceted role in catalyzing tyrosine nitration.
  • The findings provide insights into the chemical mechanisms underlying nitrative stress.
  • This study offers a novel approach for analyzing metal-ion-catalyzed post-translational modifications.