133388-96-2

Basic information

• Product Name: FOR-NLE-OH
• Synonyms: N-FORMYL-L-NORLEUCINE;FORMYL-L-2-AMINO-HEXANOIC ACID;FOR-NLE-OH;FOR-NORLEUCINE;FOR-ACPO(2)-OH;FOR-AHX(2)-OH;FOR-L-2-AMINOHEXANOIC ACID;FOR-L-NORLEUCINE
• CAS NO: 133388-96-2
• Molecular Formula: C₇H₁₃NO₃
• Molecular Weight: 159.18
• Mol File: 133388-96-2.mol
• Article Data: 3

Chemical Properties

• Appearance: /
• Storage Temp.: Store at RT.
• CAS DataBase Reference: FOR-NLE-OH(CAS DataBase Reference)
• NIST Chemistry Reference: FOR-NLE-OH(133388-96-2)
• EPA Substance Registry System: FOR-NLE-OH(133388-96-2)

Safety Data

• Hazard Codes: Xi
• Statements: 36
• Safety Statements: 26
• Hazardous Substances Data: 133388-96-2(Hazardous Substances Data)

Usage

General Description

FOR-NLE-OH is a synthetic peptide derivative that is often used in research and development as a chemical tool to study the effects of neuropeptide FF (NPFF) on opioid receptor activity. It is a potent and selective NPFF receptor antagonist, and has been shown to block the actions of NPFF on opioid receptors in various experimental models. This chemical has also been studied for its potential therapeutic applications, particularly in the areas of pain management and addiction treatment. Overall, FOR-NLE-OH is a valuable chemical compound that helps further our understanding of the complex interactions between neuropeptides and opioid receptors in the body.

Upstream product

• 327-57-1 L-Norleucine 
• 2258-42-6 formyl acetic anhydride 

Downstream Products

• 133388-98-4 For-Nle-His-Phe-OMe 
• 327-57-1 L-Norleucine 
• 327-56-0 D-norleucine 

Relevant articles and documents

Expression of binding energy on an antibody reaction coordinate

In this paper, we report the investigation of how the catalytic antibody 17E8 uses remote binding energy along the catalyzed hydrolytic reaction coordinate. With the use of alternative substrate analogues, we find that 17E8 can use free energy from binding interactions between the substrate side chain and antibody recognition pocket to equally stabilize the transition state and the Michaelis complex. In these cases, the interactions are not used to increase k(cat). We have also identified substrates for which the interactions are used to preferentially stabilize the transition state over the Michaelis complex. In these cases, the interactions are used to increase k(cat). Mechanistic studies support the idea that the differences in the substrates' kinetic activities results from differences in the expression of side-chain-pocket binding energy along the reaction coordinates. These results suggest that generating catalytic antibodies to transition-state analogues may be limited because the selective use of remote binding interactions cannot be programmed into transition-state analogues.

Asymmetric synthesis of N-methyl-α-amino esters from a glyoxal derived chiral heterocycle

The reaction between a chiral template derived from glyoxal with organometallic reagents leads ultimately to the optically active title compounds. The stereochemical outcome of the key-step which involves substitution of a thiophenol group depends on the organometallic: predominantly inversion with alkyl copper or complete retention with alkyl zinc halides. The stereodirecting effect of an allylic hydroxy group in an iminium intermediate is evidenced in the case of the organozinc reagent.