1613293-39-2

Upstream product

• 15252-44-5 1-amino-pent-4-yne 
• 6097-07-0 N-(pent-4-ynyl)phthalimide 
• 14267-92-6 1-chloro-4-pentyne 
• 1613293-41-6 C₁₆H₁₆N₂O 
• 95298-68-3 3-methoxy-5-oxo-cyclohex-3-ene-1-carboxylic acid 
• 1613293-40-5 C₁₅H₁₂N₂O₄ 
• 116668-47-4 6-amino-2-naphthoic acid 

Relevant academic research and scientific papers

TARGETED COVALENT PROBES AND INHIBITORS OF PROTEINS CONTAINING REDOX-SENSITIVE CYSTEINES

Covalent, irreversible small-molecule inhibitors that modify the sulfenyl form (i.e., sulfenic acid, RSOH and sulfenamide, RSNR'2) of therapeutically important proteins (particularly kinases and phosphatases) are disclosed, where the compositions include a compound having a substituted aryl or heterocyclic core structure that promotes binding interactions with a specific protein, and a nucleophilic reaction center (carbon, nitrogen, sulfur, or phosphorous) that is capable of forming a covalent bond with a sulfenic acid- or sulfenamide-modified cysteine residue in the protein. Methods for synthesizing these compounds are also disclosed, as well as methods of using them for determining the bioactivity of a chemical composition comprising an active compound toward a specific protein and for determining the potency of an inhibitor against a specific protein.

Redox-based probes as tools to monitor oxidized protein tyrosine phosphatases in living cells

Reversible oxidation of protein tyrosine phosphatases (PTPs) has emerged as an important regulatory mechanism whereby reactive oxygen species (ROS) inactivates the PTP and promotes phosphorylation and induction of the signaling cascade. The lack of sensitive and robust methods to directly detect oxidized PTPs has made it difficult to understand the effects that PTP oxidative inactivation play in redox signaling. We report the use of redox-based probes to directly detect oxidized PTPs in a cellular context, which highlights the importance of direct approaches to assist in the study of physiological and pathophysiological PTP activity in redox regulation. We also demonstrate, as a proof-of-concept, that these redox-based probes serve as prototypes for the design and development of a new class of inhibitors for phosphatases. We envision a nucleophile reacting with the oxidized inactive catalytic cysteine to generate an irreversible thioether adduct which prevents the phosphatase from being reactivated and ultimately fortifies the signaling cascade. Our results reveal the potential of translation of our redox-based probes, which are used to understand redox cell circuitry and disease biology, to small-molecule nucleophile-based inhibitors, which may treat diseases associated with redox stress. This may have implications in the treatment of type 2 diabetes and cancer.