An improved phenylarsine oxide-affinity method identifies triose phosphate isomerase as a candidate redox receptor protein.

Reversible oxidation on proteins of vicinal thiols to form intraprotein disulfides is believed to be an important means by which redox sensitivity is conferred on cellular signaling and metabolism. Affinity chromatography using immobilized phenylarsine oxide (PAO), which binds preferentially to vicinal thiols over monothiols, has been used in very limited studies to isolate the fraction of cellular proteins that exhibit reversible oxidation of vicinal thiols to presumed disulfide bonds. A challenge to the use of PAO-affinity chromatography for isolation of readily oxidizable vicinal thiol proteins (VTPs) has been the lack of a disulfide reducing agent that reverses oxidation of the PAO-binding protein thiols and maintains these in the reduced state necessary to bind PAO but does not also compete with the VTPs for binding to the immobilized PAO.

Oxidative inhibition of protein phosphatase 2A activity: role of catalytic subunit disulfides.

A molecular basis for the inhibition of brain protein phosphatase 2A (PP2A) activity by oxidative stress was examined in a high-speed supernatant (HSS) fraction from rat cerebral cortex. PP2A activity was subject to substantial disulfide reducing agent-reversible inhibition in the HSS fraction. Results of gel electrophoresis support the conclusions that inhibition of PP2A activity was associated with the both the disulfide cross-linking of the catalytic subunit (PP2A(C)) of the enzyme to other brain proteins and with the formation of an apparent novel intramolecular disulfide bond in PP2A(C).