The majority of protein disulfides in cells is considered an important inert structural, rather than a dynamic regulatory, determinant of protein function. Here, we show that some disulfides in proteins also are regulated by cell redox status with functional consequences. We find that reactive oxygen species (ROS) produced by mitochondria are actively used by cells to facilitate cell-surface protein disulfide formation, as well as folding and transport, in mammalian cells. Inhibition of mitochondrial ROS production suppresses protein disulfide formation and induces reductive stress, leading to dysfunction and retention (possibly in the Golgi, in part) of a group of cell-surface disulfide-containing proteins. Sparsely cultured cells produce less ROS than confluent cells do, which leads to decreased disulfide formation and decreased activity of a subgroup of disulfide-containing cell-surface receptors. These data support the concept of two subproteomes comprising the disulfide proteome, a structural group and a redox-sensitive regulatory group, with the latter having direct functional consequences for the cell.