Unconventional Ways to Live and Die: Cell Death and Survival in Development, Homeostasis, and Disease.

Balancing cell death and survival is essential for normal development and homeostasis and for preventing diseases, especially cancer. Conventional cell death pathways include apoptosis, a form of programmed cell death controlled by a well-defined biochemical pathway, and necrosis, the lysis of acutely injured cells. New types of regulated cell death include necroptosis, pyroptosis, ferroptosis, phagoptosis, and entosis. Autophagy can promote survival or can cause death. Newly described processes of anastasis and resuscitation show that, remarkably, cells can recover from the brink of apoptosis or necroptosis. Important new work shows that epithelia achieve homeostasis by extruding excess cells, which then die by anoikis due to loss of survival signals. This mechanically regulated process both maintains barrier function as cells die and matches rates of proliferation and death. In this review, we describe these unconventional ways in which cells have evolved to die or survive, as well as the contributions that these processes make to homeostasis and cancer.

The histidine kinase CusS senses silver ions through direct binding by its sensor domain.

The Cus system of Escherichia coli aids in protection of cells from high concentrations of Ag(I) and Cu(I). The histidine kinase CusS of the CusRS two-component system functions as a Ag(I)/Cu(I)-responsive sensor kinase and is essential for induction of the genes encoding the CusCFBA efflux pump. In this study, we have examined the molecular features of the sensor domain of CusS in order to understand how a metal-responsive histidine kinase senses specific metal ions. We find that the predicted periplasmic sensor domain of CusS directly interacts with Ag(I) ions and undergoes a conformational change upon metal binding. Metal binding also enhances the tendency of the domain to dimerize. These findings suggest a model for activation of the histidine kinase through metal binding events in the periplasmic sensor domain.