Friction-driven scission: How nonlocal mechanisms contribute to membrane fission across domains of life | Science Advances

Membrane fission is an energy-consuming process, critical for all domains of life. Prototypical fission machineries use local energy input such as nucleoside triphosphate hydrolysis to constrict and cut membranes. However, some membrane fission reactions paradoxically rely on protein scaffolds that by themselves stabilize rather than cut membranes. It turns out these proteins do not work alone; they use nonlocal energy input that generates a membrane tension gradient. Such a gradient mobilizes membrane flow that in turn tends to relax the membrane tension gradient. By interfering with membrane flow, the protein scaffold causes the membrane tension to increase unchecked to the point of mechanical failure, membrane fission. This friction-driven scission (FDS) mechanism is generic, conserved from bacteria to humans, and only requires two ingredients: a membrane tension generating process and a protein scaffold that hinders the associated membrane flow. Because both are often present in cells, it is likely that FDS contributes to membrane fission more frequently than previously appreciated.