Abstract
BCL-2 proteins control the intrinsic pathway of programmed cell death. Composed of anti- and pro-apoptotic members, their network of interactions forms a molecular switch that controls mitochondrial outer-membrane permeability. Apoptotic stimulation leads to BAK/BAX oligomerization and pore formation, yet the molecular details of this pivotal step remain poorly understood, and controversy persists regarding the activation mechanism. Here we use native mass spectrometry and kinetics to show that the homo-oligomerization of BAK and BAX is spontaneous in hydrophobic environments. This process is abrogated by hetero-dimerization of both BAK and BAX with the anti-apoptotic BCL-2 protein MCL-1. Pro-apoptotic BH3-only proteins disrupt these hetero-dimers by binding competitively to MCL-1, releasing BAK/BAX for homo-oligomerization. Thus, we infer that their oligomeric states are thermodynamically favored at the membrane. Our approach provides the framework for future quantitative biophysical characterizations of the BCL-2 network, and advances our molecular understanding of apoptosis.