Structural basis for the regulatory mechanism of mammalian mitochondrial respiratory chain megacomplex-I2III2IV2

Abstract

Mammalian mitochondrial electron transport chain complexes are the most important and complicated protein machinery in mitochondria. Although this system has been studied for more than a century, its composition and molecular mechanism are still largely unknown. Here we report the high-resolution cryo-electron microscopy (Cryo-EM) structures of porcine respiratory chain megacomplex-I2III2IV2 (MCI2III2IV2) in five different conformations, including State 1, State 2, Mid 1, Mid 2, and Mid 3. High-resolution Cryo-EM imaging, combined with super-resolution gated stimulated emission depletion microscopy (gSTED), strongly supports the formation of MCI2III2IV2 in live cells. Each MCI2III2IV2 structure contains 141 subunits (70 different kinds of peptides, 2.9 MDa) in total with 240 transmembrane helices. The mutual influence among CI, CIII, and CIV shown in the MCI2III2IV2 structure suggests this megacomplex could act as an integral unit in electron transfer and proton pumping. The conformational changes from different states suggest a plausible regulatory mechanism for the MCI2III2IV2 activation/deactivation process.