A chemically synthesized pre-sequence of an imported mitochondrial protein can form an amphiphilic helix and perturb natural and artificial phospholipid bilayers.

Abstract

Subunit IV of yeast cytochrome oxidase is made in the cytoplasm with a transient pre‐sequence of 25 amino acids which is removed upon import of the protein into mitochondria. To study the function of this cleavable pre‐sequence in mitochondrial protein import, three peptides representing 15, 25 or 33 amino‐terminal residues of the subunit IV precursor were chemically synthesized. All three peptides were freely soluble in aqueous buffers, yet inserted spontaneously from an aqueous subphase into phospholipid monolayers up to an extrapolated limiting monolayer pressure of 40‐50 mN/m. The two longer peptides also caused disruption of unilamellar liposomes. This effect was increased by a diffusion potential, negative inside the liposomes, and decreased by a diffusion potential of opposite polarity. The peptides, particularly the two longer ones, also uncoupled respiratory control of isolated yeast mitochondria. The 25‐residue peptide had little secondary structure in aqueous buffer but became partly alpha‐helical in the presence of detergent micelles. Based on the amino acid sequence of the peptides, a helical structure would have a highly asymmetric distribution of charged and apolar residues and would be surface active. Amphiphilic helicity appears to be a general feature of mitochondrial pre‐sequences. We suggest that this feature plays a crucial role in transporting proteins into mitochondria.