Abstract
Aqueous channels are at the core of the translocase of the outer membrane (TOM) and the translocase of the inner membrane for the transport of preproteins (TIM23), the translocases mediating the transport of proteins across the outer and inner mitochondrial membranes. Yet, the existence of a channel associated to the translocase of the inner membrane for the insertion of multitopic protein (TIM22) complex has been arguable, as its function relates to the insertion of multispanning proteins into the inner membrane. For the first time, we report conditions for detecting a channel activity associated to the TIM22 translocase in organelle, i.e. intact mitoplasts. An internal signal peptide in the intermembrane space of mitochondria is a requisite to inducing this channel, which is otherwise silent. The channel showed slightly cationic and high conductance activity of 1000 pS with a predominant half-open substate. Despite their different composition, the channels of the three mitochondrial translocases were thus remarkably similar, in agreement with their common task as pores transiently trapping proteins en route to their final destination. The opening of the TIM22 channel was a step-up process depending on the signal peptide concentration. Interestingly, low membrane potentials kept the channel fully open, providing a threshold level of the peptide is present. Our results portray TIM22 as a dynamic channel solely active in the presence of its cargo proteins. In its fully open conformation, favored by the combined action of internal signal peptide and low membrane potential, the channel could embrace the in-transit protein. As insertion progressed and initial interaction with the signal peptide faded, the channel would close, sustaining its role as a shunt that places trapped proteins into the membrane.
Highlights
Functioning and death entirely rely on protein translocation
The translocase of the outer membrane (TOM)3 is the common gate for the transport of every mitochondrial protein across the outer membrane, and the TIM23 translocase imports matrix-targeted preproteins with cleavable amino-terminal presequences
With the direct application of patch clamping to mitochondrial membranes, we have shown that channels are essential to the TOM and TIM23 translocases
Summary
Isolation of Mitochondria and Preparation of Mitoplasts and Proteoliposomes—Two strains of Saccharomyces cerevisiae, Tim23(Gal10), and Tim22(Gal10), in which the expression of tim or tim genes is controlled by a Gal promoter, were used [22]. Inner membranes were reconstituted into giant proteoliposomes by dehydration-rehydration as previously described [18, 25] using soybean L-␣-phosphatidylcholine (Sigma Type IV-S). Patch Clamping Techniques—Patch clamp experiments were carried out directly on mitoplasts and on proteoliposomes containing purified mitochondrial inner membranes. Voltages across excised patches were reported as bath potentials. The 0.5-ml bath was perfused with 3–5 ml of medium containing the desired peptides. ImageJ version 1.34s (courtesy of NHI) was used to estimate the amounts of Tim22p and Tim23p and to assess the cross-contamination of the inner membranes. These values were extrapolated from the linear correlations obtained with increasing amounts of membranes. Peptide composition and purity were assessed by high performance liquid chromatography and mass spectrometry and were typically Ͼ90% pure
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