Mitochondrial Presequence Translocase: Switching between TOM Tethering and Motor Recruitment Involves Tim21 and Tim17

Detection and analysis of protein–protein interactions in organellar and prokaryotic proteomes by native gel electrophoresis: (Membrane) protein complexes and supercomplexes

It is an essential and challenging task to unravel protein-protein interactions in their actual in vivo context. Native gel systems provide a separation platform allowing the analysis of protein complexes on a rather proteome-wide scale in a single experiment. This review focus on blue-native (BN)-PAGE as the most versatile and successful gel-based approach to separate soluble and membrane protein complexes of intricate protein mixtures derived from all biological sources. BN-PAGE is a charge-shift method with a running pH of 7.5 relying on the gentle binding of anionic CBB dye to all membrane and many soluble protein complexes, leading to separation of protein species essentially according to their size and superior resolution than other fractionation techniques can offer. The closely related colorless-native (CN)-PAGE, whose applicability is restricted to protein species with intrinsic negative net charge, proved to provide an especially mild separation capable of preserving weak protein-protein interactions better than BN-PAGE. The essential conditions determining the success of detecting protein-protein interactions are the sample preparations, e.g. the efficiency/mildness of the detergent solubilization of membrane protein complexes. A broad overview about the achievements of BN- and CN-PAGE studies to elucidate protein-protein interactions in organelles and prokaryotes is presented, e.g. the mitochondrial protein import machinery and oxidative phosphorylation supercomplexes. In many cases, solubilization with digitonin was demonstrated to facilitate an efficient and particularly gentle extraction of membrane protein complexes prone to dissociation by treatment with other detergents. In general, analyses of protein interactomes should be carried out by both BN- and CN-PAGE.

Characterization of Mmp37p, a Saccharomyces cerevisiae mitochondrial matrix protein with a role in mitochondrial protein import

Many mitochondrial proteins are encoded by nuclear genes and after translation in the cytoplasm are imported via translocases in the outer and inner membranes, the TOM and TIM complexes, respectively. Here, we report the characterization of the mitochondrial protein, Mmp37p (YGR046w) and demonstrate its involvement in the process of protein import into mitochondria. Haploid cells deleted of MMP37 are viable but display a temperature-sensitive growth phenotype and are inviable in the absence of mitochondrial DNA. Mmp37p is located in the mitochondrial matrix where it is peripherally associated with the inner membrane. We show that Mmp37p has a role in the translocation of proteins across the mitochondrial inner membrane via the TIM23-PAM complex and further demonstrate that substrates containing a tightly folded domain in close proximity to their mitochondrial targeting sequences display a particular dependency on Mmp37p for mitochondrial import. Prior unfolding of the preprotein, or extension of the region between the targeting signal and the tightly folded domain, relieves their dependency for Mmp37p. Furthermore, evidence is presented to show that Mmp37 may affect the assembly state of the TIM23 complex. On the basis of these findings, we hypothesize that the presence of Mmp37p enhances the early stages of the TIM23 matrix import pathway to ensure engagement of incoming preproteins with the mtHsp70p/PAM complex, a step that is necessary to drive the unfolding and complete translocation of the preprotein into the matrix.

Tim50 Maintains the Permeability Barrier of the Mitochondrial Inner Membrane

Transport of metabolites across the mitochondrial inner membrane is highly selective, thereby maintaining the electrochemical proton gradient that functions as the main driving force for cellular adenosine triphosphate synthesis. Mitochondria import many preproteins via the presequence translocase of the inner membrane. However, the reconstituted Tim23 protein constitutes a pore remaining mainly in its open form, a state that would be deleterious in organello. We found that the intermembrane space domain of Tim50 induced the Tim23 channel to close. Presequences overcame this effect and activated the channel for translocation. Thus, the hydrophilic cis domain of Tim50 maintains the permeability barrier of mitochondria by closing the translocation pore in a presequence-regulated manner.

Mitochondrial morphology and protein import—A tight connection?

Although the field of mitochondrial protein import and assembly may have initially been viewed as a completely distinct area of investigation to that of mitochondrial morphology and dynamics, recent findings have noted a clear influence on organelle morphology by perturbations in protein import pathways. This review aims to provide an overview of the mitochondrial import machinery in context of the recent link between translocation components and organelle structure, in addition to conferring the questions and challenges that have surfaced due to these observations.

Translocation of mitochondrial inner-membrane proteins: conformation matters

Most of the mitochondrial inner-membrane proteins are generated without a presequence and their targeting depends on inadequately defined internal segments. Despite the numerous components of the import machinery identified by proteomics, the properties of hydrophobic import substrates remain poorly understood. Recent studies support several principles for these membrane proteins: first, they become organized into partially assembled forms within the translocon; second, they present noncontiguous targeting signals; and third, they induce conformational changes in translocase subunits, thereby mediating "assembly on demand" of the import machinery. It is possible that the energy needed for these proteins to pass across the outer membrane, to travel through the intermembrane space and to target the inner-membrane surface is provided by conformational changes involving import components that seem to have natively unfolded structures. Such structural malleability might render some of the translocase subunits more adept at driving the protein import process.

Mdm38 interacts with ribosomes and is a component of the mitochondrial protein export machinery

Saccharomyces cerevisiae Mdm38 and Ylh47 are homologues of human Letm1, a protein implicated in Wolf-Hirschhorn syndrome. We analyzed the function of Mdm38 and Ylh47 in yeast mitochondria to gain insight into the role of Letm1. We find that mdm38Δ mitochondria have reduced amounts of certain mitochondrially encoded proteins and low levels of complex III and IV and accumulate unassembled Atp6 of complex V of the respiratory chain. Mdm38 is especially required for efficient transport of Atp6 and cytochrome b across the inner membrane, whereas Ylh47 plays a minor role in this process. Both Mdm38 and Ylh47 form stable complexes with mitochondrial ribosomes, similar to what has been reported for Oxa1, a central component of the mitochondrial export machinery. Our results indicate that Mdm38 functions as a component of an Oxa1-independent insertion machinery in the inner membrane and that Mdm38 plays a critical role in the biogenesis of the respiratory chain by coupling ribosome function to protein transport across the inner membrane.

Essential role of Isd11 in mitochondrial iron-sulfur cluster synthesis on Isu scaffold proteins

Mitochondria are indispensable for cell viability; however, major mitochondrial functions including citric acid cycle and oxidative phosphorylation are dispensable. Most known essential mitochondrial proteins are involved in preprotein import and assembly, while the only known essential biosynthetic process performed by mitochondria is the biogenesis of iron-sulfur clusters (ISC). The components of the mitochondrial ISC-assembly machinery are derived from the prokaryotic ISC-assembly machinery. We have identified an essential mitochondrial matrix protein, Isd11 (YER048w-a), that is found in eukaryotes only. Isd11 is required for biogenesis of cellular Fe/S proteins and thus is a novel subunit of the mitochondrial ISC-assembly machinery. It forms a complex with the cysteine desulfurase Nfs1 and is required for formation of an Fe/S cluster on the Isu scaffold proteins. We conclude that Isd11 is an indispensable eukaryotic component of the mitochondrial machinery for biogenesis of Fe/S proteins.

Conserved Mechanism of Oxa1 Insertion into the Mitochondrial Inner Membrane

Oxa1 is the mitochondrial representative of a family of related proteins that mediate the insertion of substrate proteins into the membranes of bacteria, chloroplasts, and mitochondria. Several studies have demonstrated that the bacterial homologue YidC participates both in the direct uptake of proteins from the bacterial cytosol, and in the uptake of nascent proteins from the Sec translocase. Studies on the biogenesis of membrane proteins in mitochondria established that Oxa1 has the capability to receive substrates at the inner surface of the inner membrane. In this study, we asked if Oxa1 may similarly cooperate with a protein translocase within the membrane. Since Oxa1 is involved in its own biogenesis, we used the precursor of Oxa1 as a model protein and investigated its import pathway. We found that immediately after import into mitochondria, Oxa1 initially accumulates at Tim23 that forms the inner membrane protein translocase. Cleavage of the Oxa1 presequence is dependent on mtHsp70, a heat shock protein of the mitochondrial matrix. However, mutant mtHsp70 showing a defect in the release of bound substrate proteins does not interfere with subsequent membrane insertion, indicating that membrane insertion of the mature protein is essentially mtHsp70-independent. We conclude that Oxa1 has the ability to accept preproteins within the membrane.

Protein import into mitochondria

Mitochondria comprise approx. 1000–3000 different proteins, almost all of which must be imported from the cytosol into the organelle. So far, six complex molecular machines, protein translocases, were identified that mediate this process. The TIM23 complex is a major translocase in the inner mitochondrial membrane. It uses two energy sources, namely membrane potential and ATP, to facilitate preprotein translocation across the inner membrane and insertion into the inner membrane. Recent research has led to the discovery of a number of new constituents of the TIM23 complex and to the unravelling of the mechanisms of preprotein translocation.

Pam17 is required for architecture and translocation activity of the mitochondrial protein import motor

Import of mitochondrial matrix proteins involves the general translocase of the outer membrane and the presequence translocase of the inner membrane. The presequence translocase-associated motor (PAM) drives the completion of preprotein translocation into the matrix. Five subunits of PAM are known: the preprotein-binding matrix heat shock protein 70 (mtHsp70), the nucleotide exchange factor Mge1, Tim44 that directs mtHsp70 to the inner membrane, and the membrane-bound complex of Pam16-Pam18 that regulates the ATPase activity of mtHsp70. We have identified a sixth motor subunit. Pam17 (encoded by the open reading frame YKR065c) is anchored in the inner membrane and exposed to the matrix. Mitochondria lacking Pam17 are selectively impaired in the import of matrix proteins and the generation of an import-driving activity of PAM. Pam17 is required for formation of a stable complex between the cochaperones Pam16 and Pam18 and promotes the association of Pam16-Pam18 with the presequence translocase. Our findings suggest that Pam17 is required for the correct organization of the Pam16-Pam18 complex and thus contributes to regulation of mtHsp70 activity at the inner membrane translocation site.

The essential mitochondrial protein Erv1 cooperates with Mia40 in biogenesis of intermembrane space proteins

The proteins of the mitochondrial intermembrane space (IMS) are encoded by nuclear genes and synthesized on cytosolic ribosomes. While some IMS proteins are imported by the classical presequence pathway that involves the membrane potential deltapsi across the inner mitochondrial membrane and proteolytic processing to release the mature protein to the IMS, the import of numerous small IMS proteins is independent of a deltapsi and does not include proteolytic processing. The biogenesis of small IMS proteins requires an essential mitochondrial IMS import and assembly protein, termed Mia40. Here, we show that Erv1, a further essential IMS protein that has been reported to function as a sulfhydryl oxidase and participate in biogenesis of Fe/S proteins, is also required for the biogenesis of small IMS proteins. We generated a temperature-sensitive yeast mutant of Erv1 and observed a strong reduction of the levels of small IMS proteins upon shift of the cells to non-permissive temperature. Isolated erv1-2 mitochondria were selectively impaired in import of small IMS proteins while protein import pathways to other mitochondrial subcompartments were not affected. Small IMS precursor proteins remained associated with Mia40 in erv1-2 mitochondria and were not assembled into mature oligomeric complexes. Moreover, Erv1 associated with Mia40 in a reductant-sensitive manner. We conclude that two essential proteins, Mia40 and Erv1, cooperate in the assembly pathway of small proteins of the mitochondrial IMS.

Inactivation of the mitochondrial heat shock protein zim17 leads to aggregation of matrix hsp70s followed by pleiotropic effects on morphology and protein biogenesis

The biogenesis of mitochondrial matrix proteins involves the translocase of the outer membrane, the presequence translocase of the inner membrane and the presequence translocase-associated motor. The mitochondrial heat shock protein 70 (mtHsp70) forms the central core of the motor. Recent studies led to the identification of Zim17, a mitochondrial zinc finger motif protein that interacts with mtHsp70. Different views have been reported on the localization of Zim17 in the mitochondrial inner membrane or matrix. Depletion of Zim17 impairs several critical mitochondrial processes, leading to inhibition of protein import, defects of Fe/S protein biogenesis and aggregation of Hsp70s in the matrix. Additionally, we found that inactivation of Zim17 altered the morphology of mitochondria. These pleiotropic effects raise the question of the specific function of Zim17 in mitochondria. Here, we report that Zim17 is a heat shock protein of the mitochondrial matrix that is loosely associated with the inner membrane. To address the function of Zim17 in organello, we generated a temperature-sensitive mutant allele of the ZIM17 gene in yeast. Upon a short-term shift of the yeast mutant cells to a non-permissive temperature, matrix Hsp70s aggregated while protein import, Fe/S protein activity and mitochondrial morphology were not, or only mildly, affected. Only after a long-term shift to non-permissive temperature, were strong defects in protein import, Fe/S protein activity and mitochondrial morphology observed. These findings suggest that the heat shock protein Zim17 plays a specific role in preventing protein aggregation in the mitochondrial matrix, and that aggregation of Hsp70s causes pleiotropic effects on protein biogenesis and mitochondrial morphology.

Role of Pam16's degenerate J domain in protein import across the mitochondrial inner membrane

Translocation of proteins across the mitochondrial inner membrane is an essential process requiring an import motor having mitochondrial Hsp70 (mtHsp70) at its core. The J protein partner of mtHsp70, Pam18, is an integral part of this motor, serving to stimulate the ATPase activity of mtHsp70. Pam16, an essential protein having an inactive J domain that is unable to stimulate mtHsp70's ATPase activity, forms a heterodimer with Pam18, but its function is unknown. We set out to test the importance of three properties of Pam16: (i) a stable interaction between Pam16 and Pam18, (ii) the inability of Pam16's degenerate J domain to stimulate Ssc1's ATPase domain, and (iii) the innately lower stimulatory activity of the Pam16:Pam18 heterodimer, compared to Pam18 alone. Neither substantial reduction in the ability of Pam18 to stimulate Ssc1's ATPase activity, nor the presence of an active J domain in Pam16, had deleterious effects on cell growth, indicating the lack of importance of two of these biochemical properties. However, a stable interaction between Pam16's degenerate J domain and Pam18's J domain was found to be critical for function. Alterations that destabilized the Pam16:Pam18 heterodimer had deleterious effects on cell growth and mitochondrial protein import; intragenic suppressors that restored robust growth also restored heterodimer stability. Our results support the idea that Pam16's J-like domain strongly interacts with Pam18's J domain, leading to a productive interaction of Pam18 with mtHsp70 at the import channel.

Protein Targeting: Entropy, Energetics and Modular Machines

New light is being shed on the mechanism of protein import into mitochondria. The inner membrane translocase can switch between modes of translocation, and assists what might be an entropic device to drive the initial entry of substrate proteins across the outer membrane.

A Railroad Switch in Mitochondrial Protein Import

Chacinska et al., (2005) recently clarified how translocation machineries of the mitochondrial outer and inner membranes cooperate to correctly sort preproteins destined for the mitochondrial matrix and inner membrane.