Biogenesis of inner membrane proteins in Escherichia coli

The inner membrane proteome of the model organism Escherichia coli is composed of inner membrane proteins, lipoproteins and peripherally attached soluble proteins. Our knowledge of the biogenesis of inner membrane proteins is rapidly increasing. This is in particular true for the early steps of biogenesis - protein targeting to and insertion into the membrane. However, our knowledge of inner membrane protein folding and quality control is still fragmentary. Furthering our knowledge in these areas will bring us closer to understand the biogenesis of individual inner membrane proteins in the context of the biogenesis of the inner membrane proteome of Escherichia coli as a whole. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

Insertion of bitopic membrane proteins into the inner membrane of mitochondria involves an export step from the matrix

The mitochondrial inner membrane contains a large number of polytopic proteins that are derived from prokaryotic ancestors of mitochondria. Little is known about the intramitochondrial sorting of these proteins. We chose two proteins of known topology as examples to study the pathway of insertion into the inner membrane; Mrs2 and Yta10 are bitopic proteins that expose negatively charged loops of different complexity into the intermembrane space. Here we show that both Mrs2 and Yta10 transiently accumulate as sorting intermediates in the matrix before they integrate into the inner membrane. The sorting pathway of both proteins can be separated into two sequential reactions: (i) import into the matrix and (ii) insertion from the matrix into the inner membrane. The latter process was found to depend on the membrane potential and, in this respect, is similar to the insertion of membrane proteins in bacteria. A comparison of the charge distribution of intermembrane space loops in a variety of mitochondrial inner membrane proteins suggests that this mode of "conservative sorting" might be the typical insertion route for polytopic inner membrane proteins that originated from bacterial ancestors.     

Identification of cold-inducible inner membrane proteins of the psychrotrophic bacterium, Shewanella livingstonensis Ac10, by proteomic analysis

Shewanella livingstonensis Ac10 is a psychrotrophic Gram-negative bacterium that grows at temperatures close to 0°C. Previous proteomic studies of this bacterium identified cold-inducible soluble proteins and outer membrane proteins that could possibly be involved in its cold adaptation (Kawamoto et al. in Extremophiles 11:819–826, 2007). In this study, we established a method for separating the inner and outer membranes by sucrose density gradient ultracentrifugation and performed proteomic studies of the inner membrane fraction. The cells were grown at temperatures of 4 and 18°C, and phospholipid-enriched inner membrane fractions were obtained. Two-dimensional polyacrylamide gel electrophoresis and peptide mass fingerprinting analysis of the proteins identified 14 cold-inducible proteins (more than a 2-fold increase at 4°C). Six of these proteins were predicted to be inner membrane proteins. Two predicted periplasmic proteins, 5 predicted cytoplasmic proteins, and 1 predicted outer membrane protein were also found in the inner membrane fraction, suggesting their association with the inner membrane proteins and/or lipids. These cold-inducible proteins included proteins that are presumed to be involved in chemotaxis (AtoS and PspA), membrane protein biogenesis (DegP, SurA, and FtsY), and morphogenesis (MreB). These findings provide a basis for further studies on the cold-adaptation mechanism of this bacterium.     

Proline residues of transmembrane domains determine the sorting of inner membrane proteins in mitochondria

Most inner membrane proteins of mitochondria are synthesized in the cytosol and reach the inner membrane using one of two alternative sorting pathways. On the stop transfer route, proteins are arrested during import at the level of the inner membrane. The conservative sorting pathway involves translocation through the inner membrane and insertion from the matrix. It is unclear how the translocase of the inner membrane 23 protein translocation machinery differentiates between the two classes of proteins. Here we show that proline residues in hydrophobic stretches strongly disfavor the translocation arrest of transmembrane domains (TMDs) and favor the transfer of preproteins to the matrix. We propose that proline residues, together with the hydrophobicity of the TMD and the presence of charged residues COOH-terminally flanking the TMD, are determinants of the intramitochondrial sorting of inner membrane proteins.     

Protein insertion into the inner membrane of mitochondria

The inner membrane of mitochondria harbours a large number of polypeptides, many of which have evolved from proteins of the prokaryotic progenitors of mitochondria. The sorting routes on which these proteins are integrated into the mitochondrial inner membrane reflect their phylogenetic origin: Proteins of eukaryotic descent typically reach their destination following arrest of import at the level of the inner membrane. In contrast, many proteins inherited from the prokaryotic progenitor cell are inserted into the inner membrane in an export step following translocation into the matrix. Recently, three different insertion pathways from the matrix into the inner membrane were identified which show considerable parallels to the protein insertion processes in bacteria and chloroplasts. Two of these pathways depend on the related inner membrane proteins Oxa1 and Cox18. A third route is less well defined and depends on the membrane-associated matrix protein Mba1.     

Electrophoretic purification of biologically active structural proteins of the simian adenovirus SA7 in the presence of sodium dodecyl sulfate

The modification of disc electrophoresis technique in polyacrylamide gel with sodium dodecylsulphate (SDS) has been elaborated for synchronous isolation of some structural proteins in biologically active form and in preparative quantities from adenoviruses. Virions of SA7 adenovirus were mildly dissociated in SDS solution at 20 degrees C and structural proteins were stained by fluorescamin. After separation the zones of proteins corresponding to the native capsomeres of hexon and protein IV as well as the zones of inner proteins V and VII have been identified as fluorescent at UV-irradiation, excised and extracted by SDS solution. After the removal of SDS by protein precipitation in acetone the preparations of hexon and IV reveal the quaternary structure of native capsomers and full spectrum of antigenic and immunogenic activities of native proteins. Preparations of inner proteins V and VII possess activity in condensing adenoviral DNA. The technique is usable for preparative purification of inner polypeptide VI SA7, as well as capsomers and inner proteins of other adenoviruses.     

Dislocation by the m-AAA Protease Increases the Threshold Hydrophobicity for Retention of Transmembrane Helices in the Inner Membrane of Yeast Mitochondria

Sorting of mitochondrial inner membrane proteins is a complex process in which translocons and proteases function in a concerted way. Many inner membrane proteins insert into the membrane via the TIM23 translocon, and some are then further acted upon by the mitochondrial m-AAA protease, a molecular motor capable of dislocating proteins from the inner membrane. This raises the possibility that the threshold hydrophobicity for the retention of transmembrane segments in the inner membrane is different depending on whether they belong to membrane proteins that are m-AAA protease substrates or not. Here, using model transmembrane segments engineered into m-AAA protease-dependent proteins, we show that the threshold hydrophobicity for membrane retention measured in yeast cells in the absence of a functional m-AAA protease is markedly lower than that measured in its presence. Whether a given hydrophobic segment in a mitochondrial inner membrane protein will ultimately form a transmembrane helix may therefore depend on whether or not it will be exposed to the pulling force exerted by the m-AAA protease during biogenesis.     

The mitochondrial gateway to cell death

Mitochondria play a key role in death signaling. The intermembrane space of these organelles contains a number of proteins which promote cell death once they are redistributed to the cytosol. The formation of pores in the outer membrane of mitochondria defines a gateway through which the apoptogenic proteins pass during death signaling. Interactions between pro-apoptotic and pro-survival members of the Bcl-2 family of proteins are decisive in the initiation of pore opening. While the specific composition of the pore in molecular terms is still subject to debate and continuing investigation, it is recognized functionally as a passive channel which not only allows egress of proteins to cytosol but also entry in the reverse direction. A variety of constraints may restrict the release of proteins from the intermembrane space to the cytosol. These include trapping in the intercristal spaces formed by the convoluted invaginations of the inner membrane, binding of proteins to the inner membrane or to other soluble proteins of the intermembrane space, or insertion of proteins into the inner membrane. There is a corresponding variety of mechanisms that facilitate release of apoptogenic proteins from such entrapment. Morphological changes that expand the inner membrane enable proteins to be released from enclosure in intercristal spaces, allowing these proteins access to the mitochondrial gateway. Specific cases include cytochrome c molecules bound to inner membrane cardiolipin and released upon oxidation of that lipid component. Further, AIF that is embedded in the inner membrane is released by proteases (caspases or calpains), which enter from the cytosol once the outer membrane pore has opened. The facilitation (or restriction) of apoptogenic protein release through the mitochondrial gateway may provide new opportunities for regulating cell death.     

Protein transport machineries for precursor translocation across the inner mitochondrial membrane

The mitochondrial inner membrane has a central function for the energy metabolism of the cell. The respiratory chain generates a proton gradient across the inner mitochondrial membrane, which is used to produce ATP by the F1Fo-ATPase. To maintain the electrochemical gradient, the inner membrane represents an efficient permeability barrier for small molecules. Nevertheless, metabolites as well as polypeptide chains need to be transported across the inner membrane while the electrochemical gradient is retained. While specialized metabolite carrier proteins mediate the transport of small molecules, dedicated protein translocation machineries in the inner mitochondrial membrane (so called TIM complexes) transport precursor proteins across the inner membrane. Here we describe the organization of the TIM complexes and discuss the current models as to how they mediate the posttranslational import of proteins across and into the inner mitochondrial membrane.     

Mitochondria use different mechanisms for transport of multispanning membrane proteins through the intermembrane space

The mitochondrial inner membrane contains numerous multispanning integral proteins. The precursors of these hydrophobic proteins are synthesized in the cytosol and therefore have to cross the mitochondrial outer membrane and intermembrane space to reach the inner membrane. While the import pathways of noncleavable multispanning proteins, such as the metabolite carriers, have been characterized in detail by the generation of translocation intermediates, little is known about the mechanism by which cleavable preproteins of multispanning proteins, such as Oxa1, are transferred from the outer membrane to the inner membrane. We have identified a translocation intermediate of the Oxa1 preprotein in the translocase of the outer membrane (TOM) and found that there are differences from the import mechanisms of carrier proteins. The intermembrane space domain of the receptor Tom22 supports the stabilization of the Oxa1 intermediate. Transfer of the Oxa1 preprotein to the inner membrane is not affected by inactivation of the soluble TIM complexes. Both the inner membrane potential and matrix heat shock protein 70 are essential to release the preprotein from the TOM complex, suggesting a close functional cooperation of the TOM complex and the presequence translocase of the inner membrane. We conclude that mitochondria employ different mechanisms for translocation of multispanning proteins across the aqueous intermembrane space.     

Import of preproteins into the chloroplast inner envelope membrane

The chloroplast inner envelope membrane contains many integral proteins which differ in the number of alpha-helices that anchor the protein into the bilayer. For most of these proteins it is not known which pathway they engage to reach their final localisation within the membrane. In yeast mitochondria, two distinct sorting/insertion pathways have been described for integral inner membrane proteins, involving the Tim22 and Tim23 translocases. These routes involve on the one hand a conservative sorting, on the other hand a stop-transfer pathway. In this study we performed a systematic characterisation of the import behaviour of seven inner envelope proteins representing different numbers of predicted alpha-helices. We investigated their energy dependence, import rate, involvement of components of the chloroplast general import pathway and distribution between soluble and membrane fractions. Our results show the existence of at least two different families of inner envelope proteins that can be classified due to the occurrence of an intermediate processing form. Each of the proteins we investigated seems to use a stop-transfer pathway for insertion into the inner envelope.     

Subcellular localization of seven VirB proteins of Agrobacterium tumefaciens: implications for the formation of a T-DNA transport structure.

Plant cell transformation by Agrobacterium tumefaciens involves the transfer of a single-stranded DNA-protein complex (T-complex) from the bacterium to the plant cell. One of the least understood and important aspects of this process is how the T-complex exits the bacterium. The eleven virB gene products have been proposed to specify the DNA export channel on the basis of their predicted hydrophobicity. To determine the cellular localization of the VirB proteins, two different cell fractionation methods were employed to separate inner and outer membranes. Seven VirB-specific antibodies were used on Western blots (immunoblots) to detect the proteins in the inner and outer membranes and soluble (containing cytoplasm and periplasm) fractions. VirB5 was in both the inner membrane and cytoplasm. Six of the VirB proteins were detected in the membrane fractions only. Three of these, VirB8, VirB9, and VirB10, were present in both inner and outer membrane fractions regardless of the fractionation method used. Three additional VirB proteins, VirB1, VirB4, and VirB11, were found mainly in the inner membrane fraction by one method and were found in both inner and outer membrane fractions by a second method. These results confirm the membrane localization of seven VirB proteins and strengthen the hypothesis that VirB proteins are involved in the formation of a T-DNA export channel or gate. That most of the VirB proteins analyzed are found in both inner and outer membrane fractions suggest that they form a complex pore structure that spans both membranes, and their relative amounts in the two membrane fractions reflect their differential sensitivity to the experimental conditions.     

The Escherichia coli SRP and SecB targeting pathways converge at the translocon.

Two distinct protein targeting pathways can direct proteins to the Escherichia coli inner membrane. The Sec pathway involves the cytosolic chaperone SecB that binds to the mature region of pre-proteins. SecB targets the pre-protein to SecA that mediates pre-protein translocation through the SecYEG translocon. The SRP pathway is probably used primarily for the targeting and assembly of inner membrane proteins. It involves the signal recognition particle (SRP) that interacts with the hydrophobic targeting signal of nascent proteins. By using a protein cross-linking approach, we demonstrate here that the SRP pathway delivers nascent inner membrane proteins at the membrane. The SRP receptor FtsY, GTP and inner membranes are required for release of the nascent proteins from the SRP. Upon release of the SRP at the membrane, the targeted nascent proteins insert into a translocon that contains at least SecA, SecY and SecG. Hence, as appears to be the case for several other translocation systems, multiple targeting mechanisms deliver a variety of precursor proteins to a common membrane translocation complex of the E.coli inner membrane.     

Insertion of proteins into the inner membrane of mitochondria: the role of the Oxa1 complex

The inner mitochondrial membrane harbors a large number of proteins that display a wide range of topological arrangements. The majority of these proteins are encoded in the cell's nucleus, but a few polytopic proteins, all subunits of respiratory chain complexes are encoded by the mitochondrial genome. A number of distinct sorting mechanisms exist to direct these proteins into the mitochondrial inner membrane. One of these pathways involves the export of proteins from the matrix into the inner membrane and is used by both proteins synthesized within the mitochondria, as well as by a subset of nuclear encoded proteins. Prior to embarking on the export pathway, nuclear encoded proteins using this sorting route are initially imported into the mitochondrial matrix from the cytosol, their site of synthesis. Protein export from the matrix into the inner membrane bears similarities to Sec-independent protein export in bacteria and requires the function of the Oxa1 protein. Oxa1 is a component of a general protein insertion site in yeast mitochondrial inner membrane used by both nuclear and mitochondrial DNA encoded proteins. Oxa1 is a member of the conserved Oxa1/YidC/Alb3 protein family found throughout prokaryotes throughout eukaryotes (where it is found in mitochondria and chloroplasts). The evidence to demonstrate that the Oxa1/YidC/Alb3 protein family represents a novel evolutionarily conserved membrane insertion machinery is reviewed here.     

Inner nuclear membrane and regulation of Smad-mediated signaling

Smads mediate signal transduction by cytokines of the transforming growth factor-beta family. Recent data show that intrinsic and extrinsic proteins of the inner nuclear membrane affect the activities of Smads. MAN1, an integral protein of the inner nuclear membrane, binds to receptor-regulated Smads and antagonizes signaling by transforming growth factor-beta, activin and bone morphogenic protein. Lamins A and C, extrinsic intermediate filament proteins of the inner nuclear membrane that are mutated in several human diseases, appear to regulate phosphorylation of Smads. These data demonstrate that proteins within and associated with the inner nuclear membrane lipid bilayer regulate signal transduction pathways involved in numerous developmental, physiological and pathophysiological processes.     

Biogenesis of inner membrane proteins in Escherichia coli

For a long time, it was generally assumed that the biogenesis of inner membrane proteins in Escherichia coli occurs spontaneously, and that only the translocation of large periplasmic domains requires the aid of a protein machinery, the Sec translocon. However, evidence obtained in recent years indicates that most, if not all, inner membrane proteins require the assistance of protein factors to reach their native conformation in the membrane. Here, we review and discuss recent advances in our understanding of the biogenesis of inner membrane proteins in E. coli.     

The essential virulence protein VirB8 localizes to the inner membrane of Agrobacterium tumefaciens.

Agrobacterium tumefaciens genetically transforms plant cells by transferring a specific DNA fragment from the bacterium through several biological membranes to the plant nucleus where the DNA is integrated. This complex DNA transport process likely involves membrane-localized proteins in both the plant and the bacterium. The 11 hydrophobic or membrane-localized proteins of the virB operon are excellent candidates to have a role in DNA export from agrobacteria. Here, we show by TnphoA mutagenesis and immunogold electron microscopy that one of the VirB proteins, VirB8, is located at the inner membrane. The observation that a virB8::TnphoA fusion restores export of alkaline phosphatase to the periplasm suggests that VirB8 spans the inner membrane. Immunogold labeling of VirB8 was detected on the inner membrane of vir-induced A. tumefaciens by transmission electron microscopy. Compared with that of the controls, VirB8 labeling was significantly greater on the inner membrane than on the other cell compartments. These results confirm the inner membrane localization of VirB8 and strengthen the hypothesis that VirB proteins help form a transfer DNA export channel or gate.     

Synthesis and assembly of the membrane proteins in E. coli.

Kinetics of integration of membrane proteins were studied in E. coli to discover how membrane proteins find their final location in the functional membrane. The experiments make use of a simple and convenient method developed for isolating inner and outer membranes from a number of small-scale cultures with high recovery. Among the proteins that constitute the cell surface structures, inner membrane proteins are integrated most rapidly after synthesis, whereas outer membrane proteins delay somewhat, and periplasmic proteins delay further in reaching their destinations. Protein I, a major outer membrane protein with molecular weight of about 37,000 daltons, exhibits significantly slower rates of integration than other outer membrane proteins. The decreased fluidity of membrane lipids by temperature shiftdown of an unsaturated fatty acid auxotroph grown on elaidate results in abnormally slow assembly of the outer membrane proteins and also in an anomalous assembly of the inner membrane proteins, suggesting that the fluid state of the lipids is required for normal operation of these processes. The possible relevance of these findings to the mechanism of membrane formation is discussed.     

Identification and characterization of Cor413im proteins as novel components of the chloroplast inner envelope

Plastids are surrounded by two membrane layers, the outer and inner envelope membranes, which have various transport and metabolic activities. A number of envelope membrane proteins have been identified by biochemical approaches and have been assigned to specific functions. Despite those efforts, the chloroplast envelope membrane is expected to contain a number of as yet unidentified proteins that may affect specific aspects of plant growth and development. In this report, we identify and characterize a novel class of inner envelope membrane proteins, designated as Cor413 chloroplast inner envelope membrane group (Cor413im). Both in vivo and in vitro studies indicate that Cor413im proteins are targeted to the chloroplast envelope. Biochemical analyses of Cor413im1 demonstrate that it is an integral membrane protein in the inner envelope of chloroplasts. Quantitative real-time PCR analysis reveals that COR413IM1 is more abundant than COR413IM2 in cold-acclimated Arabidopsis leaves. The analyses of T-DNA insertion mutants indicate that a single copy of COR413IM genes is sufficient to provide normal freezing tolerance to Arabidopsis. Based on these data, we propose that Cor413im proteins are novel components that are targeted to the chloroplast inner envelope in response to low temperature.