Characterization of the supporting role of SecE in protein translocation

SecYEG functions as a membrane channel for protein export. SecY constitutes the protein-conducting pore, which is enwrapped by SecE in a V-shaped manner. In its minimal form SecE consists of a single transmembrane segment that is connected to a surface-exposed amphipathic α-helix via a flexible hinge. These two domains are the major sites of interaction between SecE and SecY. Specific cleavage of SecE at the hinge region, which destroys the interaction between the two SecE domains, reduced translocation. When SecE and SecY were disulfide bonded at the two sites of interaction, protein translocation was not affected. This suggests that the SecY and SecE interactions are static, while the hinge region provides flexibility to allow the SecY pore to open.     

Cysteine-directed cross-linking demonstrates that helix 3 of SecE is close to helix 2 of SecY and helix 3 of a neighboring SecE.

Preprotein translocation in Escherichia coli is mediated by translocase, a multimeric membrane protein complex with SecA as the peripheral ATPase and SecYEG as the translocation pore. Unique cysteines were introduced into transmembrane segment (TMS) 2 of SecY and TMS 3 of SecE to probe possible sites of interaction between the integral membrane subunits. The SecY and SecE single-Cys mutants were cloned individually and in pairs into a secYEG expression vector and functionally overexpressed. Oxidation of the single-Cys pairs revealed periodic contacts between SecY and SecE that are confined to a specific alpha-helical face of TMS 2 and 3, respectively. A Cys at the opposite alpha-helical face of TMS 3 of SecE was found to interact with a neighboring SecE molecule. Formation of this SecE dimer did not affect the high-affinity binding of SecA to SecYEG and ATP hydrolysis, but blocked preprotein translocation and thus uncouples the SecA ATPase activity from translocation. Conditions that prevent membrane deinsertion of SecA markedly stimulated the interhelical contact between the SecE molecules. The latter demonstrates a SecA-mediated modulation of the protein translocation channel that is sensed by SecE.     

Mapping the sites of interaction between SecY and SecE by cysteine scanning mutagenesis.

In Escherichia coli, the SecYEG complex mediates the translocation and membrane integration of proteins. Both genetic and biochemical data indicate interactions of several transmembrane segments (TMSs) of SecY with SecE. By means of cysteine scanning mutagenesis, we have identified intermolecular sites of contact between TMS7 of SecY and TMS3 of SecE. The cross-linking of SecY to SecE demonstrates that these subunits are present in a one-to-one stoichiometry within the SecYEG complex. Sites in TMS3 of SecE involved in SecE dimerization are confined to a specific alpha-helical interface and occur in an oligomeric SecYEG complex. Although cross-linking reversibly inactivates translocation, the contact between TMS7 of SecY and TMS3 of SecE remains unaltered upon insertion of the preprotein into the translocation channel. These data support a model for an oligomeric translocation channel in which pairs of SecYEG complexes contact each other via SecE.     

A SecE mutation that modulates SecY-SecE translocase assembly,identified as a specific suppressor of SecY defects

The SecY39(Cs) (cold-sensitive) alteration of Arg357 results in a defect of translocation initiation. As a means to dissect the Sec translocation machinery, we isolated mutations that act as suppressors of the secY39 defect. A specific secE mutation, designated secE105, was thus isolated. This mutation proved to be identical with the prlG2 mutation and to suppress a number of cold-sensitive secY mutations. However, other prlG mutations did not effectively suppress the secY defects. Evidence indicates that the Ser105-to-Pro alteration in the C-terminal transmembrane segment of SecE weakens SecY-SecE association. In vitro analyses showed that the SecE(S105P) alteration preferentially stimulates the initial phase of translocation. It is suggested that the S105P alteration affects the SecYEG channel such that it is more prone to open and to accept the translocation initiation domain of a preprotein molecule.     

The carboxyl-terminal region of SecE interacts with SecY and is functional in the reconstitution of protein translocation activity in Escherichia coli.

Genes encoding the C- and N-terminal regions of SecE were constructed and placed under the control of the tac promoter on plasmids. The C-terminal region of SecE (SecE-C) was sufficient for suppression of the secEcs phenotype, confirming the results of Schatz et al. (Schatz, P. J., Bieker, K. L., Ottemann, K. M., Silhavy, T. J., and Beckwith, J. (1991) EMBO J. 10, 1749-1757). SecE-C allowed the overproduction of SecY, and its overproduction was achieved when the tac-secY gene, on a plasmid, was induced, indicating that the C-terminal region is the site of interaction of SecE with SecY and that the interaction makes the two Sec proteins stable. SecE-C was purified and used with SecY for the reconstitution of protein translocation activity. SecE-C was active in the functional reconstitution. The SecE-C/SecY-dependent protein translocation absolutely required SecA and ATP as the native translocation reaction did. Quantitative analysis revealed that SecE-C was 50% as active as intact SecE. The N-terminal region of SecE (SecE-N) also suppressed in vivo the defect caused by the secEcs mutation. SecE-N was, however, inactive in the overproduction of SecY. A possible oligomeric structure of SecE is discussed.     

Importance of transmembrane segments in <Emphasis Type="Italic"> Escherichia coli </Emphasis>SecY

To assess the functional importance of the transmembrane regions of SecY, we constructed a series of SecY variants, in which the six central residues of each transmembrane segment were replaced by amino acid residues from either transmembrane segment 3 or 4 of LacY. The SecY function, as assessed by the ability to complement cold-sensitive secYmutants with respect to their growth and translocase defects, was eliminated by the alterations in transmembrane segments 2, 3, 4, 7, 9 and 10. Among them, those in segments 3 and 4 had especially severe effects. In contrast, transmembrane segments 1, 5, 6, and 8 were more tolerant to the sequence alterations. The purified protein with an altered transmembrane segment 6 retained, in large measure, the ability to support SecA-dependent preprotein translocation in vitro. These results will help us to further understand how the SecYEG protein translocation channel functions.     

Evaluating the oligomeric state of SecYEG in preprotein translocase

SecA insertion and deinsertion through SecYEG drive preprotein translocation at the Escherichia coli inner membrane. We present three assessments of the theory that oligomers of SecYEG might form functional translocation sites. (i) Formaldehyde cross- linking of translocase reveals cross-links between SecY, SecE and SecG, but not higher order oligomers. (ii) Cross-linking of membranes containing unmodified SecE and hemagglutinin-tagged SecE (SecE(HA)) reveals cross-links between SecY and SecE and between SecY and SecE(HA). However, anti-HA immunoprecipitates contain neither untagged SecE nor SecY cross-linked to SecE. (iii) Membranes containing similar amounts of SecE and SecE(HA) were saturated with translocation intermediate (I(29)) and detergent solubilized. Anti-HA immunoprecipitation of I(29) required SecYE(HA)G and SecA, yet untagged SecE was not present in this translocation complex. Likewise, anti-HA immunoprecipitates of membranes containing equal amounts of SecY and SecY(HA) were found to contain SecY(HA) but not SecY. Both immunoprecipitates contain more moles of I(29) than of the untagged subunit, again suggesting that translocation intermediates are not engaged with multiple copies of SecYEG. These studies suggest that the active form of preprotein translocase is monomeric SecYEG.     

Nearest neighbor analysis of the SecYEG complex. 2. Identification of a SecY-SecE cytosolic interface

Although the importance of interactions involving both the cytosolic and transmembrane regions of SecY and SecE has been documented, no information has been available for the physical contact sites of these translocase subunits in their cytosolic domains. We now carried out site-specific cross-linking experiments to identify SecY and SecE regions that are physically close. Cysteines introduced into SecY residue 244 in the fourth cytosolic domain (C4) as well as into residues 354-356 and 362 in the C5 domain could be cross-linked with natural or engineered residues at positions 79 and 81 in the central part of the cytosolic loop of SecE. These cross-linkages were abolished by the Gly240 mutation in the SecY C4 region as well as by prlG alterations in SecE transmembrane segment 3, known to compromise SecY-SecE interaction. We suggest that the cytosolic and intramembrane interactions bring these two subunits together, forming a functionally crucial SecYE interface involving the SecY C5 region and the conserved cytosolic segment of SecE.     

Preprotein translocation by a hybrid translocase composed of Escherichia coli and Bacillus subtilis subunits

Bacterial protein translocation is mediated by translocase, a multisubunit membrane protein complex that consists of a peripheral ATPase SecA and a preprotein-conducting channel with SecY, SecE, and SecG as subunits. Like Escherichia coli SecG, the Bacillus subtilis homologue, YvaL, dramatically stimulated the ATP-dependent translocation of precursor PhoB (prePhoB) by the B. subtilis SecA-SecYE complex. To systematically determine the functional exchangeability of translocase subunits, all of the relevant combinations of the E. coli and B. subtilis secY, secE, and secG genes were expressed in E. coli. Hybrid SecYEG complexes were overexpressed at high levels. Since SecY could not be overproduced without SecE, these data indicate a stable interaction between the heterologous SecY and SecE subunits. E. coli SecA, but not B. subtilis SecA, supported efficient ATP-dependent translocation of the E. coli precursor OmpA (proOmpA) into inner membrane vesicles containing the hybrid SecYEG complexes, if E. coli SecY and either E. coli SecE or E. coli SecG were present. Translocation of B. subtilis prePhoB, on the other hand, showed a strict dependence on the translocase subunit composition and occurred efficiently only with the homologous translocase. In contrast to E. coli SecA, B. subtilis SecA binds the SecYEG complexes only with low affinity. These results suggest that each translocase subunit contributes in an exclusive manner to the specificity and functionality of the complex.     

The core of the bacterial translocase harbors a tilted transmembrane segment 3 of SecE

The bacterial translocase mediates the translocation and membrane integration of proteins. The integral membrane proteins SecY and SecE are conserved core subunits of the translocase. Previous cysteine-scanning studies showed that the transmembrane segment (TMS) 3 of SecE contacts TMS 2 and 7 of SecY, and TMS 3 of another SecE. We now demonstrate that SecE also contacts TMS 10 of SecY. Combining all available cysteine-scanning mutagenesis data, a three-dimensional model has been built in which the positions of the helices that form the central core of the bacterial translocase are mapped. Remarkably, this model reveals that TMS 3 of SecE is strongly tilted relative to SecY.     

Nearest neighbor analysis of the SecYEG complex. 1. Identification of a SecY-SecG interface

Integral membrane components SecY, SecE, and SecG of protein translocase form a complex in the Escherichia coli plasma membrane. To characterize subunit interactions of the SecYEG complex, a series of SecY variants having a single cysteine in its cytoplasmic (C1-C6) or periplasmic (P1-P5) domain were subjected to site-specific cross-linking experiments using bifunctional agents with thiol-amine reactivity. Experiments using inverted membrane vesicles revealed specific cross-linkings between a cysteine residue placed in the C2 or C3 domain of SecY and the cytosolic lysine (Lys26) near the first transmembrane segment of SecG. These SecY Cys residues also formed a disulfide bond with an engineered cytosolic cysteine at position 28 of SecG. Thus, the C2-C3 region of SecY is in the proximity of the N-terminal half of the SecG cytoplasmic loop. Experiments using spheroplasts revealed the physical proximity of P2 (SecY) and the C-terminal periplasmic region of SecG. In addition, mutations in secG were isolated as suppressors against a cold-sensitive mutation (secY104) affecting the TM4-C3 boundary of SecY. These results collectively suggest that a C2-TM3-P2-TM4-C3 region of SecY serves as an interface with SecG.     

SecY variants that interfere with Escherichia coli protein export in the presence of normal secY

As an approach for studying how SecY, an integral membrane protein translocation factor of Escherichia coli, interacts with other protein molecules, we isolated a dominant negative mutation, secY-d1, of the gene carried on a plasmid. The mutant plasmid severely inhibited export of maltose-binding protein and less severely of OmpA, when introduced into sec+ cells. It inhibited growth of secY and secE mutant cells, but not of secA and secD mutant cells or wild-type cells. The mutation deletes three amino acids that should be located at the interface of cytoplasmic domain 5 and transmembrane segment 9. We also found that some SecY-PhoA fusion proteins that lacked carboxy-terminal portions of SecY but retain a region from periplasmic domain 3 to transmembrane segment 7 were inhibitory to protein export. We suggest that these SecY variants are severely defective in catalytic function of SecY, which requires cytoplasmic domain 5 and its carboxy-terminal side, but retain the ability to associate with other molecules of the protein export machinery, which requires the central portion of SecY; they probably exert the 'dominant negative' effects by competing with normal SecY for the formation of active Sec complex. These observations should provide a basis for further genetic analysis of the Sec protein complex in the membrane.     

Purification of SecE and reconstitution of SecE-dependent protein translocation activity

SecE was solubilized from SecE-overproducing E. coli cells and purified through ion exchange and size exclusion chromatographies. When the solubilized membrane containing overproduced amounts of SecY and SecE was fractionated by means of size exclusion chromatography, the two proteins were eluted in different fractions with slight overlapping. Proteoliposomes active in protein translocation were reconstituted from these fractions only when both SecE and SecY were present. When reconstitution was carried out with the purified SecE and fractions containing SecY but only a small amount of SecE, the resultant proteoliposomes exhibited appreciable translocation activity, indicating that SecE is essential for protein translocation. The translocation activity of proteoliposomes was proportional to the amount of purified SecE used for reconstitution. SecE-dependent protein translocation absolutely required ATP and SecA.     

PrlA suppressor mutations cluster in regions corresponding to three distinct topological domains.

The SecY protein of Escherichia coli and its homologues in other organisms, are integral components of the cellular protein translocation machinery. Suppressor mutations that alter SecY (the prlA alleles) broaden the specificity of this machinery and allow secretion of precursor proteins with defective signal sequences. Twenty-five prlA alleles have been characterized. These suppressor mutations were found to cluster in regions corresponding to three distinct topological domains of SecY. Based on the nature and position of the prlA mutations, we propose that transmembrane domain 7 of SecY functions in signal sequence recognition. Results suggest that this interaction may involve a right-handed supercoil of alpha-helices. Suppressor mutations that alter this domain appear to prevent signal sequence recognition, and this novel mechanism of suppression suggests a proofreading function for SecY. We propose that suppressor mutations that alter a second domain of SecY, transmembrane helix 10, also affect this proof-reading function, but indirectly. Based on the synthetic phenotypes exhibited by double mutants, we propose that these mutations strengthen the interaction with another component of the translocation machinery, SecE. Suppressor mutations were also found to cluster in a region corresponding to an amino-terminal periplasmic domain. Possible explanations for this unexpected finding are discussed.     

SecY, SecE, and band 1 form the membrane-embedded domain of Escherichia coli preprotein translocase.

The preprotein translocase of Escherichia coli is a multisubunit enzyme with two domains, the peripheral membrane protein SecA and the membrane-embedded SecY/E protein. SecY/E has been isolated as a complex of three polypeptides, SecY, SecE, and band 1. We now present four lines of evidence that the active species of SecY/E is composed of a tightly associated complex of these three subunits: 1) antibodies to SecY efficiently precipitate SecY/E activity as well as all three polypeptides; 2) the proportions of SecY, SecE, and band 1 in the immunoprecipitates are the same as in the starting fraction; 3) the immunoprecipitable complex is not disrupted by treatment with either high salt or urea but is disrupted by brief incubation at 20 degrees C, and the kinetics of dissociation of both band 1 and SecE from SecY at 20 degrees C parallel the loss of translocation ATPase activity; 4) upon immunoprecipitation of similar units of activity of translocase from detergent solutions from either wild-type membranes or a SecY and SecE overproducer strain, the SecE and band 1 subunits are recovered in the same proportions. These data establish that the subunits of SecY/E are firmly associated and that it is the associated complex which is active for translocation.     

Bacterial protein translocation requires only one copy of the SecY complex in vivo

The transport of proteins across the plasma membrane in bacteria requires a channel formed from the SecY complex, which cooperates with either a translating ribosome in cotranslational translocation or the SecA ATPase in post-translational translocation. Whether translocation requires oligomers of the SecY complex is an important but controversial issue: it determines channel size, how the permeation of small molecules is prevented, and how the channel interacts with the ribosome and SecA. Here, we probe in vivo the oligomeric state of SecY by cross-linking, using defined co- and post-translational translocation intermediates in intact Escherichia coli cells. We show that nontranslocating SecY associated transiently through different interaction surfaces with other SecY molecules inside the membrane. These interactions were significantly reduced when a translocating polypeptide inserted into the SecY channel co- or post-translationally. Mutations that abolish the interaction between SecY molecules still supported viability of E. coli. These results show that a single SecY molecule is sufficient for protein translocation.     

SecY and integral membrane components of the Escherichia coli protein translocation system

Genetic approaches can address the question of how integral membrane Sec factors interact with each other and facilitate protein translocation across the cytoplasmic membrane of E. coli. This review summarizes genetic analyses of SecY, SecE and some other protein translocation factors, utilizing 'prl' mutations, 'sec' mutations, 'suppressor-directed inactivation', 'Sec titration', dominant negative mutations and their suppressors. Evidence suggests that co-ordinate participation of SecY, SecE, SecD, SecF, and probably some other factors, is crucial for the process.     

Chloroplast SecY is complexed to SecE and involved in the translocation of the 33-kDa but not the 23-kDa subunit of the oxygen-evolving complex

SecY is a component of the protein-conducting channel for protein transport across the cytoplasmic membrane of prokaryotes. It is intimately associated with a second integral membrane protein, SecE, and together with SecA forms the minimal core of the preprotein translocase. A chloroplast homologue of SecY (cpSecY) has previously been identified and determined to be localized to the thylakoid membrane. In the present work, we demonstrate that a SecE homologue is localized to the thylakoid membrane, where it forms a complex with cpSecY. Digitonin solubilization of thylakoid membranes releases the SecY/E complex in a 180-kDa form, indicating that other components are present and/or the complex is a higher order oligomer of the cpSecY/E dimer. To test whether cpSecY forms the protein-conducting channel of the thylakoid membrane, translocation assays were conducted with the SecA-dependent substrate OE33 and the SecA-independent substrate OE23, in the presence and absence of antibodies raised against cpSecY. The antibodies inhibited translocation of OE33 but not OE23, indicating that cpSecY comprises the protein-conducting channel used in the SecA-dependent pathway, whereas a distinct protein conducting channel is used to translocate OE23.     

In vivo cross-linking of the SecA and SecY subunits of the Escherichia coli preprotein translocase.

Precursor protein translocation across the Escherichia coli inner membrane is mediated by the translocase, which is composed of a heterotrimeric integral membrane protein complex with SecY, SecE, and SecG as subunits and peripherally bound SecA. Cross-linking experiments were conducted to study which proteins are associated with SecA in vivo. Formaldehyde treatment of intact cells results in the specific cross-linking of SecA to SecY. Concurrently with the increased membrane association of SecA, an elevated amount of cross-linked product was obtained in cells harboring overproduced SecYEG complex. Cross-linked SecA copurified with hexahistidine-tagged SecY and not with SecE. The data indicate that SecA and SecY coexist as a stable complex in the cytoplasmic membrane in vivo.     

Mapping an Interface of SecY (PrlA) and SecE (PrlG) by Using Synthetic Phenotypes and In Vivo Cross-Linking

SecY and SecE are integral cytoplasmic membrane proteins that form an essential part of the protein translocation machinery in Escherichia coli. Sites of direct contact between these two proteins have been suggested by the allele-specific synthetic phenotypes exhibited by pairwise combinations of prlA and prlG signal sequence suppressor mutations in these genes. We have introduced cysteine residues within the first periplasmic loop of SecY and the second periplasmic loop of SecE, at a specific pair of positions identified by this genetic interaction. The expression of the cysteine mutant pair results in a dominant lethal phenotype that requires the presence of DsbA, which catalyzes the formation of disulfide bonds. A reducible SecY-SecE complex is also observed, demonstrating that these amino acids must be sufficiently proximal to form a disulfide bond. The use of cysteine-scanning mutagenesis enabled a second contact site to be discovered. Together, these two points of contact allow the modeling of a limited region of quaternary structure, establishing the first characterized site of interaction between these two proteins. This study proves that actual points of protein-protein contact can be identified by using synthetic phenotypes.