SecA protein, a peripheral protein of the Escherichia coli plasma membrane, is essential for the functional binding and translocation of proOmpA.

We have reconstituted protein translocation across plasma membrane vesicles of Escherichia coli using purified proOmpA and trigger factor, a 63 kd soluble protein. Treatment of membrane vesicles with urea inactivates them for translocation unless a factor present in cytoplasmic extracts is added during the translocation reaction. Sedimentation analysis showed that the stimulatory activity is of distinctly higher mol. wt than trigger factor. Cytoplasmic extracts from a strain that greatly overproduces the SecA protein are highly enriched in the stimulatory activity for untreated membranes and restore translocation to urea-treated membranes, suggesting that this protein is the stimulatory factor. This assay was used to monitor the isolation of SecA protein from the overproducing strain. The purified protein is soluble, yet binds peripherally to membranes with high affinity and supports translocation. Using pure proOmpA, SecA protein, trigger factor and urea-treated membranes, the protein export process was resolved into binding and translocation steps. We find that proOmpA binds to membrane vesicles with or without SecA protein, but that translocation only occurs when SecA was bound prior to proOmpA.     

SecA protein hydrolyzes ATP and is an essential component of the protein translocation ATPase of Escherichia coli.

Bacterial protein export requires two forms of energy input, ATP and the membrane electrochemical potential. Using an in vitro reaction reconstituted with purified soluble and peripheral membrane components, we can now directly measure the translocation-coupled hydrolysis of ATP. This translocation ATPase requires inner membrane vesicles, SecA protein and translocation-competent proOmpA. The stimulatory activity of membrane vesicles can be blocked by either antibody to the SecY protein or by preparing the membranes from a secY-thermosensitive strain which had been incubated at the non-permissive temperature in vivo. The SecA protein itself has more than one ATP binding site. 8-azido-ATP inactivates SecA for proOmpA translocation and for translocation ATPase, yet does not inhibit a low level of ATP hydrolysis inherent in the isolated SecA protein. These data show that the SecA protein has a central role in coupling the hydrolysis of ATP to the transfer of pre-secretory proteins across the membrane.     

SecA protein is required for secretory protein translocation into E. coli membrane vesicles

The soluble and membrane components of an E. coli in vitro protein translocation system prepared from a secA amber mutant, secA13[Am], contain reduced levels of SecA and are markedly defective in both the cotranslational and posttranslational translocation of OmpA and alkaline phosphatase into membrane vesicles. Moreover, the removal of SecA from soluble components prepared from a wild-type strain by passage through an anti-SecA antibody column similarly abolishes protein translocation. Translocation activity is completely restored by addition of submicrogram amounts of purified SecA protein, implying that the observed defects are solely related to loss of SecA function. Interestingly, the translocation defect can be overcome by reconstitution of SecA into SecA-depleted membranes, suggesting that SecA is an essential, membrane-associated translocation factor.     

SecY and SecA interact to allow SecA insertion and protein translocation across the Escherichia coli plasma membrane.

SecA, the preprotein-driving ATPase in Escherichia coli, was shown previously to insert deeply into the plasma membrane in the presence of ATP and a preprotein; this movement of SecA was proposed to be mechanistically coupled with preprotein translocation. We now address the role played by SecY, the central subunit of the membrane-embedded heterotrimeric complex, in the SecA insertion reaction. We identified a secY mutation (secY205), affecting the most carboxyterminal cytoplasmic domain, that did not allow ATP and preprotein-dependent productive SecA insertion, while allowing idling insertion without the preprotein. Thus, the secY205 mutation might affect the SecYEG 'channel' structure in accepting the preprotein-SecA complex or its opening by the complex. We isolated secA mutations that allele-specifically suppressed the secY205 translocation defect in vivo. One mutant protein, SecA36, with an amino acid alteration near the high-affinity ATP-binding site, was purified and suppressed the in vitro translocation defect of the inverted membrane vesicles carrying the SecY205 protein. The SecA36 protein could also insert into the mutant membrane vesicles in vitro. These results provide genetic evidence that SecA and SecY specifically interact, and show that SecY plays an essential role in insertion of SecA in response to a preprotein and ATP and suggest that SecA drives protein translocation by inserting into the membrane in vivo.     

The purified E. coli integral membrane protein SecY/E is sufficient for reconstitution of SecA-dependent precursor protein translocation

We have previously reconstituted the soluble phase of precursor protein translocation in vitro using purified proteins (the precursor proOmpA, the chaperone SecB, and the ATPase SecA) in addition to isolated inner membrane vesicles. We now report the isolation of the SecY/E protein, the integral membrane protein component of the E. coli preprotein translocase. The SecY/E protein, reconstituted into proteoliposomes, acts together with SecA protein to support translocation of proOmpA, the precursor form of outer membrane protein A. This translocation requires ATP and is strongly stimulated by the protonmotive force. The initial rates and the extents of translocation into either native membrane vesicles or proteoliposomes with pure SecY/E are comparable. The SecY/E protein consists of SecY, SecE, and an additional polypeptide. Antiserum against SecY immunoprecipitates all three components of the SecY/E protein.     

In vitro protein translocation into inverted membrane vesicles prepared from Vibrio alginolyticus is stimulated by the electrochemical potential of Na+ in the presence of Escherichia coli SecA

A protein translocation system was reconstituted from inverted membrane vesicles prepared from Na+ pump-possessing Vibrio alginolyticus and purified Escherichia coli SecA. The translocation required ATP and was stimulated by the functioning of the Na+ pump, suggesting that the electrochemical potential of Na+, but not that of H+, is important for protein translocation in Vibrio.     

Topology inversion of SecG is essential for cytosolic SecA-dependent stimulation of protein translocation

SecG, a subunit of the protein translocon, undergoes a cycle of topology inversion. To further examine the role of this topology inversion, we analyzed the activity of membrane vesicles carrying a SecG-PhoA fusion protein (SecG-PhoA inverted membrane vesicles (IMVs)). In the absence of externally added SecA, SecG-PhoA IMVs were as active in protein translocation as SecG(+) IMVs per SecA. Consistent with this observation, insertion of membrane-bound SecA into SecG-PhoA IMVs was normally observed. On the other hand, externally added SecA did not affect the activity of SecG-PhoA IMVs, but it caused >10-fold stimulation of the translocation activity of SecG(+) IMVs, indicating that the topology inversion of SecG, which cannot occur in SecG-PhoA IMVs, is essential for cytosolic SecA-dependent stimulation of protein translocation. SecG-PhoA IMVs generated a 46-kDa fragment of SecA upon trypsin treatment. The accumulation of this membrane-inserted SecA in the SecG-PhoA IMVs was responsible for the loss of the soluble SecA-dependent stimulation. Moreover, fixation of the inverted SecG topology was found to be dependent on soluble SecA. The dual functions of SecG in protein translocation will be discussed.     

A novel membrane protein involved in protein translocation across the cytoplasmic membrane of Escherichia coli.

A novel factor, which is a membrane component of the protein translocation machinery of Escherichia coli, was discovered. This factor was found in the trichloracetic acid-soluble fraction of solubilized cytoplasmic membrane. The factor was purified to homogeneity by ion exchange column chromatographies and found to be a hydrophobic protein with a molecular mass of approximately 12 kDa. The factor caused > 20-fold stimulation of the protein translocation when it was reconstituted into proteoliposomes together with SecE and SecY. SecE, SecY, SecA and ATP were essential for the factor-dependent stimulation of the activity. The factor stimulated the translocation of all three precursor proteins examined, including authentic proOmpA. Stimulation of the translocation of proOmpF-Lpp, a model presecretory protein, was especially remarkable, since no translocation was observed unless proteoliposomes were reconstituted with the factor. Partial amino acid sequence of the purified factor was determined. An antibody raised against a synthetic peptide of this sequence inhibited the protein translocation into everted membrane vesicles, indicating that the factor is playing an important role in protein translocation into membrane vesicles. The partial amino acid sequence was found to coincide with that deduced from the reported DNA sequence of the upstream region of the leuU gene. Cloning and sequencing of the upstream region revealed the presence of a new open reading frame, which encodes a hydrophobic protein of 11.4 kDa. We propose that the factor is a general component of the protein translocation machinery of E. coli.     

SecA protein needs both acidic phospholipids and SecY/E protein for functional high-affinity binding to the Escherichia coli plasma membrane.

Translocation of preproteins across the Escherichia coli inner membrane requires acidic phospholipids. We have studied the translocation of the precursor protein proOmpA across inverted inner membrane vesicles prepared from cells depleted of phosphatidylglycerol and cardiolipin. These membranes support neither translocation nor the translocation ATPase activity of the SecA subunit of preprotein translocase. We now report that inner membrane vesicles which are depleted of acidic phospholipids are unable to bind SecA protein with high affinity. These membranes can be restored to translocation competence by fusion with liposomes containing phosphatidylglycerol, suggesting that the defect in SecA binding is a direct effect of phospholipid depletion rather than a general derangement of inner membrane structure. Reconstitution of SecY/E, the membrane-embedded domain of translocase, into proteoliposomes containing predominantly a single synthetic acidic lipid, dioleoylphosphatidylglycerol, allows efficient catalysis of preprotein translocation.     

Characterization of a Bacillus subtilis SecA mutant protein deficient in translocation ATPase and release from the membrane

SecA is the precursor protein binding subunit of the bacterial precursor protein translocase, which consists of the SecY/E protein as integral membrane domain. SecA is an ATPase, and couples the hydrolysis of ATP to the release of bound precursor proteins to allow their proton-motive-force-driven translocation across the cytoplasmic membrane. A putative ATP-binding motif can be predicted from the amino acid sequence of SecA with homology to the consensus Walker A-type motif. The role of this domain is not known. A lysine residue at position 106 at the end of the glycine-rich loop in the A motif of the Bacillus subtilis SecA was replaced by an asparagine through site-directed mutagenesis (K106N SecA). A similar replacement was introduced at an adjacent lysine residue at position 101 (K101N SecA). Wild-type and mutant SecA proteins were expressed to a high level and purified to homogeneity. The catalytic efficacy (k_cat/k_m) of the K106N SecA for lipid-stimulated ATP hydrolysis was only 1% of that of the wild-type and K101N SecA. K106N SecA retained the ability to bind ATP, but its ATPase activity was not stimulated by precursor proteins. Mutant and wild-type SecA bind with similar affinity to Escherichia coli inner membrane vesicles and insert into a phospholipid mono-layer, in contrast to the wild type, membrane insertion of the K106N SecA was not prevented by ATP. K106N SecA blocks the ATP and proton-motive-force-dependent chase of a translocation intermediate to fully translocated proOmpA. It is concluded that the GKT motif in the amino-terminal domain of SecA is part of the catalytic ATP-binding site. This site may be involved in the ATP-driven protein recycling function of SecA which allows the release of SecA from its association with precursor proteins, and the phospholipid bilayer.     

Determinants of membrane-targeting and transmembrane translocation during bacterial protein export.

We have separately analyzed membrane-targeting and membrane translocation of an exported bacterial protein. The precursor of the outer membrane protein LamB of Escherichia coli was synthesized in vitro and translocated into inverted plasma membrane vesicles under co- and post-translational conditions. The translation/translocation products of LamB were subsequently resolved into soluble and membrane-associated material. Dissipation of the H(+)-motive force, depletion of ATP and treatment of membranes with N-ethylmaleimide each inhibited processing and translocation of preLamB without preventing its binding to the membranes. Hence, all three conditions block transmembrane passage rather than membrane-targeting. The latter was abolished by pretreatment of salt-extracted membrane vesicles with trypsin. It was also drastically reduced when preLamB was synthesized in cell extracts derived from either a secA amber or a secB null mutant. Membrane-targeting of preLamB therefore requires soluble SecA and SecB as well as a protease-sensitive membrane receptor. The finding that SecA is involved in targeting whereas ATP is required for the transmembrane passage suggests that SecA, which harbors an ATPase activity [Lill et al. (1989), EMBO J., 8, 961-966], might have a dual function in bacterial protein export.     

A mutation in secY that causes enhanced SecA insertion and impaired late functions in protein translocation

A cold-sensitive secY mutant (secY125) with an amino acid substitution in the first periplasmic domain causes in vivo retardation of protein export. Inverted membrane vesicles prepared from this mutant were as active as the wild-type membrane vesicles in translocation of a minute amount of radioactive preprotein. The mutant membrane also allowed enhanced insertion of SecA, and this SecA insertion was dependent on the SecD and SecF functions. These and other observations suggested that the early events in translocation, such as SecA-dependent insertion of the signal sequence region, is actually enhanced by the SecY125 alteration. In contrast, since the mutant membrane vesicles had decreased capacity to translocate chemical quantity of pro-OmpA and since they were readily inactivated by pretreatment of the vesicles under the conditions in which a pro-OmpA translocation intermediate once accumulated, the late translocation functions appear to be impaired. We conclude that this periplasmic secY mutation causes unbalanced early and late functions in translocation, compromising the translocase's ability to catalyze multiple rounds of reactions.     

Coupled structure change of SecA and SecG revealed by the synthetic lethality of the secAcsR11 and ΔsecG::kan double mutant

An Escherichia coli strain carrying either the secAcsR11 or Δ secG :: kan mutation is unable to grow at low temperature owing to cold-sensitive protein translocation but grows normally at 37°C. However, introduction of the two mutations into the same cells caused a severe defect in protein translocation and the cells were unable to grow at any temperature examined, indicating that secG is essential for the secAcsR11 mutant. The mutant SecA (csSecA) was found to possess a single amino acid substitution in the precursor-binding region and was defective in the interaction with the precursor protein. Furthermore, the membrane insertion of SecA and the membrane topology inversion of SecG, both of which took place upon the initiation of protein translocation, were significantly retarded even at 37°C, when csSecA was used instead of the wild-type SecA. The insertion of the wild-type SecA was also significantly defective when SecG-depleted membrane vesicles were used in place of SecG-containing ones. No insertion of csSecA occurred into SecG-depleted membrane vesicles. Examination of in vitro protein translocation at 37°C revealed that SecG is essential for csSecA-dependent protein translocation. We conclude that SecG and SecA undergo a coupled structure change, that is critical for efficient protein translocation.     

A high concentration of SecA allows proton motive force-independent translocation of a model secretory protein into Escherichia coli membrane vesicles

The in vitro translocation of OmpF-Lpp, a model secretory protein, into inverted membrane vesicles of Escherichia coli obligatorily requires the proton motive force (delta mu H+) in the conventional assay system (Yamada, H., Tokuda, H., and Mizushima, S. (1989) J. Biol. Chem. 264, 1723-1728). The translocation, however, took place efficiently, even in the absence of delta mu H+, when the system was supplemented with additional SecA. With the stripped membrane vesicles, which are permeable to protons, or in the absence of NADH, the supplementation of SecA remarkably stimulated the translocation activity. The further addition of NADH did not significantly enhance the translocation activity under the SecA-enriched conditions. OmpF-Lpp thus translocated could be recovered from the vesicular lumen by sonication, indicating that complete translocation occurred in the absence of delta mu H+. It is suggested that delta mu H+ is required for high affinity interaction of SecA with the presumed secretory machinery in the cytoplasmic membrane and that a high concentration of SecA modulates the delta mu H+ requirement.     

Development of a minimal cell-free translation system for the synthesis of presecretory and integral membrane proteins

By combining translation and membrane integration/translocation systems, we have constructed a novel cell-free system for the production of presecretory and integral membrane proteins in vitro. A totally defined, cell-free system reconstituted from a minimal number of translation factors was supplemented with urea-washed inverted membrane vesicles (U-INVs) prepared from Escherichia coli, as well as with purified proteins mediating membrane targeting of presecretory and integral membrane proteins. Initially, efficient membrane translocation of a presecretory protein (pOmpA) was obtained simply by the addition of only SecA and SecB. Proteinase K digestion clearly showed the successful translocation of pOmpA inside the vesicles. Next, integration of an inner membrane protein (MtlA) into U-INVs was achieved in the presence of only SRP (Ffh) and SR (FtsY). Finally, a membrane protein possessing a large periplasmic region (FtsQ) and therefore requiring both factors (SRP/SR and SecA/SecB) for membrane integration/translocation was also shown to be integrated correctly in this cell-free system. Thus, our novel cell-free system provides not only an efficient strategy for the production of membrane-related proteins but also an improved platform for the biological study of protein translocation and integration mechanisms.     

Selective SecA association with signal sequences in ribosome-bound nascent chains: a potential role for SecA in ribosome targeting to the bacterial membrane

The role of SecA in selecting bacterial proteins for export was examined using a heterologous system that lacks endogenous SecA and other bacterial proteins. This approach allowed us to assess the interaction of SecA with ribosome-bound photoreactive nascent chains in the absence of trigger factor, SecB, Ffh (the bacterial protein component of the signal recognition particle), and the SecYEG translocon in the bacterial plasma membrane. In the absence of membranes, SecA photocross-linked efficiently to nascent translocation substrate OmpA in ribosome-nascent chain (RNC) complexes in an interaction that was independent of both ATP and SecB. However, no photocross-linking to a nascent membrane protein that is normally targeted by a signal recognition particle was observed. Modification of the signal sequence revealed that its affinity for SecA and Ffh varied inversely. Gel filtration showed that SecA binds tightly to both translating and non-translating ribosomes. When purified SecA.RNC complexes containing nascent OmpA were exposed to inner membrane vesicles lacking functional SecA, the nascent chains were successfully targeted to SecYEG translocons. However, purified RNCs lacking SecA were unable to target to the same membranes. Taken together, these data strongly suggest that cytosolic SecA participates in the selection of proteins for export by co-translationally binding to the signal sequences of non-membrane proteins and directing those nascent chains to the translocon.     

SecB protein stabilizes a translocation-competent state of purified prePhoE protein

Efficient translocation of pure precursor of PhoE protein (prePhoE) could be accomplished in an in vitro system consisting of only inverted Escherichia coli inner membrane vesicles, ATP, and SecA and SecB protein. In this in vitro system SecB and not trigger factor could stabilize a translocation-competent state of prePhoE. In contrast, translocation competency of proOmpA could be induced by both trigger factor and SecB protein, suggesting specificity in interactions between cytosolic factors and precursors in outer membrane protein translocation.     

Covalently dimerized SecA is functional in protein translocation

The ATPase SecA provides the driving force for the transport of secretory proteins across the cytoplasmic membrane of Escherichia coli. SecA exists as a dimer in solution, but the exact oligomeric state of SecA during membrane binding and preprotein translocation is a topic of debate. To study the requirements of oligomeric changes in SecA during protein translocation, a non-dissociable SecA dimer was formed by oxidation of the carboxyl-terminal cysteines. The cross-linked SecA dimer interacts with the SecYEG complex with a similar stoichiometry as non-cross-linked SecA. Cross-linking reversibly disrupts the SecB binding site on SecA. However, in the absence of SecB, the activity of the disulfide-bonded SecA dimer is indistinguishable from wild-type SecA. Moreover, SecYEG binding stabilizes a cold sodium dodecylsulfate-resistant dimeric state of SecA. The results demonstrate that dissociation of the SecA dimer is not an essential feature of the protein translocation reaction.     

Membrane deinsertion of SecA underlying proton motive force-dependent stimulation of protein translocation

The proton motive force (PMF) renders protein translocation across the Escherichia coli membrane highly efficient, although the underlying mechanism has not been clarified. The membrane insertion and deinsertion of SecA coupled to ATP binding and hydrolysis, respectively, are thought to drive the translocation. We report here that PMF significantly decreases the level of membrane-inserted SecA. The prlA4 mutation of SecY, which causes efficient protein translocation in the absence of PMF, was found to reduce the membrane-inserted SecA irrespective of the presence or absence of PMF. The PMF-dependent decrease in the membrane-inserted SecA caused an increase in the amount of SecA released into the extra-membrane milieu, indicating that PMF deinserts SecA from the membrane. The PMF-dependent deinsertion reduced the amount of SecA required for maximal translocation activity. Neither ATP hydrolysis nor exchange with external SecA was required for the PMF-dependent deinsertion of SecA. These results indicate that the SecA deinsertion is a limiting step of protein translocation and is accelerated by PMF, efficient protein translocation thereby being caused in the presence of PMF.