The role of the mature domain of proOmpA in the translocation ATPase reaction.

The export of proOmpA, the precursor of outer membrane protein A from Escherichia coli, requires preprotein translocase, which is comprised of SecA, SecY/E, and acidic phospholipids. Previous studies of proOmpA translocation intermediates (Schiebel, E., Driessen, A. J. M., Hartl, F.-U., and Wickner, W. (1991) Cell 64, 927-939) suggested that the "slippage" of the translocating polypeptide chain and the high level of ATP hydrolysis, characteristic of the "translocation ATPase," were part of a futile cycle. To examine the role of the mature domain of proOmpA in its translocation-dependent ATP hydrolysis, we used chemical cleavage to generate NH2-terminal fragments of this preprotein. Each fragment contained the 21-residue leader region and either 53 or 228 residues of the mature domain (preproteins P74 and P249, respectively). As observed with full-length proOmpA, the translocation of each fragment requires ATP and both the SecA and SecY/E domains of translocase and is stimulated by the transmembrane proton electrochemical gradient. The apparent maximal velocities of P74 and proOmpA translocation are similar. While the translocation of P74 and of proOmpA show the same apparent Km for ATP, far less ATP is hydrolyzed during the translocation of P74. Thus, the mature carboxyl-terminal domain of proOmpA has a major role in supporting the translocation ATPase.     

Delta mu H+ and ATP function at different steps of the catalytic cycle of preprotein translocase.

Preprotein translocation in E. coli requires ATP, the membrane electrochemical potential delta mu H+, and translocase, an enzyme with an ATPase domain (SecA) and the membrane-embedded SecY/E. Studies of translocase and proOmpA binds to the SecA domain. Second, SecA binds ATP. Third, ATP-binding energy permits translocation of approximately 20 residues of proOmpA. Fourth, ATP hydrolysis releases proOmpA. ProOmpA may then rebind to SecA and reenter this cycle, allowing progress through a series of transmembrane intermediates. In the absence of delta mu H+ or association with SecA, proOmpA passes backward through the membrane, but moves forward when either ATP and SecA or a membrane electrochemical potential is supplied. However, in the presence of delta mu H+ (fifth step), proOmpA rapidly completes translocation. delta mu H(+)-driven translocation is blocked by SecA plus nonhydrolyzable ATP analogs, indicating that delta mu H+ drives translocation when ATP and proOmpA are not bound to SecA.     

Preprotein translocation creates a halide anion permeability in the Escherichia coli plasma membrane.

The electrochemical potential drives the translocation of the precursor form of outer membrane protein A (proOmpA) and other proteins across the plasma membrane of Escherichia coli. We have measured the electrical potential, delta psi, across inverted membrane vesicles during proOmpA translocation. delta psi, generated by the electron transport chain, is substantially dissipated by proOmpA translocation. delta psi dissipation requires SecA, ATP, and proOmpA. proOmpA which, due to the covalent addition of a folded protein to a cysteinyl side chain, is arrested during its translocation, can nevertheless cause the loss of delta psi. Thus the movement of charged amino acyl residues is not dissipating the potential. This translocation-specific reduction in delta psi is only seen in the presence of halide anions, although halide anions are not needed for proOmpA translocation per se. We therefore propose that translocation intermediates directly increase the membrane permeability to halide anions.     

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.     

SecD and SecF are required for the proton electrochemical gradient stimulation of preprotein translocation.

Mutations in secD and secF show impaired protein translocation across the inner membrane of Escherichia coli. We investigated the effect of SecD and SecF (SecD/F) depletion on preprotein translocation into inverted inner membrane vesicles (IMVs). Both IMVs and cells which were depleted of SecD/F were defective in their ability to maintain a proton electrochemical gradient. The translocation of pre-maltose binding protein (preMBP), which is strongly delta microH+ dependent, showed a 5-fold decreased rate with IMVs lacking SecD/F. In contrast, proteolytic processing of preMBP to MBP by leader peptidase was similar in IMVs containing and lacking SecD/F, consistent with earlier findings that only ATP-dependent translocation is required for the initiation of translocation. In the absence of a delta microH+, with ATP as the sole energy source, preMBP translocation into IMVs which contained or were depleted of SecD/F was identical. Translocation of the precursor of outer membrane protein A (proOmpA) in the presence of subsaturating ATP also required a generated delta microH+ and, under these conditions, proOmpA translocation required SecD/F. With saturating concentrations of ATP, where delta microH+ has little effect on in vitro proOmpA translocation, SecD/F also had little effect on translocation. These results explain why SecD/F effects are precursor protein dependent in vitro.     

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.     

Electrophysiological studies in Xenopus oocytes for the opening of Escherichia coli SecA-dependent protein-conducting channels

Protein translocation in Escherichia coli requires protein-conducting channels in cytoplasmic membranes to allow precursor peptides to pass through with adenosine triphosphate (ATP) hydrolysis. Here, we report a novel, sensitive method that detects the opening of the SecA-dependent protein-conducting channels at the nanogram level. E. coli inverted membrane vesicles were injected into Xenopus oocytes, and ionic currents were recorded using the two-electrode voltage clamp. Currents were observed only in the presence of E. coli SecA in conjunction with E. coli membranes. Observed currents showed outward rectification in the presence of KCl as permeable ions and were significantly enhanced by coinjection with the precursor protein proOmpA or active LamB signal peptide. Channel activity was blockable with sodium azide or adenylyl 5'-(beta,gamma-methylene)-diphosphonate, a nonhydrolyzable ATP analogue, both of which are known to inhibit SecA protein activity. Endogenous oocyte precursor proteins also stimulated ion current activity and can be inhibited by puromycin. In the presence of puromycin, exogenous proOmpA or LamB signal peptides continued to enhance ionic currents. Thus, the requirement of signal peptides and ATP hydrolysis for the SecA-dependent currents resembles biochemical protein translocation assay with E. coli membrane vesicles, indicating that the Xenopus oocyte system provides a sensitive assay to study the role of Sec and precursor proteins in the formation of protein-conducting channels using electrophysiological methods.     

Multiple SecA molecules drive protein translocation across a single translocon with SecG inversion

SecA is a translocation ATPase that drives protein translocation. D209N SecA, a dominant-negative mutant, binds ATP but is unable to hydrolyze it. This mutant was inactive to proOmpA translocation. However, it generated a translocation intermediate of 18 kDa. Further addition of wild-type SecA caused its translocation into either mature OmpA or another intermediate of 28 kDa that can be translocated into mature by a proton motive force. The addition of excess D209N SecA during translocation caused a topology inversion of SecG. Moreover, an intermediate of SecG inversion was identified when wild-type and D209N SecA were used in the same amounts. These results indicate that multiple SecA molecules drive translocation across a single translocon with SecG inversion. Here, we propose a revised model of proOmpA translocation in which a single catalytic cycle of SecA causes translocation of 10-13 kDa with ATP binding and hydrolysis, and SecG inversion is required when the next SecA cycle begins with additional ATP hydrolysis.     

Translocation can drive the unfolding of a preprotein domain.

Precursor proteins are believed to have secondary and tertiary structure prior to translocation across the Escherichia coli plasma membrane. We now find that preprotein unfolding during translocation can be driven by the translocation event itself. At certain stages, translocation and unfolding can occur without exogenous energy input. To examine this unfolding reaction, we have prepared proOmpA-Dhfr, a fusion protein of the well studied cytosolic enzyme dihydrofolate reductase (Dhfr) connected to the C-terminus of proOmpA, the precursor form of outer membrane protein A. At an intermediate stage of its in vitro translocation, the N-terminal proOmpA domain has crossed the membrane while the folded Dhfr portion, stabilized by its ligands NADPH and methotrexate, has not. When the ligands are removed from this intermediate, translocation occurs by a two-step process. First, 20-30 amino acid residues of the fusion protein translocate concomitant with unfolding of the Dhfr domain. This reaction requires neither ATP, delta mu H+ nor the SecA subunit of translocase. Strikingly, this translocation accelerates the net unfolding of the Dhfr domain. In a second step, SecA and ATP hydrolysis drive the rapid completion of translocation. Thus energy derived from translocation can drive the unfolding of a substantial protein domain.     

Electrophysiological Studies in Xenopus Oocytes for the Opening of Escherichia coli SecA-Dependent Protein-Conducting Channels

Protein translocation in Escherichia coli requires protein-conducting channels in cytoplasmic membranes to allow precursor peptides to pass through with adenosine triphosphate (ATP) hydrolysis. Here, we report a novel, sensitive method that detects the opening of the SecA-dependent protein-conducting channels at the nanogram level. E. coli inverted membrane vesicles were injected into Xenopus oocytes, and ionic currents were recorded using the two-electrode voltage clamp. Currents were observed only in the presence of E. coli SecA in conjunction with E. coli membranes. Observed currents showed outward rectification in the presence of KCl as permeable ions and were significantly enhanced by coinjection with the precursor protein proOmpA or active LamB signal peptide. Channel activity was blockable with sodium azide or adenylyl 5′-(β,γ-methylene)-diphosphonate, a nonhydrolyzable ATP analogue, both of which are known to inhibit SecA protein activity. Endogenous oocyte precursor proteins also stimulated ion current activity and can be inhibited by puromycin. In the presence of puromycin, exogenous proOmpA or LamB signal peptides continued to enhance ionic currents. Thus, the requirement of signal peptides and ATP hydrolysis for the SecA-dependent currents resembles biochemical protein translocation assay with E. coli membrane vesicles, indicating that the Xenopus oocyte system provides a sensitive assay to study the role of Sec and precursor proteins in the formation of protein-conducting channels using electrophysiological methods.     

ProOmpA spontaneously folds in a membrane assembly competent state which trigger factor stabilizes.

The precursor protein proOmpA can translocate across purified Escherichia coli inner membrane vesicles in the absence of any other soluble proteins. ProOmpA, purified 2000-fold in the presence of 8 M urea, is competent for translocation following rapid renaturation via dilution. ATP, the transmembrane electrochemical potential, and functional secY protein are essential for the translocation of proOmpA renatured by dilution. The kinetics of its translocation and the level of translocation at each concentration of ATP are indistinguishable from that of proOmpA renatured by dialysis with trigger factor. After dilution, the proOmpA rapidly loses its competence for membrane assembly. However, this competence is stabilized by trigger factor. Assembly-competent proOmpA is in a protease-sensitive conformation, whereas proOmpA which has lost this competence is more resistant to degradation. This suggests that the primary role for trigger factor in in vitro protein translocation is to maintain precursor proteins in a translocation-competent conformation. We propose that a properly folded precursor protein and ATP are the only soluble components which are essential for bacterial protein translocation.     

Direct demonstration of ATP-dependent release of SecA from a translocating preprotein by surface plasmon resonance

Translocase mediates the transport of preproteins across the inner membrane of Escherichia coli. SecA binds with high affinity to the membrane-embedded protein-conducting SecYEG complex and serves as both a receptor for secretory proteins and as an ATP-driven molecular motor. Cycles of ATP binding and hydrolysis by SecA drive the progressive movement of the preprotein across the membrane. Surface plasmon resonance allows an online monitoring of protein interactions. Here we report on the kinetic analysis of the interaction between SecA and the membrane-embedded SecYEG complex. Immobilization of membrane vesicles containing overproduced SecYEG on the Biacore Pioneer L1 chip allows the detection of high affinity SecA binding to the SecYEG complex and online monitoring of the translocation of the secretory protein proOmpA. SecA binds tightly to the SecYEG.proOmpA complex and is released only upon ATP hydrolysis. The results provide direct evidence for a model in which SecA cycles at the SecYEG complex during translocation.     

Translocation of ProOmpA possessing an intramolecular disulfide bridge into membrane vesicles of Escherichia coli. Effect of membrane energization

In the absence of delta mu H+, the in vitro translocation of proOmpA resulted in the stable accumulation of a possible translocation intermediate in addition to a transiently accumulating one. The stable intermediate was detected on a polyacrylamide gel as two proteinase K-resistant bands corresponding to a molecular weight of about 28,000. The appearance of the bands was appreciably enhanced when proOmpA was oxidized with ferricyanide. No mature OmpA appeared. When proOmpA reduced with dithiothreitol was used, on the other hand, the bands did not appear at all. Upon the replacement of Cys302 of OmpA with Gly, the intermediate accumulation was abolished. The proOmpA treated with dithiothreitol was labeled with N-[3H]-ethylmaleimide, whereas that treated with ferricyanide was not. The ferricyanide-treated proOmpA was translocated into membrane vesicles in the presence of delta mu H+. The mature OmpA thus translocated and processed was not labeled with N-[3H]ethylmaleimide. It is concluded that proOmpA possessing the Cys290-Cys302 disulfide bridge can be translocated without cleavage of the bridge, when delta mu H+ is imposed. The accumulation of the disulfide bridge-containing intermediate was ATP-dependent, whereas its conversion to the translocated mature form was not blocked in the presence of adenosine 5'-(beta, gamma-imino)triphosphate. It is concluded that the early and late stages of the translocation reaction require ATP and delta mu H+ differently.     

Characterization of a mutant form of SecA that alleviates a SecY defect at low temperature and shows a synthetic defect with SecY alteration at high temperature

The secY205 mutant is cold-sensitive for protein export, with an in vitro defect in supporting ATP- and preprotein-dependent insertion of SecA into the membrane. We characterized SecA81 with a Gly516 to Asp substitution near the minor ATP-binding region, which suppresses the secY205 defect at low temperature and exhibits an allele-specific synthetic defect with the same SecY alteration at 42 degrees C. The overproduced SecA81 aggregated in vivo at temperatures above 37 degrees C. Purified SecA81 exhibited markedly enhanced intrinsic and membrane ATPase activities at 30 degrees C, while it was totally inactive at 42 degrees C. The trypsin digestion patterns indicated that SecA81 has some disorder in the central region of SecA, which encompasses residues 421-575. This conformational abnormality may result in unregulated ATPase at low temperature as well as the thermosensitivity of the mutant protein. In the presence of both proOmpA and the wild-type membrane vesicles, however, the thermosensitivity was alleviated, and SecA81 was able to catalyze significant levels of proOmpA-stimulated ATP hydrolysis as well as proOmpA translocation at 42 degrees C. While SecA81 was able to overcome the SecY205 defect at low temperature, the SecY205 membrane vesicles could not significantly support the translocation ATPase or the proOmpA translocation activity of SecA81 at 42 degrees C. The inactivated SecA81 molecules seemed to jam the translocase since it interfered with translocase functions at 42 degrees C. Based on these results, we propose that under preprotein-translocating conditions, the SecYEG channel can stabilize and activate SecA, and that this aspect is defective for the SecA81-SecY205 combination. The data also suggest that the conformation of the central region of SecA is important for the regulation of ATP hydrolysis and for the productive interaction of SecA with SecY.     

A chemically cross-linked nonlinear proOmpA molecule can be translocated into everted membrane vesicles of Escherichia coli in the presence of the proton motive force.

The chemical cross-linking between the two cysteine residues at positions + 290 and + 302 of proOmpA was performed with N,N'-bis(3-maleimidopropionyl)-2-hydroxy-1,3-propanediamine. In the absence of the proton motive force (delta muH+), the cross-linked proOmpA was only partially translocated into everted membrane vesicles, leading to accumulation of translocation intermediates. In the presence of delta mu H+, the cross-linked proOmpA was completely translocated. The translocated OmpA still possessed the cross-linked loop composed of 13 amino acid residues and the cross-linker. It is concluded that polypeptide chains need not be necessarily linear and fully expanded to be translocated.     

The conformation of SecA, as revealed by its protease sensitivity, is altered upon interaction with ATP, presecretory proteins, everted membrane vesicles, and phospholipids

Interactions between SecA and cellular components involved in the translocation of secretory proteins across the cytoplasmic membrane of Escherichia coli were studied by examining changes in the sensitivity of SecA to staphylococcal protease V8. In the presence of ATP, the amino-terminal 95-kDa portion of the SecA molecule became highly resistant to V8 digestion. Adenosine 5'-(gamma-thio)triphosphate (ATP gamma S) and ADP were as effective as ATP. For the effect, ATP could be partly replaced by CTP and UTP, but not GTP, as in the case of the protein translocation reaction. In the presence of proOmpA, a presecretory protein, on the other hand, SecA became more sensitive to V8 digestion. The signal peptide region was involved in this effect. The V8-digestion profile in the presence of both proOmpA and ATP or ADP was the same as that in the presence of proOmpA alone. Consistently, proOmpA-induced discharge of ADP or ATP gamma S from SecA was observed by means of flow dialysis. SecA-deprived everted membrane vesicles and an E. coli phospholipid mixture were also effective in making SecA more sensitive to V8 digestion. Among the phospholipids, phosphatidylglycerol and cardiolipin were effective, whereas phosphatidylethanolamine was not. It is suggested that SecA directly interacts with these cellular components and the interactions result in changes in the conformation of SecA. The physiological significance of such interactions in protein secretion is discussed.     

Secretion in yeast: preprotein binding to a membrane receptor and ATP- dependent translocation are sequential and separable events in vitro

We have used a cytosol-free assay in which efficient translocation and signal peptide cleavage is achieved when the affinity-purified precursor of OmpA (proOmpA) is diluted out of 8 M urea into a suspension of yeast rough microsomes. This aspect of protein targeting and transport occurs in two discernible steps: (a) in the absence of ATP and cytosolic factors, the precursor binds to the membranes but is not translocated; (b) addition of ATP results in the translocation of the bound precursor and its processing to the mature form. The binding to microsomes of radiolabeled proOmpA is saturable and inhibited by the addition of unlabeled proOmpA but not by mature OmpA or other proteins. The binding of radiolabeled prepro-alpha-factor is also effectively competed by other preproteins, but not by mature ones. Scatchard analysis showed the Kd of proOmpA to be 7.5 X 10(-9) M. Binding is most likely protein mediated as treatment of the microsomes with the protease papain was found to be inhibitory. These results represent the first functional characterization of secretory protein precursor binding to membranes. Alkylation of the microsomes with NEM, washing the membranes with urea or using membranes from the (translocation) mutant ptll at the nonpermissive temperature, did not affect binding, but did eliminate the subsequent ATP-dependent translocation. The ability to subdivide translocation into individual reactions provides a more precise means of determining the membrane components involved in this process.     

Glutamate uptake into synaptic vesicles of bovine cerebral cortex and electrochemical potential difference of proton across the membrane.

Measurements have been made of the ATP-dependent membrane potential (delta psi) and pH gradient (delta pH) across the membranes of the synaptic vesicles purified from bovine cerebral cortex, using the voltage-sensitive dye bis[3-propyl-5-oxoisoxazol-4-yl]pentamethine oxanol and the delta pH-sensitive fluorescent dye 9-aminoacridine respectively. A pre-existing small delta pH (inside acidic) was detected in the synaptic vesicles, but no additional significant contribution by MgATP to delta pH was observed. In contrast, delta psi (inside positive) increased substantially upon addition of MgATP. This ATP-dependent delta psi was reduced by thiocyanate anion (SCN-), a delta psi dissipator, or carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP), a protonmotive-force dissipator. Correspondingly, a substantially larger glutamate uptake occurred in the presence of MgATP, which was inhibited by SCN- and FCCP. A nonhydrolysable analogue of ATP, adenosine 5'-[beta gamma-methylene]triphosphate, did not substitute for ATP in either delta psi generation or glutamate uptake. The results support the hypothesis that a H+-pumping ATPase generates a protonmotive force in the synaptic vesicles at the expense of ATP hydrolysis, and the protonmotive force thus formed provides a driving force for the vesicular glutamate uptake. The delta psi generation by ATP hydrolysis was not affected by orthovanadate, ouabain or oligomycin, but was inhibited by N-ethylmaleimide, quercetin, trimethyltin, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid. These results indicate that the H+-pumping ATPase in the synaptic vesicle is similar to that in the chromaffin granule, platelet granule and lysosome.     

Sec-dependent membrane protein biogenesis: SecYEG, preprotein hydrophobicity and translocation kinetics control the stop-transfer function.

Preprotein translocase catalyzes membrane protein integration as well as complete translocation. Membrane proteins must interrupt their translocation and be laterally released from the translocase into the lipid bilayer. We have analyzed the translocation arrest and lateral release activities of Escherichia coli preprotein translocase with an in vitro reaction and the preprotein proOmpA carrying a synthetic stop-transfer sequence. Membrane protein integration is catalytic, occurs with kinetics similar to those of proOmpA itself and only requires the functions of SecYEG and SecA. Though a strongly hydrophobic segment will direct the protein to leave the translocase and enter the lipid bilayer, a protein with a segment of intermediate hydrophobicity partitions equally between the translocated and membrane-integrated states. Analysis of the effects of PMF, varied ATP concentrations or synthetic translocation arrest show that the stop-translocation efficiency of a mildly hydrophobic segment depends on the translocation kinetics. In contrast, the lateral partitioning from translocase to lipids depends solely on temperature and does not require SecA ATP hydrolysis or SecA membrane cycling. Thus translocation arrest is controlled by the SecYEG translocase activity while lateral release and membrane integration are directed by the hydrophobicity of the segment itself. Our results suggest that a greater hydrophobicity is required for efficient translocation arrest than for lateral release into the membrane.     

The proton motive force lowers the level of ATP required for the in vitro translocation of a secretory protein in Escherichia coli

The role of the electrochemical potential difference of proton (delta mu H+) in protein translocation across the membrane of Escherichia coli was examined in detail using an efficient in vitro assay system (Yamada, H., Tokuda, H., and Mizushima, S. (1989) J. Biol. Chem. 264, 1723-1728). Delta mu H+ reduced the level of ATP necessary for the efficient translocation of OmpF-Lpp, a chimeric model secretory protein. The apparent Km value of the translocation reaction for ATP was lower by 2 orders of magnitude in the presence of delta mu H+ than in its absence. The membrane potential and delta pH, both of which are components of delta mu H+, independently lowered the apparent Km value of the translocation reaction for ATP. An ATP-generating system also lowered the level of ATP required for translocation in the absence of delta mu H+ but not in its presence. It is proposed that ADP formed during protein translocation lowers the affinity of the putative translocation machinery for ATP and that the removal of ADP from the secretory machinery, a possible critical step in the translocation reaction, is stimulated in the presence of either delta mu H+, an ATP-generating system, or a higher concentration of ATP.