Short Hydrophobic Segments in the Mature Domain of ProOmpA Determine Its Stepwise Movement during Translocation across the Cytoplasmic Membrane of Escherichia coli*

(Received for publication, September 17, 1996, and in revised form, November 12, 1996)

Ken Sato Dagger §, Hiroyuki Mori , Masasuke Yoshida Dagger , Mitsuo Tagaya and Shoji Mizushima

From the Dagger  Research Laboratory of Resources Utilization, Tokyo Institute of Technology, Nagatsuta 4259, Yokohama 226 and the  School of Life Science, Tokyo University of Pharmacy and Life Science, Horinouchi 1432-1, Hachioji, Tokyo 192-03, Japan

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

Based on the finding that a series of engineered proOmpAs containing disulfide-bridged loops of different sizes at different positions exhibits a discontinuous mode of polypeptide transit across the cytoplasmic membrane of Escherichia coli, we suggested previously that the translocation of preproteins takes place at every 30 amino acid residues (Uchida, K., Mori, H., and Mizushima, S. (1995) J. Biol. Chem. 270, 30862-30868). In the present study, we investigated the molecular mechanism underlying this stepwise translocation. Deletion or relocation of hydrophobic segments of the mature domain of proOmpA (H1, residues 233-237; H2, residues 261-265) significantly altered the pattern of the stepwise translocation. The stepwise mode of polypeptide insertion was also observed with reconstituted proteoliposomes comprising purified SecA, SecY, and SecE. Cross-linking experiments involving a photoactivable cross-linker revealed that SecY and SecA are the components which interact with the hydrophobic segment of proOmpA. The present results indicate that the hydrophobic segments of the mature domains of preproteins interact with membrane embedded translocase during polypeptide transit across the membrane, which causes a discontinuous mode of polypeptide movement.


INTRODUCTION

The translocation of preproteins across the cytoplasmic membrane of Escherichia coli is mediated through interactions of molecules, including a set of Sec proteins (1-5). The driving force for translocation is provided by the proton motive force and the energy formed through SecA-mediated hydrolysis of ATP (6-9). SecY, SecE, and SecG, a heterotrimeric membrane-embedded translocase, provide an intramembrane pathway for preprotein transit (10-12). Biochemical studies, such as purification of the components of the translocase and their reconstitution into proteoliposomes of specified compositions in E. coli systems, have been performed (13, 14). These studies revealed the minimum components required for translocation and their modes of action in substantial detail. However, the details of the mechanism by which preproteins move through the cytoplasmic membrane remains to be elucidated.

In previous studies, we showed that a proOmpA derivative containing a disulfide-bridged loop between Cys-290 and Cys-302 can be translocated across everted membrane vesicles of the cytoplasmic membrane of E. coli. In the absence of the proton motive force, on the other hand, translocation ceased when the loop reached the membrane (15, 16). Taking advantage of this phenomenon, we analyzed how preproteins are translocated across the membrane. We changed the position of one of the cysteine residues (cysteine-290) toward the N terminus so as to obtain proOmpA derivatives with disulfide-bridged loops of different sizes at different positions (17). We expected that the lengths of the translocated polypeptides would become shorter as the first cysteine residue becomes closer to the N terminus, if translocation ceases at the position of the loop. In contrast to our expectation, however, we found that the size of the translocated polypeptides remained almost the same for OmpA derivatives containing loops of 10-25 and 29-59 amino acid residues, respectively, with a change of about 3 kDa. This suggested that the in vitro translocation of proOmpA through the secretory machinery takes place in every 30 amino acid residue segments. Under certain conditions, the movement of a polypeptide chain by about 20 amino acid residues during translocation was also demonstrated upon the addition of a nonhydrolyzable ATP analog, ATPgamma S1 or AMP-PNP (7). SecA may be involved in this discontinuous polypeptide transition. The binding of ATP to SecA results in the membrane insertion of a 30-kDa fragment of the SecA protein (18), which may be accompanied by the insertion of segments of preproteins into the membrane.

Although the insertion-deinsertion cycle of SecA may partly explain the stepwise translocation of preproteins, the details of the mechanism remained unclear. It is quite difficult to imagine that SecA strictly recognizes every 30 amino acid residue segments, which have a wide variety of physicochemical properties. We therefore assume that the mature domains of preproteins have some elements that control their stepwise movement.

In the present study, we examined whether or not hydrophobic segments of the mature domain of proOmpA determine the stepwise movement during translocation across everted membrane vesicles of E. coli. We focused on the fact that many outer membrane proteins in addition to OmpA periodically contain hydrophobic segments in their mature domains, although they are hydrophilic in general (19). We relocated or replaced hydrophobic segment(s) with an artificial hydrophilic sequence(s), and compared the patterns of stepwise movement.


EXPERIMENTAL PROCEDURES

Materials

Everted membrane vesicles were isolated from E. coli K003 (Lpp-, Delta uncB-C-Tn10) as described previously (20). SecA was purified as described previously (21). Mutant proOmpAs were purified as described by Crooke et al. (22), and SecB was purified as described by Weiss et al. (23). All proOmpA derivatives used for the in vitro translocation reactions were synthesized in vitro in the presence of EXPRE35S35S protein labeling mix (DuPont NEN) (17). SecE and SecY were purified as described by Akimaru et al. (14). Na125I (100 mCi/ml) was purchased from ICN. IODO-GEN, 5,5'-dithiobis-(2-nitrobenzoic acid), and N-[4-(p-azidosalicylamido)butyl]-3'-(2'-pyridyldithio)propionamide (APDP) were from Pierce. Irradiation of samples was performed with a UV lightbox from Funakoshi (Funa-UV-linker FS-1500). ATP, creatine kinase, and creatine phosphate were obtained from Boehringer Mannheim. Proteinase K was purchased from Merck. Restriction enzymes were from Takara Shuzo Co. Sephadex G-50 (medium) and protein A-Sepharose CL-4B were purchased from Pharmacia Biotech Inc.

Construction of ProOmpA Derivatives

pTD-T7, an expression vector carrying the T7 promoter, was a generous gift from Dr. Date (24). 1.3-kilobase pair EcoRI-HindIII fragments encoding mutant ompA genes were isolated from the pOA series plasmids described by Uchida et al. (17) and then subcloned into the EcoRI-HindIII site of pTD-T7. The resultant plasmids are referred to as pTDL16-L43. The pTDL plasmids were transformed into E. coli CJ236, and uracil-containing single-stranded phagemid DNA was isolated. Oligonucleotide-directed mutagenesis was performed according to the method of Kunkel (25). The following oligonucleotide primers were used: proOmpAL16- 43Delta H1, 5'-GTCGGTGTAACCCGTACGCTCATCTTTACCGT-3' (splI); proOmpAL16-29Delta H2, 5'-GCCGGGATACCTTTGGACGTACGCTCATCTTTAACAGACTGAGCACGG-3' (splI); proOmpAL35Delta H2, 5'-GCCGGGATGCATTTGGACGTACGCTCATCTTTAACAGACTGAGCACGG-3' (splI); proOmpAL43Delta H2, 5'-GCCGGGATACCTTTGGACGTACGCTCATCTTTACATGTCTGAGCACGG-3' (splI); proOmpAL16-29Delta H1+2, 5'-GGGATACCTTTGGAGAGCTCTTTATCACGAACAGACTGAGCACGG-3' (SacI); proOmpAL35Delta H1+2, 5'-GGGATGCATTTGGAGAGCTCTTTATCACGAACAGACTGAGCACGG-3' (SacI); proOmpAL43Delta H1+2, 5'-GGGATACCTTTGGAGAGCTCTTTATCACGACATGTCTGAGCACGG-3' (SacI); proOmpAL16-43Delta H0, 5'-CAAGTTGCTCAGAACAACTACGAGCTGATCCAGAG-3' (<UNL><IT>Pvu</IT>II</UNL>); proOmpAL43C302Q, 5'-CGATCCGGAGCCAGCTGGTCGATCAGTG-3' (PvuII); proOmpA2xH1, 5'-AGCGTGGTCGTGTTGTGCCGAGTTGTTCTGGGTTAC-3' (BamHI) and 5'-CGATCCGGAGCCAGCTGGTCGATCAGTG-3' (PvuII); proOmpA2xH1C, 5'-GTAACCCAGAACAACTGCGCACAACACGACCAC-3' (FspI). The restriction sites created are shown in parentheses and the deleted site is underlined. Using these primers, the complementary DNA strand was synthesized and the resulting double-stranded DNA was transformed into JM109. To obtain double-stranded DNA for the Delta H1+2 series, uracil-containing single-stranded phagemid DNA was isolated from the Delta H1 series, and then the complementary strand was synthesized. These plasmids encoding various mutated ompA genes were subjected to in vitro transcription with T7 RNA polymerase, followed by in vitro translation as described (15).

In Vitro Translocation of Looped ProOmpA Derivatives

Translated 35S-labeled proOmpA derivatives were oxidized with ferricyanide and then subjected to in vitro translocation essentially according to the method of Uchida et al. (17). The translocation mixture (25 µl) comprised a 35S-labeled proOmpA derivative, membrane vesicles (5 µg of protein), 2 mM ATP (or 5 mM AMP-PNP), 5 mM MgSO4, 50 mM potassium phosphate (pH 7.5), 15 µg/ml SecB, and 40 µg/ml SecA. Dithiothreitol was added to the final concentration of 5 mM, if necessary. The ATP concentration was maintained by regeneration with 10 mM creatine phosphate and 10 µg/ml creatine kinase. After 10-min incubation at 37 °C, the mixture was treated with proteinase K (200 µg/ml) for 20 min at 0 °C, subjected to trichloroacetic acid precipitation, and then analyzed by SDS-polyacrylamide gel electrophoresis and fluorography. Translocation of looped proOmpAs with reconstituted proteoliposomes was performed according to the method of Akimaru et al. (14).

Conjugation of APDP

ProOmpAL43C302Q, in which a cysteine residue was introduced at Cys-260 was replaced with a glutamine residue, was also created. 35S-Labeled proOmpA was conjugated with APDP via Cys-260 according to the method of Joly and Wickner (26). Briefly, APDP was dissolved in dimethyl sulfoxide (3 mg in 50 µl) and then diluted 200-fold with 100 mM potassium phosphate (pH 7.5). To 70 µl of the 35S-labeled proOmpA dissolved in 6 M urea and 100 mM potassium phosphate (pH 7.5), 100 µl of diluted APDP was added. After 1 h at room temperature, proteins were precipitated with trichloroacetic acid, and then washed with acetone twice, then the washed precipitate was dissolved in 6 M urea and 50 mM potassium phosphate (pH 7.5).

Immunoprecipitation of Cross-linked Products

After in vitro translocation reaction and photolysis, samples were solubilized in a solution comprising 50 mM Tris-HCl (pH 8.0), 150 mM NaCl, and 1% SDS, diluted 33-fold with dilution buffer consisting of 50 mM Tris-HCl (pH 8.0), 150 mM NaCl, 100 µM 5,5'-dithiobis(2-nitrobenzoic acid), and 0.1% Triton X-100 and then mixed with an appropriate antibody, anti-SecY or anti-SecA. After incubation at 4 °C for 1.5 h, the antigen-antibody complexes were isolated with protein A-Sepharose CL-4B. The resin was washed with dilution buffer and then incubated in sample buffer for electrophoresis at 37 °C for 5 min to recover the bound proteins.

Membrane Insertion of 125I-Labeled SecA

Purified SecA was iodinated according to the method of Economou and Wickner (18) with a minor modification, as described below. Na125I and SecA were incubated on ice for 20 min in a tube that had been coated with IODO-GEN. The reaction mixture was transferred to another tube containing 2 mM dithiothreitol and then applied to a Sephadex G-50 column to remove Na125I. To prepare 125I-SecA-bound membrane vesicles, 4 nM 125I-SecA and 200 µg/ml urea-washed membrane vesicles were incubated for 15 min on ice in a 100-µl reaction buffer consisting of 50 mM Tris-HCl (pH 8.0), 50 mM KCl, 5 mM MgCl2 and 0.2 mg/ml bovine serum albumin. The membrane vesicles were isolated and then resuspended in the same buffer. 125I-SecA-bound membrane vesicles, 1 mM ATP, 50 µg/ml SecB, 5 mM phosphocreatine, creatine kinase (10 µg/ml), and 20 µg/ml looped proOmpA derivative were incubated in reaction buffer for 15 min at 37 °C, followed by proteinase K treatment (final, 0.1 mg/ml) for 15 min on ice. Proteins were precipitated with trichloroacetic acid and then analyzed by SDS-polyacrylamide gel electrophoresis and fluorography.


RESULTS

Construction of ProOmpA Derivatives Containing Disulfide-bridged Loops

We first looked at the hydropathy profile of the wild-type proOmpA (Fig. 1A). There are two major hydrophobic segments, referred to as H1 (residues 233-237) and H2 (residues 261-265), respectively, close to the N-terminal side of two cysteine residues (Cys-290 and Cys-302). Fig. 1B summarizes the positions of the cysteine residues used for the formation of a disulfide bridge with those of the two hydrophobic regions. We constructed, by the oligonucleotide-directed mutagenesis method, genes encoding derivatives of proOmpA in which either or both of the hydrophobic segments were replaced with artificial hydrophilic amino acid sequences (Fig. 1D). As judged from the hydropathy profile, the replacement was expected to render both hydrophobic segments completely hydrophilic (Fig. 1C).


Fig. 1.

A, hydropathy profile of proOmpA. Hydropathy was calculated according to Kyte and Doolittle with a span of seven residues. Hydrophobic stretches H1 and H2 are indicated by bold bars. B, structures of proOmpA derivatives. The amino acid residues of the signal peptide (-21 to -1) and the mature domain (+1 to +325) are indicated with the positions of cysteine residues. The amino acid residues replaced by a cysteine residue are shown in parentheses. The name of each proOmpA derivatives, loop size, and hydrophobic stretches H1 and H2 are also shown. WT, wild-type. C, amino acid sequences of the H1 and H2 regions. Each segment was replaced by an artificial amino acid sequence, which is shown with the amino acid residue positions. The hydropathy patterns of these mutated proOmpAs are also shown. D, structures of mutated proOmpA derivatives. The name of each proOmpA with removed hydrophobic segment(s) is indicated.


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The Effects of Hydrophobic Segments in the Mature Domain of ProOmpA

These proOmpA derivatives were then subjected to in vitro translocation into everted membrane vesicles of E. coli in the absence of the proton motive force (Fig. 2). As shown in Fig. 2A, the sizes of proteinase K-resistant fragments (band A) were essentially the same for proOmpAs containing loops of 16 and 21 amino acid residues (L16 and L21). When the size of the loop increased (L35), a sudden decrease in the size of the fragment, by about 3 kDa, occurred and several fragments were observed (collectively referred to as band B). The sizes of the fragments were the same for L35 and L43. L29 exhibited an intermediate profile between those of L21 and L35. These results were essentially the same as those of Uchida et al. (17). This stepwise profile was not due to the substrate specificity of proteinase K, because similar profiles were observed when other proteases with different substrate specificities were used (17).


Fig. 2. A-D, alignment of translocation intermediates obtained oined on proteinase K treatment in the process of translocation of the series of looped proOmpAs, with or without removed H1 and/or H2 portion(s). Various 35S-proOmpAs with a disulfide-bridged loop (L43-L16), in 8 M urea and 50 mM potassium phosphate (pH 7.5), were diluted in an assay mixture (25 µl) comprising 5 µg of everted membrane vesicles, 1 µg of SecA, 0.375 µg of SecB, 5 mM MgSO4, and 2 mM ATP in 50 mM potassium phosphate (pH 7.5). After 10-min incubation at 37 °C, the samples were treated with 5 µl of proteinase K (5 µg/µl) for 20 min on ice. The samples were then recovered by trichloroacetic acid precipitation, washed with acetone, and then subjected to SDS-PAGE and fluorography. The positions of the translocation intermediates of OmpAs are indicated by A and B. Models of the translocation intermediates are also shown. E, structure of proOmpA2xH1 and its in vitro translocation. 35S-ProOmpA derivatives were subjected to in vitro translocation as described above. The position of the mature OmpA is indicated.
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As shown in Fig. 2B, when the H1 segment was replaced with a hydrophilic sequence, the sizes of the protease K-resistant fragments were the same for all proOmpA derivatives (L16, L21, L29, L35, and L43). Similar results were obtained when trypsin was used instead of proteinase K (data not shown), suggesting that the observed profile was not due to the specificity of the protease. When the H2 segment was replaced with a hydrophilic one, no fragment was observed at the position of band A for L16 or L21. Instead, bands C* and C were observed for L16 and L21, respectively. It should be noted that a slight decrease in size occurred between L16 and L21 (Fig. 2C), suggesting that translocation occurred continuously. When both the H1 and H2 segments were replaced, the size of the proteinase K-resistant fragments continuously decreased as the loop size increased, except for L35 and L43 (Fig. 2D). Discontinuous translocation between L35 and L43 can be explained by the fact that appropriate proteinase K cleavage sites do not exist from around residues +260 to +252, where the translocation of L43 is predicted to cease at the position of its loop. These results suggest that the hydrophobic segments are involved in the stepwise movement. Similar profiles were observed when translocation was performed in the presence of the proton motive force (data not shown), suggesting that the mechanism of SecA-dependent translocation is principally the same in the absence and presence of the proton motive force, as we discussed previously (17). Furthermore, when the translocation reaction was conducted in the presence of everted membrane vesicles derived from a strain harboring the mutation in the prlA666, which was shown to be a particularly strong suppressor for a variety of maltose-binding protein export defects (27), the patterns of the translocation of looped proOmpA derivatives were the same as that obtained in the presence of the wild-type membranes (data not shown).

To confirm that the hydrophobicity is important for the stepwise movement, we inserted another H1 segment just before the original H1 segment to increase the hydrophobicity (proOmpA2xH1). As shown in Fig. 2E, the hydrophobic segment 2xH1 showed substantial stop-translocation activity. The size of proteinase K resistant fragment, 26 kDa, was the same as that of the proOmpA containing loops of 43 amino acid residues (L43), implying that the translocation of proOmpA2xH1 was interrupted at the H1 region. These results suggest that the hydrophobicity itself is important for the translocation stall.

If hydrophobic segments really determine the discontinuous transition of proOmpA through the membrane, it was expected that the relocation of hydrophobic segments would lead to a change in the stepwise translocation pattern. We therefore constructed a series of proOmpAs, in which hydrophobic segment H1 was shifted about 14 residues closer to the N terminus, and then subjected them to in vitro translocation (Fig. 3A). Proteinase K digestion of the translocated mutant proOmpAs with the relocated H1 region (proOmpAH0+2) revealed a change in the stepwise profile (Fig. 3B). In the case of wild-type proOmpA derivatives, a shift of band A to B occurred around a loop size of 29 (Fig. 2A), whereas proOmpA derivatives with the relocated H1 region showed a shift at a loop size of 35. This result strongly supports the idea that hydrophobic segments are directly involved in the discontinuous transition of a polypeptide across membrane vesicles.


Fig. 3. Structure of proOmpAH0+2 and alignment of its translocation intermediates obtained on proteinase K treatment. A, comparison of the primary structures of wild-type (WT) and proOmpAH0+2 (H0+2) with the amino acid positions. B, the conditions for limited translocation and digestion with proteinase K were the same as those given in the legend to Fig. 2. The positions of the translocation intermediates of the OmpAH0+2 series are indicated by A and B.
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H1 and H2 Segments of ProOmpA Are Responsible for the Formation of Translocation Intermediates

When the in vitro translocation reaction was performed with a low concentration of ATP (10 µM), translocation intermediates of proOmpA were observed (7, 9). We examined whether or not the proteinase K-resistant fragment that was formed on partial translocation of proOmpA with a disulfide-bridged loop was identical with translocation intermediates accumulated with a low concentration of ATP. A low concentration of ATP permitted a slow translocation reaction and thereby resulted in protease-resistant intermediates, termed I29 and I16 (Fig. 4, lane 1). Translocation intermediate I29 showed the same mobility as band B on SDS-polyacrylamide gel electrophoresis, indicating that the translocation was interrupted at the same site (Fig. 4, lanes 1 and 2). On the other hand, limited translocation of the proOmpA devoid of the H1 and H2 segments gave several bands, which gave a different pattern from I29 (Fig. 4, lane 3). These results suggest that hydrophobic segments in the mature domain of proOmpA are responsible for the accumulation of translocation intermediates with a low concentration of ATP.


Fig. 4. Intermediates of various proOmpA derivatives during translocation. The indicated 35S-proOmpA derivatives were preincubated in assay mixtures under the conditions given in the legend to Fig. 2, except for ATP, for 2.5 min at 37 °C. The samples were further incubated for 10 min with 10 µM ATP (lanes 1 and 3) or 2 mM ATP (lanes 2 and 4), followed by proteinase K treatment (final, 200 µg/ml) for 20 min at 0 °C, and then analyzed by SDS-PAGE and fluorography. Translocation intermediates I29 and I16 are indicated.
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Minimum Components Required for Stepwise Translocation

Reconstitution studies revealed that SecA, SecE, and SecY are the minimum components mediating preprotein translocation (13, 14). To determine whether or not these components are enough for the stepwise movement of proOmpA derivatives, an in vitro preprotein translocation reaction with reconstituted proteoliposomes comprising purified SecA, SecE, and SecY was carried out with a series of looped proOmpAs. As shown in Fig. 5, proOmpAs with disulfide-bridged loops exhibited a discontinuous mode of translocation, which was similar to that observed with everted membrane vesicles. This implies that the stepwise movement of proOmpA derivatives is achieved only through SecA, SecE, SecY, and phospholipids.


Fig. 5. Alignment of translocation intermediate bands obtained on proteinase K treatment with reconstituted proteoliposomes. Samples (15 µl) of reconstituted proteoliposomes were mixed with 1.5 µg of SecA and 5 µl of 10 mM potassium phosphate (pH 7.5), containing 10 mM MgSO4, 10 mM ATP, 150 mM NaCl, and an ATP-generating system composed of 50 mM creatine phosphate and creatine kinase (1.25 mg/ml). After 3-min preincubation at 37 °C, the reaction was started by the addition of 35S-proOmpA. The translocated portion, which became proteinase K-resistant, was detected by SDS-PAGE, followed by fluorography. The positions of the translocation intermediates of OmpAs are indicated by A and B. WT, wild-type proOmpA with no disulfide-bridged loop.
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Cross-linking with the H2 Region and Translocase

Using a photoactivable and reducible cross-linker, APDP, Joly and Wickner (26) showed that OmpA in a translocation intermediate is cross-linked to SecA and SecY, suggesting that translocation occurs through a proteinaceous channel. To determine whether or not the H2 segment interacts with SecA and SecY during translocation, we introduced a cysteine residue (Cys-260) in the H2 segment and replaced Cys-302 with a glutamine residue and then APDP was attached to the cysteine residue of the radiolabeled proOmpA. The translocation reaction was conducted with a low concentration of ATP (10 µM) to produce translocation intermediates (Fig. 6A, lane 2). After membrane vesicles had been isolated by centrifugation to remove free 35S-proOmpAL43C302Q, they were irradiated with UV light. This photolysis allowed a reactive group attached to Cys-260 to form a covalent bond with its nearest neighbor. To determine whether or not SecA and SecY are cross-linked, immunoprecipitation was performed as described before (28) and then the precipitates were analyzed by SDS-polyacrylamide gel electrophoresis in the presence of dithiothreitol. Treatment of the precipitates with dithiothreitol resulted in the release of 35S-proOmpAL43C302Q from the attached nearest neighbor. Most of the cross-linked 35S-proOmpAL43C302Q was specifically precipitated by antisera directed against SecY (lane 4), whereas a part of the cross-linked 35S-proOmpAL43C302Q was precipitated by antisera raised against SecA (lane 5). When ATP was absent, no significant amount of 35S-proOmpAL43C302Q was immunoprecipitated by either anti-SecY (lane 7) or anti-SecA (lane 8), indicating that cross-linking with SecY and SecA occurred only when partial translocation had taken place. After the photolysis, when excess purified antigen (purified SecA and SecY) was added to the reaction mixture, the amount of precipitated 35S-proOmpAL43C302Q was drastically reduced (Fig. 6B). Since SecA repeats the insertion-deinsertion cycle during translocation, cross-linking of 35S-proOmpAL43C302Q with SecA might occur during its insertion into the membrane. These results suggest that the H2 segment interacts mainly with SecY, and partly with membrane-embedded SecA, when translocation is arrested. This is in good agreement with the idea of Joly and Wickner (26) that the interaction of the translocating chain with translocase occurs initially through SecA followed by SecY.


Fig. 6. A, limited translocation and nearest neighbor analysis. Translocation intermediates were prepared under the conditions given in the legend to Fig. 4 with APDP-conjugated proOmpAL43C302Q prepared as described under "Experimental Procedures." APDP-proOmpAL43C302Q in urea was diluted in the reaction mixture (25 µl) described in the legend to Fig. 2, without ATP, followed by incubation at 37 °C for 2.5 min. After the 10-min incubation with 10 µM ATP (lanes 2, 4, and 6) or with 5 mM AMP-PNP (lanes 3 and 5) at 37 °C, membrane vesicles were isolated by centrifugation and then resuspended in buffer comprising 50 mM potassium phosphate (pH 7.5) and 5 mM MgSO4. The samples were treated with proteinase K (ProK) (200 µg/ml), shown in lane 2. The samples were irradiated with an inverted lightbox at 256 nm for 6 min at room temperature. The irradiated samples were then dissolved in buffer comprising 50 mM potassium phosphate (pH 7.5), 5 mM MgSO4, and 1% SDS (total 25 µl), vortexed for 5 min, and then diluted with buffer consisting of 50 mM Tris-Cl (pH 8.0), 150 mM NaCl, and 0.1% Triton X-100 to 33-fold. The diluted samples were then subjected to immunoprecipitation as described under "Experimental Procedures" and then analyzed by SDS-PAGE with a reducing agent. Lane 1 contains 10% of the samples used in lanes 2-6. B, immunocompetition analysis. Experiments were performed as described above in the presence of purified SecA and SecY (lane 2, 50 µg each; lane 3, 5 µg each) and then precipitated with both anti-SecA and anti-SecY antibody. Lane 4 contains 10% of the samples used in lanes 1-3.
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SecA Membrane Insertion Is Not Affected by Hydrophobic Segments of ProOmpA

We next examined whether or not the presence of hydrophobic segments in the mature domain of proOmpA affect the insertion of SecA into the membrane. 125I-SecA was incubated with ATP and proOmpA containing a disulfide-bridged loop to form membrane-inserted SecA. Proteolysis of the membrane-inserted SecA gave a 30-kDa fragment, as observed for the membrane-inserted SecA, which had been formed with wild-type proOmpA (Fig. 7). Removal of the H1 and H2 segments from the looped proOmpA did not alter the efficiency of membrane insertion of 125I-SecA, suggesting that the hydrophobic segments play no role in the insertion of SecA into the membrane.


Fig. 7. SecA membrane insertion of looped proOmpA derivatives. The reaction mixtures comprised TL buffer without dithiothreitol (50 mM Tris-Cl (pH 8.0), 50 mM KCl, 5 mM MgCl2, and 0.2 mg/ml bovine serum albumin), 125I-SecA-bound membrane vesicles (200 µg/ml), 5 mM phosphocreatine and creatine kinase (10 µg/ml), as described under "Experimental Procedures." For the reactions in lanes 2-4 mutant proOmpA (20 µg/ml), ATP (1 mM), or both were added as indicated. The samples were incubated at 37 °C for 15 min and then digested with proteinase K (0.1 mg/ml) for 15 min on ice. After trichloroacetic acid precipitation, the samples were analyzed by SDS-PAGE and fluorography. The arrowheads indicate the protease-inaccessible 30-kDa bands.
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DISCUSSION

The results of our previous study involving proOmpAs with disulfide-bridged loops of different sizes at different positions suggested that the in vitro translocation of proOmpA through the secretory machinery takes place in every 30 amino acid residues (17). How can such exact synchronization of the stepwise movement be achieved from the N terminus to the C terminus of proOmpA? Although the secretory machinery including SecA, which repeats the insertion-deinsertion cycle during translocation (18, 29), may be responsible for the stepwise movement of preproteins, preproteins themselves may also have elements that control such movement. In the present work, we carried out systematic analysis of the stepwise movement of proOmpAs with different distributions of hydrophobic segments in the mature domain of proOmpA. Our results strongly indicate that hydrophobic segments are determinants for the stepwise movement of proOmpA. We also demonstrated that the formation of translocation intermediates with a low concentration of ATP (7, 9) is due to the hydrophobic segments in the mature domain of preproteins. Hydrophobic portions in the mature domain may transiently be arrested in the Sec machinery in the process of translocation.

The observation that proOmpA translocation takes place in about every 30 amino acid residue segments (17) can be explained by the fact that the distance between the H1 and H2 segments is about 30 residues. We assume that the loop and hydrophobic segments cooperatively act to arrest the transit of a polypeptide chain across the membrane. When the loop size is small, as in the cases of L16 and L21, the H1 segment passes through the membrane, and the H2 segment acts as an arrest signal (Fig. 1A). The H2 segment may be a stronger arrest signal than the H1 segment because the arrest of proOmpA transit occurred at the H2 segment, but not at the H1 segment, when the concentration of ATP was low (Fig. 4). When the loop size is larger, the H1 segment arrests the transit of a polypeptide, probably due to steric hindrance or another reason. It should be noted that the distance between the two hydrophobic segments is about 30 amino acid residues. This coincides with the difference in size between bands A and B. When the H1 segment is replaced with a hydrophilic sequence, the H2 segment arrests the transit irrespective of the loop size. When the H2 segment is replaced, translocation continuously occurs after the H1 segment has passed through the membrane (Fig. 2C). It was expected that the replacement of both segments results in continuous translocation. However, as shown in Fig. 2D, L35 and L43 did not exhibit continuous translocation. The reason for this is not clear at present. When the H1 segment is shifted toward the N terminus by 14 amino acid residues, the H2 segment is the dominant arrest signal even if the loop size is as large as 35 amino acid residues (L35). In L35, the H0 segment may pass through the membrane before the loop approaches the membrane, therefore the H2 segment acts as an arrest signal. On the other hand, in wild-type L35, the H1 segment may not have passed through when the loop approaches the membrane.

Hydrophobic segments, which cause the stepwise translocation, consist of four hydrophobic amino acid residues. Such sequences seem to be appropriate for transfer through the membrane, i.e. the hydrophobicities of such hydrophobic segments are below the threshold of the hydrophobicity required for the stop of transfer. It is possible that proOmpA translocation pauses not only at H1 and H2, but also at other short hydrophobic segments in the mature domain.

Similar discontinuous translocation may occur in other outer membrane proteins. Outer membrane proteins generally form cross-beta -structures (30, 31), and their most hydrophobic regions are significantly less hydrophobic than the membrane-spanning sequences of inner membrane proteins (19). The lack of long hydrophobic regions in outer membrane proteins is quite reasonable, because such regions hinder the transfer of preproteins through the Sec machinery. On the other hand, inner membrane proteins that span the bilayer one time have hydrophobic regions of 20-25 amino acid residues. The lengths of these regions in the alpha -helical conformation are long enough to span the membrane (32).

A polypeptide crosses the membrane through a tunnel or pore comprising SecY, SecE, and SecG (26). On the other hand, the peripheral cytoplasmic factor, SecA, plays roles in both initiation and the elongation step of the entire process of the polypeptide transit (7, 9). In the process of translocation, a SecA arm accompanies the polypeptide chain into the membrane-embedded translocase, so that a portion of SecA is transiently located in the membrane, as revealed by the occurrence of a 30-kDa SecA fragment that is resistant to proteolytic cleavage (18). We showed here that the hydrophobic segments in the mature domain of proOmpA derivatives had no effect on the formation of the 30-kDa proteolytic fragment of SecA. This may suggest that SecA does not participate in the specific recognition of hydrophobic segments and that other proteins such as SecY may play this role. Further study is required to clarify this possibility.

In conclusion, our present observations clearly showed that short segments comprising four hydrophobic amino acid residues are determinants for the stepwise translocation. Since such segments are ubiquitous in secretory proteins (19), stepwise movement may be common for protein translocation across the E. coli cytoplasmic membrane.


FOOTNOTES

*   This work was supported by grants from the Ministry of Education, Science, Sports and Culture of Japan and by a Japan Society for the Promotion of Science for Young Scientists (to K. S.). The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§   Supported by a Research Fellowships of the Japanese Society for the Promotion of Science for Young Scientists. To whom correspondence should be addressed. Tel.: 81-426-76-7116; Fax: 81-426-76-8866.
1    The abbreviations used are: ATPgamma S, adenosine 5'-O-(thiotriphosphate); AMP-PNP, adenosine 5'-(beta ,gamma -imino)triphosphate; APDP, N-[4-(p-azidosalicylamido)butyl]-3'-(2'-pyridyldithio)propionamide; PAGE, polyacrylamide gel electrophoresis.

Acknowledgments

We thank Dr. Philip J. Bassford, Jr. of the University of North Carolina for the donation of strain JP136 and Mie Okazaki for her skillful technical assistance.


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