(Received for publication, January 23, 1997)
From the Department of Molecular Biology and Biochemistry, Wesleyan University, Middletown, Connecticut 06459
SecA ATPase promotes Escherichia coli protein translocation by its association with the preprotein or preprotein-SecB complex, anionic phospholipids, and the other core component of translocase, integral membrane protein SecYEG. Using ligand affinity blotting we demonstrate a direct interaction of SecA with SecY protein. Proteolysis and gene truncation or fusion studies were used to further define this interaction. Our results demonstrate that the carboxyl-terminal third of SecA protein binds to the amino-terminal 107 amino acid residues of SecY protein. The direct demonstration of these interactions culminate studies that have inferred an interaction between SecA and SecYEG, and they are consistent with studies suggesting that this region of SecA interacts with the inner membrane.
Recent progress in defining the components of the bacterial protein secretion apparatus and studying their mechanism of action in an in vitro system has opened the way to a detailed analysis of this fundamental process (for reviews see Refs. 1 and 2). Such studies demonstrate that SecA plays a central role in protein export by binding to many of the components of the translocation complex. Interaction of SecA with the signal peptide and the mature portion of the preprotein, the SecB chaperone, anionic phospholipids, and integral membrane protein SecYEG has been inferred using a variety of approaches (3-8). Membrane-bound SecA inserts into and spans the inner membrane (9), an activity originally defined in lipid monolayers and bilayers composed of anionic phospholipids (10, 11). Once SecA nucleates formation of a translocation complex at the membrane periphery it appears to act as a molecular ratchet by undergoing ATP-driven cycles of membrane insertion and de-insertion, which have been proposed to promote processive translocation of bound preproteins (12-15). In addition, translocation of distal segments of preprotein can occur without bound SecA by using the proton motive force (12).
While evidence for this basic model of protein translocation has been accruing, individual steps in the overall reaction need further clarification. For example, the basis of preprotein recognition by SecA and SecB is still largely unknown as is the nature of SecA interaction with SecYEG. Although previous cross-linking of a translocating preprotein to export machinery components suggests that SecA and SecY may constitute a preprotein channel (16), consistent with previous electrophysiological studies (17), the nature of this channel and the functions of SecA and SecYEG proteins in channel activity remain ill defined. Furthermore, SecD and SecF proteins are essential for efficient protein secretion in vivo (18), but their role(s) in vitro has not been clearly defined yet, although certain activities have been proposed (9, 14, 19).
In this study we have investigated the nature of SecA interaction with its membrane receptor SecYEG. Previous studies suggested that SecA interacts with the SecY subunit based on (i) the ability of high concentrations of SecA to suppress the protein translocation defect found normally for heat-inactivated IMV1 derived from the secY24(Ts) mutant (20), (ii) the requirement of SecA-dependent translocation ATPase activity for functional SecY protein (3), (iii) the ability of SecY antibody to reduce SecA affinity for IMV by 3-fold (6), and (iv) the ability of SecA when added to IMV to afford a 2-fold protection of SecY to proteolysis (6). While compelling, none of these studies provide direct proof of SecA-SecY interaction nor do they provide any information about the potential regions of interaction of these two proteins. Further complicating this picture are recent proposals that (i) SecG facilitates the cycle of membrane insertion and de-insertion of SecA protein by itself undergoing a cycle of inversion of its membrane topology (21), and (ii) SecD and SecF proteins are required to stabilize the membrane-inserted state of SecA protein (14). To begin to clarify the different protein-protein interactions that facilitate the biochemical function of the bacterial translocon, and specifically those proteins that interact directly with SecA protein, we have used ligand affinity blotting. This method is particularly appropriate for defining interactions with integral membrane proteins where it is difficult to study the biochemical function of the protein out of the context of the membrane environment. Our results show that SecA interacts directly with SecY protein by this method, and they define specific regions of these proteins that are required for such association.
BL26 ((argF-lac)U169) is a
derivative of BL21(
DE3) used for protein overproduction utilizing
the T7 promoter system (22). BL21.19 (secA13 (Am)
supF (Ts) trp (Am)
zch::Tn10 recA::CAT clpA::KAN) (23) containing the SecA overproducing plasmid pT7secA2 (24) has been
described previously. BL21.19 containing pT7secA95 (25) or pT7SecA75,
which contains an ochre codon at amino acid residue 665 of SecA, was
used for production of SecA95 or SecA75, respectively. pT7SecA75 was
constructed from pT7SecA2 by oligonucleotide-directed mutagenesis
employing 5
-CCAACAGTTAGTTACGCTG-3
as described previously (23).
W3110 M25 (pMan510, pMan809), an ompT strain containing plasmids for overproduction of SecE and SecY using the tac
promoter, has been described previously (26). Strains BW313
(relA1 ung1 dut1 spoT1 thi1) and XL1-Blue (endA1
hsdR17 supE44 thi1 recA1 gyr96 relA1
lac (F
proAB+ lacI9
lacZM15
Tn10) were used for preparation of single-stranded plasmid
DNA for mutagenesis and subsequent transformation, respectively, as
described previously (23). TB1, araD
(lac-proAB) rspL
lacZ M15 hsdR (New England Biolabs), was used as a
host for the plasmids overproducing MBP-SecA chimeras.
Plasmid-bearing strains were grown in LB medium (27)
with 100 µg ml1 ampicillin and/or 30 µg
ml
1 kanamycin where appropriate. For SecA overproduction,
the culture was grown at 30 °C to A600 of 0.5 and shifted in a water bath to 42 °C (for SecA variants only) when 1 mM IPTG was added, and the culture was grown for an
additional 2 h. SecA was purified using blue dextran-agarose
(Sigma) as described previously (23). SecA protein was biotinylated
using ImmunoPureR photoactivatable biotin (Pierce) as
described by the manufacturer. For SecYE overproduction the culture was
grown at 37 °C to A600 of 0.6-0.7 and
followed by induction with 1 mM IPTG for 2 h. Cells were harvested by sedimentation at 5000 × g, washed in
10 mM Tris, pH 7.5, 50 mM KCl, 10 mM magnesium acetate, 1 mM dithiothreitol (buffer TKMD), and then resuspended in 1 ml of buffer TKMD per g of
cell paste containing 10 µg ml
1 DNase I (Sigma). Cells
were disrupted in a French pressure cell at 10,000 p.s.i., and unbroken
cells were removed by sedimentation at 8000 × g for 20 min. The extract was sedimented at 300,000 × g for
3 h at 4 °C to yield a supernatant (S300) and membrane pellet
(P300). Membranes were resuspended in 50 mM Tris acetate, pH 7.5, 50 mM EDTA, 1 mM dithiothreitol,
underwent Dounce homogenization, and were re-sedimented at 300,000 × g for 3 h at 4 °C. Membranes were resuspended in
50 mM Tris acetate, pH 7.5, 1 mM
dithiothreitol, 10% glycerol, 8.5% sucrose, aliquoted, frozen in a
dry ice/ethanol bath, and stored at
70 °C until further use. To
prepare detergent-solubilized membranes, membranes were solubilized in
1.25% (w/v) n-octyl-
-D-glycopyranoside (Sigma), 2 mg ml
1 Escherichia coli
phospholipid (Avanti Polar Lipids), 50 mM Tris-HCl, pH 7.5, 150 mM NaCl, and 10% (w/v) glycerol at 0 °C for 30 min, and the supernatant was used after sedimentation at 300,000 × g for 3 h.
Detergent-solubilized membranes were
separated on 15% SDS-PAGE gels using the discontinuous system of
Laemmli (28). Proteins were transferred to nitrocellulose (Schleicher & Schuell) as described previously (29). Filters were blocked in 5%
dried milk in TBS (20 mM Tris-HCl, pH 7.5, 140 mM NaCl, 0.25% Tween 20) at 4 °C for at least 2 h.
Filters were washed with 10 mM sodium phosphate buffer, pH
7.5, 10 mM NaCl, 10 mM magnesium acetate, pH
7.5, 1 mM dithiothreitol. The filters were incubated with
10 mM phosphate buffer, 10 mM NaCl, 15 mM magnesium acetate, 5 µg ml1 SecA or its
derivatives at 4 °C for 2-4 h. Filters were washed with TBS and
incubated with affinity-purified anti-SecA antibody at a 1:10,000
dilution in TBS at 4 °C for 1 h. Filters were washed with TBS
and incubated with horseradish peroxidase-conjugated anti-rabbit
secondary antibody at a 1:10,000 dilution at 4 °C for 1 h.
Filters were washed with TBS, and detection of bound antibody was done
using ECL (Amersham Corp.) as described by the manufacturer.
Biotinylated SecA or biotinylated molecular weight markers (Bio-Rad)
were detected using a streptavidin-horseradish peroxidase conjugate
(Amersham Corp.) at a 1:10,000 dilution in place of the primary and
secondary antibody. Rabbit antisera prepared against keyhole limpet
hemocyanin-conjugated peptides to the amino terminus of SecY,
MAKQPGLDFQSAKGGLGELKRRC, the carboxyl terminus of SecY,
CYESALKKANLKGYGR, or amino acid residues 64-81 of SecE, KGKATVAFAREARTEVRKC, were prepared by Tana Laboratories, LC (Houston, TX). Affinity-purified anti-SecA antibody was prepared as described previously (30) except cyanogen bromide-activated Sepharose 6MB was
used for SecA protein coupling. Unless otherwise specified Western
blotting employed antibodies or antisera at a 1:10,000 dilution,
incubations were at room temperature, and visualization of bound
antibody utilized ECL as described by the manufacturer.
The following primers were used to
amplify the region encoding the first 107 amino acid residues of SecY
using polymerase chain reaction and pMan510 as template: 5-GGG AAT TCC
ATA TGG CTA AAC AAC CGG GAT-3
, 5
-CGC GGA TCC GCG TTT CTT AAT TTC TGC CAA-3
, allowing introduction of a NdeI site at the
initiation codon and a BamHI site at the 3
end of the
corresponding secY fragment. This fragment was gel-purified,
digested with NdeI and BamHI, and mixed with a
BamHI fragment of lacZ from pMC1871 (31), and the
two fragments were introduced into the translation vector pET11c (New
England Biolabs) at the corresponding sites. The correct plasmid,
pT7secY107-lacZ, was picked as a blue colony on LB plates containing
100 µg ml
1 ampicillin and 40 µg ml
1
5-bromo-4-chloro-3-indolyl-
-D-galactopyranoside using
BL26 as the host strain, and it was verified by DNA sequence analysis. For preparation of membranes from BL21.19 (pT7secY107-lacZ), the strain
was grown in LB containing 100 µg ml
1 ampicillin at
25 °C until an A600 of 0.6 when IPTG was
added to 0.5 mM for 1 h, cells were harvested, and
membranes were prepared identically as described above.
Plasmids producing the MBP-SecA chimeras were constructed using the protein fusion and purification system (New England Biolabs) as described by the manufacturer. The following oligonucleotides were used in polymerase chain reactions to amplify portions of secA utilizing pT7SecA2 as template (restriction sites introduced in this process and the relevant portions of SecA amplified are shown in parentheses).
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Polymerase chain reaction products were purified on agarose gels, digested with the appropriate restriction enzymes, and cloned into compatible restriction enzyme sites in pMAL-c2 using the manufacturer's protocol. malE-secA fusions were verified by sequence analysis, and the MBP-SecA chimeras were overproduced from TB1 containing the appropriate plasmid and purified according to the manufacturer's instructions.
To define the interaction
of SecA with SecYEG we developed a ligand affinity blotting assay.
Membranes were prepared from a strain, W3110 M25 (pMan510, pMan809), in
which SecYE was conditionally overproduced by induction with IPTG
(SecYE++ membranes) (26). While this strain overproduces
SecY protein by approximately 40-fold and SecE by 300-fold, SecY still
remains a minor component of total membrane protein (Ref. 26 and
results not shown). SecYE++ membranes were solubilized in
detergent, separated by SDS-PAGE, transferred to nitrocellulose, and
probed with purified SecA protein. Bound SecA protein was detected
using affinity-purified rabbit anti-SecA antibody, horseradish
peroxidase-conjugated anti-rabbit antibody, and a chemiluminescent
substrate of horseradish peroxidase followed by autoradiography. The
results are shown in Fig. 1. SecA bound to a protein
with an apparent molecular mass of 35 kDa (Fig. 1C), which
was SecY protein based on the following criteria: (i) it reacted with
anti-peptide antiserum directed against either the carboxyl or amino
terminus of SecY (Fig. 1, A and B, respectively; the latter antiserum also detected a species at approximately 55 kDa
that may be a dimer of SecY as well as amino-terminal proteolytic fragments of SecY which are commonly produced during membrane solubilization (32, 33)); (ii) it was overproduced in an
IPTG-dependent fashion (compare lanes 1 and 2 of the different panels); and (iii) it was not present
when SecYE++ membranes were boiled in the presence of SDS
(lane 3), conditions that induce irreversible aggregation of
SecY (34). SecY binding was not detected when SecA protein was omitted
during a mock ligand blot, but instead only SecA protein (102 kDa) and
a presumed proteolytic fragment of SecA of 48 kDa were detected by the
anti-SecA antibody and secondary antibody employed during development
of the ligand blot (panel E). As noted previously the level
of membrane-bound SecA protein increased during SecYE overproduction
(35). It was noted that detection of the endogenous SecA protein during ligand blotting was somewhat variable depending on the level of exposure of the blot (Figs. 1, 2, 3).
To provide additional proof that we were specifically detecting SecA interaction with SecY protein using this assay we altered our detection method. In this case we used biotinylated SecA as the probe and streptavidin-conjugated horseradish peroxidase and a chemiluminescent substrate of horseradish peroxidase for detection. SecY protein was detected similarly by this method also (Fig. 1D). Neither method appeared to detect SecA interaction with SecE or SecG protein, even when 15% SDS-PAGE gels were used to resolve these smaller proteins, although these proteins could be readily detected by conventional Western blotting (results not shown). Whether this negative result is significant regarding the affinity of SecA protein for SecE or SecG must await further investigation. Finally, to optimize somewhat the ligand-blotting procedure, we determined its dependence on salt and Mg2+ concentration. SecA binding activity was strongest at either low or high salt concentrations (10 mM or 1 M NaCl) with approximately 40-fold weaker binding occurring at moderate salt concentrations (50-250 mM NaCl) (results not shown). Binding was also dependent on Mg2+ ions, but it was reduced above 15 mM MgCl2 (results not shown).
Location of the SecA-binding Site on SecYTo locate the
SecA-binding site on SecY we made use of the natural pattern of
proteolysis of SecY protein that occurs during detergent solubilization
of SecYE++ membranes (32, 33). Comparison of Western and
ligand blots of these membrane samples showed that the pattern of
proteolytic fragments of SecY detected was essentially identical when
anti-peptide antibody to the amino terminus of SecY was used for
Western blotting (Fig. 2, compare lanes 1 and 2 in panels A and B).
Furthermore, an ~27-kDa carboxyl-terminal fragment of SecY generated
by trypsinolysis of these samples was not detected by ligand
blotting (results not shown). These results suggested that the
SecA-binding determinant resided in the early amino-terminal portion of
SecY protein. To verify this presumption, we created a chimera in which
the amino-terminal 107 amino acid residues of SecY were fused to LacZ
(SecY107-LacZ), and we determined whether it contained SecA binding
activity by ligand blotting. According to the predictions of Akiyama
and Ito (36) this chimera should contain the first two transmembrane segments of SecY, TM1 and TM2, along with the first cytoplasmic and
periplasmic domains, C1 and P1, respectively, fused to
cytosolically-disposed -galactosidase. The overproduced 128-kDa
chimera could be detected readily by Western blotting employing either
anti-peptide antibody to the amino terminus of SecY or
anti-
-galactosidase antisera (Fig. 2A, lane 3,
and results not shown; note that wild-type levels of SecY protein in
these samples are at or below our standard level of detection here). In
addition, like SecY protein the chimera aggregated when membranes were
solubilized by boiling in SDS (Fig. 2A, compare lanes
3 and 4). A ligand blot of the SecY107-LacZ chimera
showed that it possessed strong SecA binding activity (Fig. 2,
compare lanes 3 and 4 of panels A and
B). These results indicate that there is a SecA-binding
determinant located in the extreme amino-terminal portion of SecY
protein. Our results are entirely consistent with previous reports that
an anti-peptide antibody directed against the amino terminus of SecY
interfered with SecA binding to IMV as well as
SecA-dependent preprotein binding to IMV, and it blocked
also translocation ATPase activity (3, 6, 37).
To locate the SecY-binding site on SecA we utilized two truncated SecA proteins, SecA95 and SecA75, that could be readily purified in soluble form and characterized. SecA95 lacks the carboxyl-terminal 66 amino acid residues of SecA, and it shows reduced protein translocation activity but it can still complement conditional lethal secA mutants when overproduced severalfold (25). SecA75 contains the amino-terminal 665 amino acid residues of SecA protein including both ATP-binding domains (23). It is inactive in catalyzing both in vivo and in vitro protein translocation, but it displays an elevated endogenous ATPase activity, a reduced membrane-stimulated ATPase activity, and no translocation ATPase activity.2 The truncated SecA proteins were purified (Fig. 3A, lanes 2 and 3) and used for ligand blotting as shown in Fig. 3B. SecA95 displayed reduced SecY binding activity compared with wild-type SecA, while the activity of SecA75 was essentially undetectable (compare lanes 2-4). The faint SecA band in each ligand blot indicated that similar sensitivities were being detected by this procedure in each case. This result suggests that the carboxyl-terminal third of SecA protein is important for SecY recognition. In an attempt to confirm and extend these results we constructed a series of six chimeras in which portions of SecA were fused to the carboxyl terminus of MBP. These chimeras were designated MBP-SecA1 through MBP-SecA6, and they contained the following portions of SecA: amino acid residues 1-209, 211-350, 351-509, 519-664, 665-820, and 822-901, respectively. The chimeras were purified (Fig. 1A, lanes 4-9) and used for ligand blotting as shown in Fig. 3C. MBP-SecA5 showed strong SecY binding activity similar to wild-type SecA, while the other MBP-SecA chimeras showed little or no SecY binding activity (lane 5 versus lanes 1-4 and lane 6). MBP alone displayed no SecY-binding activity in this assay (results not shown). These results support our finding that the carboxyl-terminal third of SecA protein is important for SecY recognition. They further suggest that a region between amino acid residues 665 and 835 of SecA contains an important SecY-binding determinant, although conformational effects due to truncation of these proteins cannot be ruled out as a cause for certain of the negative results obtained here. Our result is consistent with recent studies that show that the carboxyl-terminal third of SecA protein inserts into the membrane during protein translocation and is protected against proteolysis (13, 38), as well as our recent finding that a region somewhere between amino acid residues 665 and 858 of integral membrane SecA traverses the membrane.2
As more of the details regarding the mechanism of protein translocation are revealed, there will be an increasing need to define subreactions promoted by individual protein-protein interactions among the different components of the secretion machinery. Genetic tools such as suppressor analysis or synthetic lethality (39) and biochemical tools such as cross-linking (16) or ligand affinity blotting can provide valuable information in this context. Ligand affinity blotting has been used extensively in the past to characterize membrane receptors for diverse ligands such as hormones, interleukins, or lipoproteins (e.g. see Refs. 40-42). Previous studies suggested that SecA interacts with the SecY subunit of SecYEG, but these studies were indirect in nature or were limited by interpretation since the large antibody molecules used could directly affect neighboring interactions (3, 6, 20). Our studies using ligand blotting provide a straightforward approach to this problem, and they have allowed assignment of SecA-binding activity to SecY protein. In particular, the amino-terminal 107 amino acid residues of SecY protein were shown to interact with the carboxyl-terminal third of SecA protein. One major limitation of this approach, however, is that detergent solubilization of membranes prevents us from knowing whether this interaction takes place normally within the interior of the membrane or at its periphery, or both, nor have we gained insight into the physiological function of this interaction. Additional fine structure mapping of the binding determinants on SecA and SecY proteins along with appropriate mutant analysis and comparison to the known or emerging topology of these proteins in the membrane should allow clarification of these issues.
Of the ten transmembrane segments (TM1-TM10), six cytoplasmic domains (C1-C6, including both termini), and five periplasmic domains (P1-P5) contained in the proposed topology of SecY (36), specific functions have been suggested for several regions of SecY. These include a potential region of "catalytic function" (C5, TM9, and C6) (43, 44), a region that recognizes signal sequences and performs a signal sequence proofreading function (TM7) (45), and regions that interact with SecE protein (C4, TM10, and P1) (39, 46). Previous studies have proposed at least four functional regions of SecA protein: (i and ii) high and low affinity ATP-binding domains at amino acid residues 100-230 and 500-665, respectively (23, 26); (iii) a preprotein-binding site at amino acid residues 267-340 (7); and (iv) lipid- and SecB-binding site(s) residing in the carboxyl-terminal 70 amino acid residues of SecA (8). Recently, it has been shown that the carboxyl-terminal third of SecA protein is at least one of the portions that is integrated into the membrane during protein translocation, whereby its carboxyl terminus is periplasmically exposed (35, 38). These findings are consistent with our recent studies of the topology of integral membrane SecA protein in right side out membrane vesicles that show that SecA traverses the membrane somewhere between amino acid residues 665 and 858.2 Remarkably this region corresponds to the SecY-binding site that has been mapped in this study. Therefore, it appears quite possible that the SecY-binding determinant in SecA may interact with portions of SecY that are within the interior of the membrane. Additional studies will be required to explore this point further and to define the function(s) of the integral membrane portions of SecA protein. By doing so the parallel between our work and SecA-SecY interaction within native inner membranes should be established.
We thank Dr. H. Tokuda for provision of the anti-SecG antisera.