©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Insertion of the Polytopic Membrane Protein MalF Is Dependent on the Bacterial Secretion Machinery (*)

(Received for publication, May 5, 1995; and in revised form, January 29, 1996)

Beth Traxler (1)(§) Chris Murphy (2)(¶)

From the  (1)Department of Microbiology, University of Washington, Seattle, Washington 98195 and the (2)Department of Microbiology and Molecular Genetics, Harvard Medical School, Boston, Massachusetts 02115

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

We examined the dependence of protein export and membrane protein insertion on SecE and SecA, two components of the secretion (Sec) apparatus of Escherichia coli. The magnitude of the secretion defect observed for signal sequence-containing proteins in cells depleted of SecE is larger and more general than that in many temperature- or cold-sensitive Sec mutants. In addition, we show that the proper insertion of the polytopic MalF protein (synthesized without a signal sequence) into the cytoplasmic membrane is also SecE-dependent. In contrast to an earlier study (McGovern, K., and Beckwith, J.(1991) J. Biol. Chem. 266, 20870-20876), the membrane insertion of MalF also is inhibited by treatment of cells with sodium azide, a potent inhibitor of SecA. Therefore, our data strongly suggest that the cytoplasmic membrane insertion of MalF is dependent on the same cellular machinery as is involved in the export of signal sequence-containing proteins. We propose that the mechanism of export from the cytoplasm is related for both signal sequence-containing and cytoplasmic membrane proteins, but hydrophobic membrane proteins such as MalF may have a higher affinity for the Sec apparatus.


INTRODUCTION

Translocation of proteins across the cytoplasmic membrane in Escherichia coli(2, 3) is catalyzed by a machinery whose components have been identified both genetically and biochemically. These components include the SecA, SecE, and SecY proteins, which are essential for protein export, and at least four other proteins (SecB, SecD, SecF, and SecG) that greatly enhance protein translocation, especially at lower temperatures. Proteins localized by the Sec (^1)apparatus to the periplasm or outer membrane are synthesized with an N-terminal signal sequence that is proteolytically cleaved from the mature portion of the protein during export by the action of leader peptidase.

In vivo studies of the dependence of a particular protein on the Sec machinery for proper cellular localization have relied largely on the use of conditional Sec missense mutants. These mutant strains accumulate untranslocated, signal sequence-bearing proteins in their cytoplasm under nonpermissive conditions. The extent of a secretion defect in cells can thus be directly assessed by examining the amount of precursor species versus mature species of a given secreted protein. The analysis of the Sec dependence of protein export is made complicated by the fact that different proteins are not equally sensitive to the export inhibition conferred by conditional sec mutations. For example, in a strain deleted for the secDF genes, ribose-binding protein and maltose-binding protein (MBP) are exported relatively poorly(4) . In these same strains, OmpA is exported fairly well (the majority of protein synthesized in a short pulse is exported by 10 min), and DegP is exported with wild type kinetics. It is possible that OmpA and DegP have a greater affinity for the secretion apparatus than do ribose-binding protein or MBP.

The assessment of whether a protein is dependent upon the secretion apparatus for translocation is further confounded by the nature of the sec conditional mutations. These mutations, rather than causing the synthesis of a conditionally defective Sec protein, often result in lower levels of functional Sec protein and, in effect, reduce the quantity of functional secretion apparatus in the cell. This phenomenon has been thoroughly characterized for the secE cold-sensitive mutations(5) . The translocation of proteins that have a higher affinity for this limited secretion apparatus would be less affected relative to those proteins that have a lower affinity. Recently, a more accurate assessment of the Sec dependence of proteins has been made possible by the development of strains in which individual Sec proteins can be conditionally depleted(4, 6) . These strains contain either the secDF genes or the secE gene under control of the highly repressible araBAD promoter. Strains in which expression of the secDF genes is repressed have a very severe and general secretion defect for signal sequence-containing proteins after depletion of the SecD and F proteins(4) . In this study, we characterize the secretion defect of cells that have been depleted for the SecE protein.

Integral cytoplasmic membrane proteins often have large hydrophilic domains that must be translocated to the extracytoplasmic face of the membrane. However, most cytoplasmic membrane proteins are synthesized without cleavable N-terminal signal sequences. Whether most of these polypeptides depend on the Sec machinery for translocation of hydrophilic domains through the hydrophobic membrane is unresolved. A few cytoplasmic membrane proteins have been tested for their dependence on the Sec machinery for membrane insertion, including M13 procoat protein, leader peptidase (Lep), the methyl-accepting chemotaxis receptor protein Tsr, the ProW component of the ProU osmoregulatory system, and the MalF component of the maltose transport complex(1, 7, 8, 9) . These analyses have suggested that the M13 procoat, ProW, and MalF are Sec-independent, whereas Lep and Tsr are Sec-dependent.

Recently, an highly sensitive assay for the proper insertion of the MalF protein into the cytoplasmic membrane and its subsequent assembly into the hetero-oligomeric maltose transport complex was described (10) . This assay is based on the accessibility of the periplasmic domains of MalF (3, 180, 30, and 30 residues, respectively; (11) ) to exogenous proteases. The sensitivity of this assay in combination with the new SecE depletion mutant led us to readdress the dependence of MalF on the Sec apparatus for the export of its periplasmic regions.


MATERIALS AND METHODS

Bacterial Strains

Strain CM124 was constructed from PS291 (secEDelta19-111, pcnB80 zadL::(Tn10 Tc^s Str^r) phoADeltaPvuII, lacDeltaX74, galE, galK, rpsL, recA::cat pBRU; 5) by transformation with plasmid pCM22 (6) , replacing plasmid pBRU (secE) to test the effects of depletion of SecE upon secretion of various periplasmic and outer membrane proteins. pCM22 has the secE gene expressed from the strongly repressible promoter of the araBAD operon.

The MalF protein in all experiments is expressed at physiological levels from the normal chromosomal copy of the gene in the malB locus at 92 min on the E. coli chromosome; therefore there are no artifacts from protein overproduction. Strains BT62, BT8, and BT10 are malT^c derivatives of MC4100 (F, DeltalacU169, thiA, relA, rpsL, araD139). BT8 and BT10 are Mal and malEmalFmalGmalK, respectively (described in (10) ). BT62 is malEmalFmalGmalK with secEDelta19-111, pcnB80 zadL::(Tn10 Tc^s Str^r), recA::cat, and pCM22.

BT7 is Mal P1 transductant of KM1089, a malT^c,DeltamalF derivative of the MC1000 strain DHB3 (araD139, Delta(ara-leu) 7697, lacDeltaX74, DeltaphoA PvuII, phoR, thi, rpsL; 1). BT63 is azi-4 Leu P1 transductant of BT7.

Growth of Cells and Proteolysis Experiments

Cultures of BT7, BT8, BT63, and KM1089 were grown with aeration at 37 °C in M63 minimal medium supplemented with 0.2% glycerol, thiamine, and all amino acids except cysteine and methionine.

Cultures of CM124 were grown with aeration at 37 °C in M63 minimal medium supplemented with 0.4% D-glucose or L-arabinose, 0.2% glycerol, thiamine, and all amino acids except cysteine and methionine. Cultures of BT62 for proteolysis experiments were grown in the same fashion except with either 0.2% glucose or arabinose.

To deplete BT62 of SecE, cultures were diluted 1:100 from an overnight culture grown with arabinose into fresh M63 + glycerol + arabinose. After 2-4 h of growth, the arabinose-supplemented culture was split. One portion of the culture was maintained in medium + glycerol + arabinose. The cells from the other portion of the culture were washed in M63 medium + glycerol and then resuspended in M63 + glycerol + 0.2% glucose. Cultures were maintained at A of 0.2-0.4 during SecE depletion and S labeling.

Cells were labeled for 30 s with 40-50 µCi/ml [S]methionine using ExpreSS label (New England Nuclear). For proteolysis experiments with strain BT62, cells were induced with 1 mM cAMP (Sigma) for 5 min before the addition of radiolabel to amplify the expression of the mal genes. When NaN(3) was used, it was added to 2 mM (during the cAMP induction for strain BT62) for 3 min before labeling. After labeling, cold methionine was added to 0.05%, and incubation at 37 °C continued for 10 min. Afterwards, the pulse and chase samples were chilled to 0 °C, harvested, and converted to spheroplasts as described previously(12) . Proteolysis was done on 0.5-ml portions of labeled cells for 20 min at 0 °C with 25 µg/ml freshly prepared trypsin (Worthington Enzymes) and stopped by the addition of phenylmethylsulfonyl fluoride (Sigma) at 0.4 mg/ml and soybean trypsin inhibitor (Boehringer Mannhiem) at 25 µg/ml. After labeling/proteolysis, cells were harvested and resuspended in 50 µl of 50 mM Tris, pH 7.6, at 25 °C, 2% SDS, 1 mM EDTA (TSE) and heated to 65 °C for 20 min. Control immunoprecipitations of MBP were done from 100-µl portions of labeled cells that were resuspended in 50 µl of TSE and heated to 65 °C for 20 min. TSE samples each were diluted into 0.8 ml of 50 mM Tris, pH 8.0, 150 mM NaCl, 2% Triton X-100, 1 mM EDTA buffer, and proteins were immunoprecipitated as described with appropriate antibodies and Staphylococcal protein A (12) . Samples were analyzed by SDS-PAGE on 12.5% resolving gels. Quantitation of proteins was done with a Molecular Dynamics PhosphorImager(12) , and the data presented represent the averages of three experiments. Proteins were detected in Western blot analysis as described(10) , using a goat anti-rabbit conjugated secondary antibody (Boehringer Mannhiem).

Antibodies

Proteins were precipitated with antibody specific to MalF(10) , MBP (from New England Biolabs or Beckwith lab), DegP (Beckwith lab), and OmpA (Beckwith lab). The MalK antibodies used for control experiments (as shown in Fig. 3B) were provided by E. Schneider.


Figure 3: The effect of SecE depletion and NaN(3)-treatment on MalF protease sensitivity. Strains BT62 (MalF) and KM1089 (DeltaMalF) were grown and treated as described under ``Materials and Methods.'' Sec samples were grown in permissive conditions (in glycerol, no NaN(3) for KM1089, in glycerol + arabinose, no NaN(3) for BT62). SecE BT62 samples were grown in glucose for 3.5 h. SecA samples were grown in permissive conditions, and NaN(3) was added before labeling. A, pulse-labeled (P) or pulse-labeled and chased (C) samples were untreated(-) or treated (+) with trypsin prior to immunoprecipitation with MalF antiserum. The radiolabeled intact MalF protein and three MalF tryptic peptides (produced under Sec conditions: F1, F2, and F3) are visualized here after SDS-PAGE and fluorography with quantitation provided in Table 1. Background bands unrelated to MalF but recognized by the antiserum are shown (a, b, c, and d). B, a portion of the TSE-solublized samples from the proteolysis experiment shown were analyzed after SDS-PAGE by Western blotting with MalK antiserum. Pulse samples without trypsin are in lanes 1 and 3 for KM1089 and lanes 5, 8, and 12 for BT62. Pulse samples with trypsin are in lanes 2 and 4 for KM1089 and lanes 6, 9, and 13 for BT62. Chase samples without trypsin for BT62 are in lanes 10 and 14 (and data not shown for BT62 + glucose at 3.5 h). Chase samples with trypsin for BT62 are in lanes 7, 11, and 15.






RESULTS

SecE Depletion Causes a General Inhibition of Protein Export

To examine the effects of depletion of SecE upon secretion, we utilized a strain deleted of its chromosomal copy of secE but containing a plasmid present at low copy number with secE under control of the strongly repressible promoter of the araBAD operon(6) . This strain, CM124, is absolutely dependent upon the addition of arabinose to the growth medium for prolonged viability. After dilution of a CM124 culture from medium with arabinose to medium with glucose (depletion conditions), cell growth continues for several hours at a rate indistinguishable from the rate of a culture in arabinose (Fig. 1). After 5.5-6.5 h in glucose, the growth rate of the strain decreases.


Figure 1: Growth of SecE depletion strains. Strain CM124 was grown overnight in arabinose and then passaged into medium containing either glucose (box) or arabinose (). BT62 has the same growth curve as CM124 (data not shown). Under depletion conditions, cells grown in glucose can still recover from the effects of the SecE depletion if switched to medium with arabinose. There is a high plating efficiency (>50%) for cells moved from minimal broth with glucose to LB agar with arabinose up to 5-7 h after the incubation in glucose has started. We never have recovered any revertants of CM124 or BT62 that can grow continuously on medium with glucose and without arabinose.



CM124 cultures were assayed for the extent of their secretion defect during the course of SecE depletion. At several time points after dilution into medium with glucose or arabinose, this secretion defect was visualized by pulse labeling cells and examining the ratio of precursor to mature form of several secreted proteins using immunoprecipitation and SDS-PAGE (Fig. 2). Cells expressing SecE (grown in arabinose) exhibit no accumulation of the precursor forms of the periplasmic proteins DegP and MBP or the outer membrane protein OmpA. In contrast, cells depleted of SecE exhibit a marked defect in secretion of these proteins after 3.5 h (a time at which the two cultures are doubling at the same rate), which becomes nearly complete at later time points. Precursor forms of exported proteins such as DegP, which had previously been difficult to observe under restrictive conditions for the conditional Sec mutants, were readily observed in the SecE-depleted cells. In addition, OmpA translocation during the course of a 5-min chase was substantially less efficient than that observed using Sec conditional mutants(13) .


Figure 2: Depletion of SecE results in a severe secretion defect. Strain CM124 was grown as described in Fig. 1. Pulse-chase labeling was performed at 3.5, 5.5, and 7.5 h. The translocation of MBP, DegP, and OmpA was assayed by visualization of immunoprecipitated precursor (p) and mature (m) forms of these proteins at the pulse (0 time point) and 1-, 2-, and 5-min chase time points. The precursor form of DegP appears as a diffuse doublet rather than a discreet band on these gels.



Effect of SecE Depletion on the Membrane Incorporation of MalF

Due to the strength of the secretion defect observed in SecE-deficient conditions, we asked whether we could detect a dependence of MalF on SecE for its insertion into the cytoplasmic membrane. The three larger periplasmic domains of MalF are sensitive to cleavage by exogenously added proteases (such as trypsin) in spheroplasts of strains lacking the MalK or MalG proteins(10) . We reasoned that if MalF depends on SecE for its insertion into the cytoplasmic membrane, then depletion of SecE might result in the appearance of a trypsin-resistant MalF species. The protease-resistant MalF protein would remain in the cytoplasm and not have its periplasmic domains accessible to cleavage by externally added proteases.

To assay for MalF insertion using the proteolysis assay, spheroplasts were derived from a SecE depletion strain BT62 (malEFGK) grown in either glucose (depleted of SecE) or arabinose (Sec). We chose time points early in the SecE depletion process to maximize the likelihood that we were testing the direct effects of SecE depletion on MalF membrane insertion. In addition, the strength of the secretion defect for MBP was monitored in parallel as described for Fig. 2, so that a comparison of protein secretion versus cytoplasmic membrane protein insertion could be made. In cells that are either Sec or depleted of SecE for 2 h, the MalF protein was inserted into the cytoplasmic membrane in a trypsin-sensitive form, with its periplasmic domains accessible to protease (Table 1, +Ara and +Glu, 2 h; +Ara samples shown in Fig. 3A, lanes 3-6). In contrast, at later time points of SecE depletion, a substantial proportion of MalF became insensitive to trypsin proteolysis (Table 1, +Glu, 2.75 and 3.5 h; +Glu at 3.5 h shown in Fig. 3A, lanes 7-10). This MalF protein became trypsin-sensitive if the spheroplasts in these experiments were lysed prior to the addition of the protease (data not shown), indicating that this form of MalF was not intrinsically protease-resistant. We speculate that in secretion-compromised cells, MalF that is insensitive to externally added protease is localized to one of two compartments. Because of the hydrophobic nature of the transmembrane domains of MalF, uninserted protein might aggregate in the cytoplasm. Alternatively, insertion of some or all of the transmembrane domains might occur, resulting in MalF that is apposed to or partially inserted into the cytoplasmic membrane. This latter species would have some or all of its periplasmic domains (that are normally sensitive to external protease) in the cytoplasm. To exclude the possibility that SecE-depleted cells were resistant to spheroplast formation, which would also result in protease-resistant MalF, steady state populations of MalF were shown to be sensitive to externally added protease by Western blot analysis (data not shown). This population of MalF molecules presumably would have been properly incorporated into the membrane during the Sec conditions of the depletion time course and persisted to late times in the experiment.

The amount of radiolabeled MalF detected in the different samples does not reflect significant variation in the recovery or the integrity of the spheroplasts in each case. A fraction of each of the solublized cell extracts from the samples shown in Fig. 3A was examined by Western blot analysis (shown in Fig. 3B) with antiserum specific for MalK, a peripheral cytoplasmic membrane protein that associates with the cytoplasmic face of the membrane. A significant sample to sample variation in the recovery of the spheroplasts after the experiment would be detected as a loss of MalK signal on the Western blot in one sample in a set compared with its partners. If any of the spheroplasted samples had lysed during the experiment, the trypsin would have degraded the MalK protein inside the cell. This would be evidenced by a decrease in the intensity of the MalK signal in the samples with trypsin compared with controls without trypsin. The amount of MalK detected in the different samples of each set of spheroplasted samples is similar. In this experiment, less MalK is expressed in the SecE-depleted BT62 cells grown in glucose for 3.5 h than in the Sec cells grown in arabinose (Fig. 3B, lanes 5-7 versus 12-15). In this experiment, we also observed a 30-40% decrease in the MalF and MBP expression under the same conditions (Fig. 3A, lanes 7 and 9 versus lanes 3 and 5 and data not shown). We found this overall decrease in the expression of the mal genes under SecE-depleted conditions in approximately half of the repetitions of this experiment.

Some polypeptides unrelated to MalF also are immunoprecipitated by the MalF antiserum. These are shown in control samples from strain KM1089 (DeltamalF; Fig. 3A, lanes 1, 2, 15, and 16), which does not express MalF. The most notable of these are denoted as bands a, b, c, and d. The polypeptides c and d are only detected after proteolysis of SecE-depleted or SecA-inhibited (see below) cells and are absent from samples from Sec cells. The identity of these polypeptides is unknown. However, they do not interfere with the quantitation of the protease sensitivity of MalF and do not represent novel MalF tryptic peptides produced under Sec-inhibited conditions.

The secretion of MBP appears to be more sensitive than the membrane insertion of MalF to the effects of SecE depletion. Fig. 4shows that when the background levels of precursor MBP or protease-resistant MalF under Sec conditions (BT62 with arabinose) are subtracted, the effect of a Sec defect on MBP export is detectable sooner and is greater than the effect on MalF membrane insertion.


Figure 4: The effect of Sec inhibition on MBP and MalF localization. The abundance of precursor MBP and protease-resistant MalF is shown for after NaN(3) treatment or at different time points in the SecE depletion time course for BT62. The background level of protease-resistant MalF in cultures grown in arabinose was subtracted from the data shown in Table 1.



Two additional observations come from comparing the pulse-labeled samples with those that had been pulse-labeled and then chased. First, at time points when there is a substantial secretion defect (as measured by the inhibition of MBP export, Table 1), there is a dramatic increase in the amount of degradation of MalF by endogenous proteases during the course of the chase (comparing the pulse without trypsin with the chase without trypsin samples at 3.5 h in glucose; Table 1, MalF stability). We discuss this observation further below. Second, the portion of the MalF that is protease-resistant decreases by the end of the chase during Sec conditions (Table 1, +Glu, 2.75 and 3.5 h). The diminution of the secretion defect over the course of the chase is also observed in the MBP analysis and probably reflects residual Sec activity in the depleted cells.

Membrane Incorporation of MalF in Sodium Azide-treated Cells

Previous work had suggested that MalF is not dependent on the SecA component of the secretion apparatus for its insertion into the cytoplasmic membrane(1) . In these experiments, cells were treated with NaN(3) to inhibit SecA function(14) , and then MalF insertion was assayed by a protease sensitivity assay similar to the one described here. Two important facts led us to re-examine the dependence of MalF insertion on SecA. First, as described in the previous section, MalF insertion was dependent on expression of SecE, one of the core components of the secretion apparatus. Because the basic mechanism of secretion is thought to involve the actions of SecE, SecY, and SecA, it seemed likely that SecA might also be involved in MalF insertion. Second, the experiments of McGovern and Beckwith (1) were performed in a Mal strain background. Normally, MalF expressed in a Mal strain acquires a protease-resistant form that reflects its inclusion into a stable complex with MalG and MalK; absence of either of these components of the complex results in protease-sensitive MalF(10) . It is possible that in the Mal strains, MalF could acquire protease resistance by two different mechanisms, one in which MalF becomes complexed with MalG and MalK and one in which MalF is not inserted into the membrane due to a secretion defect. To address this latter possibility, both Mal and Mal strains were used to assess NaN(3) sensitivity of MalF insertion into the cytoplasmic membrane.

To confirm the results of McGovern and Beckwith(1) , we tested the protease sensitivity of pulse-labeled MalF in the Mal strain BT8 with and without treatment with NaN(3). Without NaN(3) treatment, MalF initially inserts into the m embrane in a trypsin-sensitive form and is rapidly converted into a trypsin-resistant conformation as a consequence of complex assembly with MalG and MalK (Table 2). The initial trypsin-sensitive form is detectable as a portion (roughly half) of the population of labeled MalF molecules after a short pulse time point in this experiment; the MalGK-complexed, trypsin-resistant MalF form is already abundant at the pulse time point and becomes the predominant species after a chase (Table 2). Consistent with previous results, cells treated with NaN(3) show no difference in the amount of trypsin-resistant MalF at the pulse time point compared with nontreated cells. In contrast, our added quantitation of the amount of trypsin-resistant MalF after a 10-min chase in the NaN(3)-treated versus untreated samples showed a significant difference (35 versus 65%). The inability to distinguish betwee n the two possible populations (described above) of trypsin-resistant MalF in these Mal cells makes interpretation of the data difficult. However, the lower level of protease-resistant MalF at the end of the chase in NaN(3)-treated Mal cells suggests that the ability of MalF to assemble into the MalFGK complex in the membrane was compromised in the treated cultures.



The ambiguities created by using Mal cells were alleviated by an analysis of the protease sensitivity of MalF in the similar malG strains BT62 and BT10. (For comparison with the SecE depletion data, the data from NaN(3)-treated BT62 cells are shown in Fig. 3and Fig. 4and in Table 1. The quantitation of the BT10 data is given in Table 2. NaN(3)-treated control samples of the DeltamalF strain KM1089 are shown in Fig. 3.) In the cultures not treated with NaN(3), the majority of MalF synthesized in a pulse is inserted into the cytoplasmic membrane in a trypsin-sensitive form, consistent with previous results(10) . This population of MalF remains trypsin-sensitive after chase, because it is unable to form a native complex. In NaN(3)-treated cultures, 30-40% of the MalF synthesized during a pulse-labeling is resistant to exogenous trypsin. Because none of this resistant species is attributable to MalFGK complex formation, it represents noninserted MalF.

As was the case in the SecE depletion experiments, this uninserted population of MalF in NaN(3)-treated cells was susceptible to endogenous proteases, as evidenced by its gradual disappearance during the course of a 10-min chase (Table 2). The stability of MalF over the course of a 10-min chase in NaN(3)-treated cultures ranges from 48-68%, compared with a slight increase in the amount of MalF detected in the chase compared with the pulse time points in untreated Sec cells. The decrease in MalF stability in Sec-inhibited cells is observed in both Mal and the malG strains.

To show that the species of MalF that is sensitive to endogenous proteolysis in NaN(3)-treated cells was actually the result of a block in SecA activity, we characterized the stability of the protein in the Mal strains BT7 and BT63. BT7 produces a wild type SecA protein. BT63 produces a SecA mutant that is partially resistant to NaN(3) (from the azi-4 allele; (14) ). The trypsin sensitivity of MalF in pulse-labeled cultures of BT7 with and without NaN(3) treatment is analogous to that observed in BT8 under similar conditions (Table 2). However, the sensitivity of MalF to trypsin and endogenous proteases in BT63 is relatively unchanged by the presence or the absence of NaN(3) treatment at both the pulse and the chase time points. The NaN(3) treatment of BT63 apparently did not impair either the membrane insertion of MalF or its subsequent assembly into the MalFGK complex. This result strongly suggests that the NaN(3) treatment of azide-sensitive cells affects the proper membrane insertion of MalF and the stability of MalF to proteolysis directly via the inhibition of SecA protein and not indirectly by a general disruption of the cell's physiology.

These results indicate that the proper insertion of MalF requires the activity of SecA in addition to SecE. As with the SecE-depleted cells, the inhibition of MalF membrane insertion and MBP export caused by NaN(3) is diminished at the end of a 10-min chase after pulse-labeling. The inhibition of membrane insertion for MalF is not as strong with NaN(3) as with SecE depletion at the 3.5 h time point ( Fig. 4and Table 1). However, the inhibition of MBP export is as strong with NaN(3) as with SecE depletion in BT62 at 3.5 h.


DISCUSSION

The involvement of the Sec proteins in the export of signal sequence-containing proteins such as OmpA and MBP is well documented. However, a general mechanism for the insertion of proteins into the cytoplasmic membrane, including translocation of their hydrophilic domains across this membrane, has not been established. This issue has been addressed in only a few cases, and the examined proteins fell into two classes: 1) Sec-independent, e.g., M13 procoat, ProW, and MalF, and 2) Sec-dependent, e.g., Lep, SecY, and Tsr(1, 7, 8, 9, 15) . In contrast to earlier work, we show here that MalF insertion into the cytoplasmic membrane requires both SecE and SecA.

Systems to study the Sec dependence of cytoplasmic membrane protein insertion have been plagued by two major problems. First, a general assay (such as signal sequence cleavage for fully secreted proteins) for cytoplasmic membrane protein insertion does not exist. To compensate for this, several studies have used an indirect assay for Sec dependence that relies on a comparison of the activity or localization of an enzymatic/polypeptide tag in fusion protein constructs in Sec or Sec conditions(8, 9) . Although the results from these experiments are suggestive, the notion that the marker tag of the fusion protein does not affect the normal process of membrane insertion for the target protein is largely untested. A few specific proteins can be directly tested for Sec involvement in membrane insertion. For example, the studies on the membrane insertion of Lep assay its Sec dependence for insertion by the protease sensitivity of a large periplasmic domain in Sec-inhibited spheroplasts(7) . The inhibition of export of this domain results in the accumulation of protease-resistant Lep. Unfortunately, relatively few integral cytoplasmic membrane proteins can be analyzed by this method because of their general resistance to exogenous proteases in extracytoplasmic domains (e.g., Tsr; (16) ). MalF rapidly acquires resistance to exogenous proteases upon its export to the cytoplasmic membrane when assembled into the oligomeric MalFGK complex. However, in spheroplasted MalG cells, properly localized MalF is sensitive to added proteases(10) . This finding allows for a sensitive MalF insertion assay in which one can attribute protease-resistant MalF in malG cells unambiguously to noninserted MalF.

The second major pitfall encountered in previous studies was the use of relatively weak conditional sec mutations. As has been shown for secEcs mutations, many conditional sec mutations likely cause a decrease in the amount of functional secretion apparatus in the cell(5, 13) . It seemed possible to us that if cytoplasmic membrane proteins in general had a greater affinity for the secretion apparatus than fully secreted proteins, then their membrane insertion and export of hydrophilic domains would be relatively less affected by the limited amount of secretion apparatus than that of fully secreted proteins. In fact, various members within the class of fully secreted proteins in E. coli, such as DegP, are only slightly affected by partial secretion defects in the cell; others, such as MBP, are extremely sensitive to even slight Sec defects. To address this issue, we sought to utilize a stronger conditional allele of the secE gene. One such conditional SecE mutant, in which the secE gene is expressed from the araBAD promoter, has been described in previous studies(6) . Because SecE is an essential component of the secretion apparatus, strains containing the psecE construct are absolutely dependent on arabinose for prolonged growth (Fig. 1).

The secretion defect in cells that have been depleted for the SecE protein is much stronger than that observed in other conditional sec mutants. The magnitude of this defect is evidenced by two findings. First, CM124 cells depleted of SecE accumulate large amounts of precursor species of proteins such as DegP, which have been difficult to visualize previously (Fig. 2). Second, precursors of proteins, such as OmpA, that accumulate under SecE depletion conditions are very slowly converted to the mature species during the course of a chase. This is in contrast to the fate of precursor OmpA accumulated in many other sec conditional mutants where a large proportion of this precursor species eventually becomes exported(13) . Conversely, there is no detectable secretion defect in the SecE depletion strains when grown under permissive conditions, in contrast to other secE conditional alleles (Fig. 2; (13) ). The ability to both elicit a strong secretion defect in SecE-depleted cells and to assay MalF insertion in a sensitive manner led us to readdress whether MalF has a Sec requirement for its insertion into the cytoplasmic membrane.

In the SecE depletion strain BT62 (malFmalG) grown in arabinose, MalF is inserted into the membrane and is sensitive to trypsin in spheroplasted cells ( Fig. 3and Table 1). This trypsin sensitivity is indistinguishable from that observed in wild type secEmalFmalG cells (Table 1, Table 2; also see 10). In cells depleted of SecE for 3.5 h, there is a dramatic increase in the amount of pulse-labeled MalF protein that is resistant to proteolysis (Fig. 4). These data strongly suggest that MalF requires the SecE component of the secretion apparatus for its proper insertion into the cytoplasmic membrane.

The dependence of MalF on SecE for its membrane insertion prompted us to re-examine the involvement of the SecA protein in this process. Like SecE-depleted cells, NaN(3)-treated BT62 cells also contain an elevated level of trypsin-resistant MalF immediately after the synthesis of the protein ( Fig. 3and Table 1). This elevated level of trypsin-resistant MalF is also seen in the secEmalFmalG strain BT10 when treated with NaNa(3) (Table 2). These results are consistent with an additional dependence on SecA for the membrane insertion of MalF.

Previously, McGovern and Beckwith (1) had examined the protease sensitivity of pulse-labeled MalF in cultures of a Mal strain with and without treatment with NaN(3)(1) . In both cases, they observed a population of protease-sensitive MalF (50%) giving rise to similar peptide patterns after SDS-PAGE. To directly compare our results with theirs, we examined the protease sensitivity of MalF in the Mal strain BT8 (Table 2). We found that a similar amount of trypsin-resistant MalF is present at the pulse time point, with or without NaN(3) treatment, consistent with the observations of McGovern and Beckwith(1) . We further characterized the amount of MalF and its trypsin sensitivity after a chase. The increase in the level of trypsin-resistant MalF during a chase in NaN(3)-untreated cells reflects the continued incorporation of MalF into the MalFGK complex. In contrast, there is a decrease in the amount of trypsin-resistant MalF at the end of a chase in the presence of NaN(3). Therefore, proteolysis experiments that only examined the state of MalF at the pulse time point in Mal cells led to incorrect conclusions regarding the Sec dependence of MalF.

In both SecE-depleted and SecA-inhibited (NaN(3)-treated) cultures, an unstable population of MalF is revealed in the unproteolyzed controls (see Table 1and Table 2, MalF stability). This turnover of newly synthesized protein during the course of the chase is a dramatic increase in the sensitivity of MalF to endogenous proteases. We suggest that when MalF is not properly inserted into the membrane, it becomes a substrate for cellular proteases, which recognize it as a misfolded protein. In BT63, containing NaN(3)-resistant SecA, NaN(3) treatment did not result in a l oss in MalF stability to endogenous proteases (Table 2).

The amount of protease-resistant MalF caused by NaN(3) inhibition of SecA is smaller than that caused by SecE depletion of the cell ( Fig. 4and Table 1). This difference in the inhibition of the membrane insertion of MalF caused by the different treatments is in contrast to a similar inhibition of MBP export due to NaN(3) treatment compared with SecE depletion at 3.5 h +Glu (Fig. 4). MalF also seems be affe cted at later times than MBP in the SecE depletion time course. The greater defect in the membrane insertion of MalF caused by SecE depletion than by NaN(3) inhibition of SecA is consistent with two previous observations. First, Werner et al.(17) have observed in vitro that the cytoplasmic membrane mannitol carrier protein MtlA was dependent upon the SecY protein for proper membrane insertion. However, MtlA inserted into membranes normally in the presence of reduced levels of SecA. Second, Rusch et al.(18) have characterized the export of alkaline phosphatase precursors as a function of the relative hydrophobicity of their signal sequences. They found that signal sequences with very high hydrophobicity mediated precursor export that was not detectably inhibited by treatment of cells with NaN(3). Proteins localized by the Sec apparatus with very hydrophobic signal sequences or transmembrane domains (like MalF or MtlA) may have a higher affinity for the Sec machinery than more typical signal sequence-containing precursor proteins. Therefore, detecting a Sec dependence for this class of proteins may require a severe Sec defect stronger than most conditional Sec mutants at nonpermissive conditions.

This proposal is supported by work from two groups characterizing the protein export (SEC) pathway in Saccharomyces cerevisiae. Green et al.(19) and Stirling et al.(20) found that the insertion of proteins into the endoplasmic reticulum membrane is dependent on several proteins, including SEC61 (a homolog of the E. coli SecY protein). However, not all sec alleles can result in inhibition of membrane protein insertion. Apparently strongly defective mutants or double mutants are required in many instances to detect a SEC involvement in membrane protein insertion, whereas weaker mutants will inhibit the export of several soluble proteins with cleavable signal sequences across the membrane.

We have determined that MalF depends on the Sec apparatus for proper membrane insertion using a direct protease assay coupled with two strategies for eliciting potent and specific secretion defects. In contrast, McGovern and Beckwith (1) concluded that MalF does not utilize the Sec apparatus for membrane localization by examining MalF and MalF fusion proteins in either SecDFcs mutants or NaN(3)-treated cells. Our work does not address the dependence of MalF on SecDF for translocation of periplasmic domains. We did assay the export of periplasmic domains of MalF-PhoA fusion proteins in NaN(3)-treated cells (data not shown). In results similar to those of McGovern and Beckwith(1) , we also failed to detect any inhibition caused by NaN(3) in the membrane assembly of the MalF fusion proteins. However, recent experiments of Sääf et al.(21) and Jander et al.(22) did demonstrate a Sec dependence for export of some periplasmic domains in other MalF fusion constructs. In the experiments of Sääf et al.(21) , NaN(3) treatment of cells expressing MalF-Lep fusions caused a weak defect in export of the large periplasmic domain of MalF, compared with the export of the precursor form of OmpA. The work of Jander et al.(22) demonstrated a role for both SecA and SecE in the export of biotinylated tags fused to different regions of Mal, but the degree of Sec involvement was not quantified.

Our study highlights the pitfalls and difficulties in determining the Sec involvement in integral membrane protein assembly. Our results suggest that great caution should be used in the interpretation of localization data from fusion protein studies, given that the MalF-PhoA fusions did not show a SecA dependence clearly evident from our analysis of the intact protein and from the analysis of some kinds of fusion proteins. The exclusive use of NaN(3)-inhibition of SecA as a secretion defect in this kind of experiment may be inadequate. We advise the additional use of strong Sec mutants (such as a SecE depletion strain) for the analysis of Sec dependence for protein localization studies.

Further studies are needed to determine whether membrane proteins without cleavable signal sequences generally rely on the Sec pathway for membrane assembly. Based on studies with an extensive collection of Lep fusion constructs, von Heijne and co-workers have proposed that the translocation of short (leq60 residues) extracytoplasmic domains is Sec-independent, whereas that of longer domains is generally Sec-dependent (reviewed in (23) ). The membrane insertion of MalF is now partially consistent with this model. However, because we quantified the amount of intact MalF after proteolysis, our results suggest that MalF may require the Sec machinery for translocation of each of its three periplasmic domains (with 180, 30, and 30 residues) that are susceptible to proteolytic cleavage, not just the largest. It may be that many, if not most, other membrane proteins will exploit the Sec machinery during the normal in vivo insertion and assembly process, regardless of the size of the hydrophilic domains to be translocated.


FOOTNOTES

*
The work in Dr. Traxler's lab was supported by a grant from the National Science Foundation. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: University of Washington, Dept. of Microbiology, Box 357242, Seattle, WA 98195. Tel.: 206-543-5485; Fax: 206-543-8297; btraxler{at}u.washington.edu.

Supported by a grant from the National Institutes of Health. Present address: Myco Pharmaceuticals, Cambridge, MA 02139.

(^1)
The abbreviations used are: MBP, maltose-binding protein; PAGE, polyacrylamide gel electrophoresis; Sec, secretion.


ACKNOWLEDGEMENTS

We thank Jon Beckwith, Colin Manoil, Karen McGovern, Michael Ehrmann, and Dana Boyd for helpful suggestions and criticisms and E. Schneider for MalK antibodies. Technical assistance was provided by A. Holt and T. Luna. We thank F. Taub for assistance in preparing the figures.


REFERENCES

  1. McGovern, K., and Beckwith, J. (1991) J. Biol. Chem. 266, 20870-20876 [Abstract/Free Full Text]
  2. Schatz, P. J., and Beckwith, J. (1990) Annu. Rev. Genet. 24, 215-248 [CrossRef][Medline] [Order article via Infotrieve]
  3. Wickner, W., Driessen, A. J., and Hartl, F.-U. (1991) Annu. Rev. Biochem. 60, 101-124 [CrossRef][Medline] [Order article via Infotrieve]
  4. Pogliano, J. A., and Beckwith, J. (1994) EMBO J. 13, 554-561 [Abstract]
  5. Schatz, P. J., Bieker, K. L., Ottemann, K. M., Silhavy, T. J., and Beckwith, J. (1991) EMBO J. 10, 1749-1757 [Abstract]
  6. Murphy, C. K., and Beckwith, J. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 2557-2561 [Abstract]
  7. Wolfe, P. B., Rice, M., and Wickner, W. (1985) J. Biol. Chem. 260, 1836-1841 [Abstract]
  8. Gebert, J. F., Overhoff, B., Manson, M. D., and Boos, W. (1988) J. Biol. Chem. 263, 16652-16660 [Abstract/Free Full Text]
  9. Whitley, P., Zander, T., Ehrmann, M., Haardt, M., Bremer, E., and von Heijne, G. (1994) EMBO J. 13, 4653-4661 [Abstract]
  10. Traxler, B., and Beckwith, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 10852-10856 [Abstract]
  11. Boyd, D., Manoil, C., and Beckwith, J. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 8525-8529 [Abstract]
  12. Traxler, B., Lee, C., Boyd, D., and Beckwith, J. (1992) J. Biol. Chem. 267, 5339-5345 [Abstract/Free Full Text]
  13. Pogliano, K. J., and Beckwith, J. (1993) Genetics 133, 763-773 [Abstract/Free Full Text]
  14. Oliver, D. B., Cabelli, R. J., Dolan, K. M., and Jarosik, G. P. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 8227-8231 [Abstract]
  15. Akiyama, Y., and Ito, K. (1989) J. Biol. Chem. 264, 437-442 [Abstract/Free Full Text]
  16. Seligman, L., and Manoil, C. (1994) J. Biol. Chem. 269, 19888-19896 [Abstract/Free Full Text]
  17. Werner, P. K., Saier, M. H., Jr., and Muller, M. (1992) J. Biol. Chem. 267, 24523-24532 [Abstract/Free Full Text]
  18. Rusch, S. L., Chen, H., Izard, J. W., and Kendall, D. A. (1994) J. Cell. Biochem. 55, 209-217 [Medline] [Order article via Infotrieve]
  19. Green, N., Fang, H., and Walter, P. (1992) J. Cell Biol. 116, 597-604 [Abstract]
  20. Stirling, C. J., Rothblatt, J., Hosobuchi, M., Deshaies, R., and Schekman, R. (1992) Mol. Biol. Cell 3, 129-142 [Abstract]
  21. Sääf, A., Andersson, H., Gafvelin, G., and von Heijne, G. (1995) Mol. Membr. Biol. 12, 209-215 [Medline] [Order article via Infotrieve]
  22. Jander, G., Cronan, J. E., and Beckwith, J. (1996) J. Bacteriol., 178, in press
  23. von Heijne, G. (1994) FEBS Lett. 346, 69-72 [CrossRef][Medline] [Order article via Infotrieve]

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