Phospholipid-induced Monomerization and Signal-peptide-induced Oligomerization of SecA*

Jordi BenachDagger §, Yi-Te Chou§, John J. FakDagger §, Anna ItkinDagger §, Daita D. NicolaeDagger §, Paul C. SmithDagger , Guenther Wittrock, Daniel L. FloydDagger , Cyrus M. GolsazDagger , Lila M. Gierasch, and John F. HuntDagger ||

From the Dagger  Department of Biological Sciences, Columbia University, New York, New York 10027 and the  Departments of Biochemistry & Molecular Biology and Chemistry, University of Massachusetts, Amherst, Massachusetts 01003

Received for publication, June 17, 2002, and in revised form, October 25, 2002

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
REFERENCES

The SecA ATPase drives the processive translocation of the N terminus of secreted proteins through the cytoplasmic membrane in eubacteria via cycles of binding and release from the SecYEG translocon coupled to ATP turnover. SecA forms a physiological dimer with a dissociation constant that has previously been shown to vary with temperature and ionic strength. We now present data showing that the oligomeric state of SecA in solution is altered by ligands that it interacts with during protein translocation. Analytical ultracentrifugation, chemical cross-linking, and fluorescence anisotropy measurements show that the physiological dimer of SecA is monomerized by long-chain phospholipid analogues. Addition of wild-type but not mutant signal sequence peptide to these SecA monomers redimerizes the protein. Physiological dimers of SecA do not change their oligomeric state when they bind signal sequence peptide in the compact, low temperature conformational state but polymerize when they bind the peptide in the domain-dissociated, high-temperature conformational state that interacts with SecYEG. This last result shows that, at least under some conditions, signal peptide interactions drive formation of new intermolecular contacts distinct from those stabilizing the physiological dimer. The observations that signal peptides promote conformationally specific oligomerization of SecA while phospholipids promote subunit dissociation suggest that the oligomeric state of SecA could change dynamically during the protein translocation reaction. Cycles of SecA subunit recruitment and dissociation could potentially be employed to achieve processivity in polypeptide transport.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
REFERENCES

The SecA translocation ATPase mediates preprotein translocation through the cytoplasmic membrane of eubacteria via cycles of binding and release from the SecYEG translocon (1-5) coupled to its own ATPase cycle (6-8) (reviewed in Ref. 9). Although the default translocation pathway is believed to involve an initial phase powered by the ATPase activity of SecA and a later phase powered by a transmembrane electrochemical potential coupled to SecYEG, the ATPase activity of SecA can mediate the translocation of an entire preprotein in the absence of a transmembrane potential (7). This observation has led to the conclusion that the SecA ATPase can mediate the processive translocation of polypeptide chains (10).

Each cycle of ATP binding and hydrolysis by SecA is believed to result in the translocation of about 40 residues of preprotein (7, 11). There is substantial evidence that SecA interacts with both the N-terminal signal sequence (6, 12-21) that targets preproteins for export from the cytoplasm as well as the mature region of the preprotein (22, 23). These binding interactions presumably allow SecA to transfer polypeptide segments to SecYEG. However, the details of the preprotein binding and transfer reactions are not understood, so there is little information on how processivity is achieved in preprotein translocation.

Achieving efficient processive translocation is likely to involve complex interactions between SecA and the preprotein. Experimental evidence for such complexity comes from studies on the interaction of synthetic signal sequence peptides with SecA in different states. The binding of such peptides inhibits the ATPase activity of a 64-kDa N-terminal fragment of SecA with elevated basal activity (19, 21) but stimulates the lipid-activated ATPase activity of intact SecA (17, 18). The different functional consequences of signal peptide interactions in these two assays suggest that SecA interacts with preproteins differently at different stages of its ATP-driven conformational reaction cycle.

Acidic phospholipids are required for efficient SecA-mediated preprotein translocation both in vivo (24) and in vitro (25, 26). SecA inserts into phospholipid monolayers in a reaction that is enhanced by the presence of acidic phospholipids (27). The ability of SecA to interact with the hydrocarbon region of phospholipids in bilayer membranes is also supported by several experiments conducted using vesicles containing acidic phospholipids (26, 28-30). Bilayer destabilizing lipids increase hydrocarbon exposure (29) and accelerate the rate of both preprotein translocation (26) and a conformational change that can be induced in SecA by interaction with vesicles (30). Moreover, SecA can be labeled by lipids containing photoactivatable groups in their hydrocarbon moieties (31, 32) when such probes are incorporated into pure lipid vesicles, although experiments of this kind also indicate that SecA becomes shielded from such interactions when it binds to SecYEG (14, 32).

SecA is believed to form a physiological dimer based on the preponderance of the dimeric form in hydrodynamic assays in vitro (33-35). The monomer-dimer equilibrium is sensitive to temperature and the ionic environment, and the dimer has a tendency to form higher order oligomers as protein concentration is increased (34, 36). Detailed analysis of hydrodynamic data indicates that two different forms of the SecA dimer are present in solution under some circumstances, differing either in their conformation or in the nature of their intersubunit interface (34). Different studies have come to differing conclusions regarding the oligomeric state of SecYEG in the active translocation complex, some supporting its functioning as a monomer (37) but others supporting its functioning as a dimer (38, 39) or a tetramer (40). The possibility that SecYEG has a different oligomeric organization from SecA, combined with the general complexity of the processive protein translocation reaction, has raised the possibility that SecA could change its oligomeric state during the functional translocation cycle (9, 34, 37, 38, 40). However, little evidence has been presented to support this possibility.

The present work shows that phospholipid and signal peptide ligands alter the complex equilibria between monomeric and oligomeric forms of SecA, supporting the possibility that changes in the oligomeric state of SecA could play a functional role in the protein translocation reaction.

    MATERIALS and METHODS
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ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
REFERENCES

Buffers and Reagents-- KET buffer contains 50 mM KCl, 1.0 mM Na-EDTA, 25 mM Tris-Cl, pH 7.6. Phospholipid analogues were purchased from Avanti Polar Lipids (Alabaster, AL) and used without further purification.

Protein Purification-- Escherichia coli SecA variants were purified as described (41). Strains overexpressing the PrlD suppressor mutants were obtained from D. B. Oliver of Wesleyan University.

Signal Peptide Synthesis and Purification-- The KRR-LamB signal peptide (+H3N-MMITLRKRRKLPLAVAVAAGVMSAQAMA-COO-) and the Delta 78 variant (+H3N-MMITLRKRRKLPVAAGVMSAQAMA-COO-) were synthesized and purified as described (13). The concentration of signal peptide in a concentrated stock solution in water was determined using quantitative amino acid analysis (conducted at the W. M. Keck Biopolymer Facility at Yale University). Some wild-type signal peptide preparations had a tendency to generate a precipitate when diluted into KET buffer, complicating fluorescence anisotropy measurements. However, these preparations produced equivalent redimerization of lyso-myristoylphosphatidylglycerol (lyso-MPG)1-bound SecA monomers in sedimentation velocity assays where the precipitate is rapidly cleared from the cell so that it does not interfere with quantitation.

Tryptophan Fluorescence Anisotropy Measurements-- Excitation-corrected emission spectra were measured as described using 297 nm excitation (41). Total fluorescence was monitored at 340 nm, whereas the anisotropy values were averaged in a window from 320 to 380 nm to improve the signal to noise ratio of the data. The anisotropy curves changed uniformly throughout this spectral region and showed no fine structure. Whereas background subtraction was generally performed using spectra collected from a pure buffer sample, a fluorescent contaminant in the dicaproyl phospholipid stocks required protein-free solutions at equivalent phospholipid concentrations to be used for background subtraction of samples containing concentrations of these species in excess of 1 mM (i.e. for the fluorescence experiments summarized in Table II).

Critical Micelle Concentration (CMC) and Micelle Size Measurements-- Detergent CMCs were determined using in situ elastic light-scattering measurements in the fluorimeter. Excitation and emission wavelengths were set to 297 and 298 nm, respectively, and the excitation-corrected 90° light scattering signal was measured as a function of detergent concentration (in KET buffer) using vertical excitation and emission polarizers with a 30-s averaging time for digital photon-counting and 4-nm slits. Linear regressions were used to fit the pre- and post-CMC regions in the plot of light scattering versus detergent concentration, and the CMC was calculated as the point at which these curves intersect. The molecular masses of the lyso-MPG and lyso-myristoylphosphatidylcholine (lyso-MPC) micelles in KET buffer were determined to be 35 and 65 kDa, respectively, from static light scattering and refractive index measurements performed using Dawn EOS and Optilab detectors (Wyatt Inc., Santa Barbara, CA). The details of these experiments will be published elsewhere.

Analytical Ultracentrifugation Measurements-- Sedimentation velocity experiments were performed at 20 °C in KET buffer in a Beckman XL-A centrifuge using an 8-slot rotor at 20,000 rpm. Double-sector Epon centerpieces were used with 420 µl in the sample cell and 440 µl of buffer in the reference cell. Absorbance measurements at 280 nm were taken in 0.002-cm radial steps. Absorbance and refractive index scans were measured from each cell every 8 min over the course of 14 h. Absorbance data were analyzed with the program SEDFIT using the continuous distribution c(S) and c(M) Lamm equation model (42, 43). The partial specific volume of the protein was assumed to be 0.734 ml/g, and the density of the solvent was calculated to be 0.998148 g/ml (44). An ensemble of ~90 scans was used for the final refinement of each c(M) distribution plot. The meniscus was identified by manual inspection and refined during fitting, and the data range was truncated near the bottom of the plateau region in the ensemble of sedimentation curves. The value of the frictional ratio f/f0 was initially assumed to be 1.2 and refined by the program (Table I). S values between ~0.5 and ~18 were considered and divided into 1000 steps. Maximum entropy regularization was used assuming a confidence level of 0.9. All fits yielded a root mean square deviation below 0.1% for the entire ensemble of scans (light gray traces in Fig. 1A).

Evaluation of the Effect of Micelle Binding on Analytical Ultracentrifugation Results-- Data from the sedimentation velocity runs were analyzed using the program SEDFIT (42, 43) as described above assuming 8 evenly spaced values for the overall partial specific volume of the hydrodynamic particle between 0.734 and 0.905 cm3/g. The first value represents the partial specific volume of the protein, whereas the second value represents an upper limit for the partial specific volume of the lyso-MPC and lyso-MPG micelles given the fact that they are more dense than D2O buffer (as evidenced by their observed sedimentation rather than floatation in this environment). The resulting plot of molecular mass versus the assumed partial specific volume of the hydrodynamic particle was empirically fit to a third order polynomial. This equation was used to calculate the total molecular mass of the particle for any given value of its overall partial specific volume (Voverall), as calculated from the assumed values for the phospholipid-to-protein mass ratio in the complex (R) and the partial specific volume of the phospholipid (VPL), as shown in Equation 1.


<A><AC>V</AC><AC>&cjs1171;</AC></A><SUB><UP>overall</UP></SUB>=(R·<A><AC>V</AC><AC>&cjs1171;</AC></A><SUB><UP>PL</UP></SUB>+0.734)/(R+1) (Eq. 1)
The molecular mass of the protein in the complex was then calculated based on the assumed phospholipid-to-protein mass ratio, yielding data of the kind shown in Fig. 1C.

Cross-linking Experiments-- 50 µM (20 °C) or 46 µM (37 °C) SecA (monomer concentration) was preincubated for 10 min in cross-linking buffer (10 mM KCl, 20 mM MgOAc2, 50 mM triethanolamine, pH 7.5) with signal peptides (at a 100 µM concentration) and/or phospholipids (at a 2 mM concentration). Cross-linking was initiated by the addition of 0.1% glutaraldehyde for 5 (20 °C) or 3 (37 °C) min and stopped by adding 2× SDS gel loading buffer and boiling for 3 min. Cross-linked proteins were analyzed by 4% SDS-PAGE and stained with Coomassie Blue.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
REFERENCES

Long-chain Phospholipid Analogues Monomerize the Physiological Dimer of SecA-- Analytical ultracentrifugation (Fig. 1, A-C), fluorescence anisotropy (Fig. 1D), and glutaraldehyde cross-linking (Fig. 2A) experiments show that the physiological dimer of SecA is monomerized by the long-chain phospholipid analogues lyso-MPG or lyso-MPC. Fluorescence anisotropy experiments (Fig. 1D) show that SecA remains a dimer in the presence of equivalent concentrations of short-chain phospholipid analogues with the same head group structures (dicaproylphosphatidylglycerol (DCPG) and dicaproylphosphatidylcholine (DCPC)).


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Fig. 1.   Long-chain phospholipid analogues monomerize the physiological dimer of SecA. The interaction of wild-type E. coli SecA with various water-soluble phospholipid analogues is characterized in KET buffer using analytical ultracentrifugation and tryptophan fluorescence spectroscopy. A, four representative absorbance scans from equivalent time points are shown from sedimentation velocity experiments conducted at 20 °C on 1.0 µM SecA either in the absence (upper panel) or presence (lower panel) of 150 µM lyso-MPG. The gray traces at the bottom of each panel show the curve fitting residuals for the complete ensemble of ~90 absorbance scans used for molecular mass calculations. B, molecular mass distribution c(M) profiles were calculated by SEDFIT (42, 43) from sedimentation velocity experiments like those shown in panel A conducted either in the absence of phospholipid (---) or in the presence of 150 µM lyso-MPG (···) or 150 µM lyso-MPC (- - -). The analysis assumes a partial specific volume of 0.734 cm3/g for all hydrodynamic species. Equivalent results were obtained when the lyso-lipid concentrations were increased to 300 or 500 µM (data not shown). C, systematic analysis of the effect of phospholipid binding to SecA on the molecular mass of the protein as inferred from the sedimentation velocity data. Because neither the partial specific volume of the phospholipid (VPL, expressed in cm3/g) nor the amount of phospholipid bound to SecA is known with certainty, the analysis was performed assuming all reasonable values for these parameters. The graph shows the mass of the protein component of the protein-detergent complex excluding the mass of the bound lipid. See "Materials and Methods" for details of the analysis. The curves for which the partial specific volume of the lipid is not indicated in the figure assumed values of 0.758, 0.783, 0.807, and 0.832 cm3/g. Solid and dashed lines are used in alternation to facilitate visualization. D, titrations of 0.25 µM SecA with lyso-MPG (black-triangle), lyso-MPC (triangle ), DCPG (black-square), or DCPC () were conducted at 24 °C and monitored by tryptophan fluorescence spectroscopy. Steady-state anisotropy is shown in the top panel, whereas relative total fluorescence at 330 nm is shown in the bottom panel. E, thermal titrations of 0.25 µM SecA were conducted in the absence (---) or presence of a 1.0 mM concentration of lyso-MPG (···), lyso-MPC (- - -), DCPG (-·-·-), or DCPC (-··-··-). Reciprocal steady-state anisotropy is shown in the top panel, and relative total fluorescence at 330 nm is shown in the bottom panel. Reciprocal anisotropy is plotted here because of the linear relationship between this parameter and temperature for a particle of constant size and shape as described by the Perin equation (48).


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Fig. 2.   Ligand-dependent changes in chemical cross-linking of SecA. The effects of phospholipid analogues (at 2 mM) and signal peptides (at 100 µM) on the oligomeric state of SecA were analyzed using glutaraldehyde (GA) cross-linking experiments evaluated by SDS-polyacrylamide gel electrophoresis. See "Materials and Methods" for experimental details. A, cross-linking conducted for 5 min at 20 °C. B, cross-linking conducted for 3 min at 37 °C. The cross-linking time was reduced in this experiment because a larger amount of background cross-linking was observed as temperature was increased.

Absorbance scans from sedimentation velocity experiments conducted either in the absence or presence of 150 µM lyso-MPG (Fig. 1A) show an obvious reduction in the sedimentation coefficient of SecA in the presence of this phospholipid analogue. The program SEDFIT was used to fit these data and data from an equivalent experiment conducted in the presence of 150 µM lyso-MPC using the continuous distribution c(S) and c(M) Lamm equation model (42, 43), with results summarized in Table I. The c(M) mass distributions inferred from these analyses (Fig. 1B) indicate that the molecular mass of SecA is reduced by approximately half in the presence of either phospholipid analogue, suggesting that they monomerize the physiological dimer of SecA. Equivalent hydrodynamic results are obtained in the presence of a 300 or 500 µM concentration of either phospholipid analogue (data not shown).

                              
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Table I
Hydrodynamic properties of SecA in the presence of model translocation ligands
Sedimentation velocity experiments were conducted at 20,000 rpm on a Beckman XL-A analytical ultracentrifuge using 1 µM E. coli SecA in KET buffer at 20 °C. Parameters were determined by the program SEDFIT (42,43) based on modeling an ensemble of ~90 absorbance profiles using the Lamm equation. Equivalent sedimentation results were obtained when the concentrations of the lyso-lipids were increased to 300 µM (data not shown). For samples run in the presence of lyso-lipids, protein masses are given assuming that either 0 or 1 micelle is bound to the SecA monomer, for reasonable limiting values of the partial specific volume of the micelle (<A><AC>v</AC><AC>&cjs1171;</AC></A>PL). See "Materials and Methods" for additional details on these experiments and calculations. Static light scattering measurements give molecular masses of 35 and 65 kDa for lyso-MPG and lyso-MPC micelles, respectively, in KET buffer.

Several details of these sedimentation velocity experiments deserve comment. The experiment conducted in the absence of phospholipid confirms that 1 µM E. coli SecA is present primarily in the form of a dimer (33, 34) at room temperature in a buffer containing 50 mM KCl, 1 mM EDTA, 25 mM Tris-Cl, pH 7.5 (Fig. 1B and Table I). Consistent with previous observations (33), a high frictional ratio is observed for this dimer (Table I). Sedimentation velocity analyses of the kind used here give time-averaged molecular masses for hydrodynamic species undergoing rapid equilibration at the sedimentation boundary (42, 43). Therefore, the minority population of SecA monomer observed in Fig. 1B indicates that a small fraction of the SecA molecules are incapable of forming the physiological dimer, probably because of N-terminal proteolysis (36). The molecular mass of the nonexchanging SecA monomer is slightly underestimated in Fig. 1B because a single frictional ratio must be assumed in analyzing the entire ensemble of hydrodynamic species (because of software limitations), and the high value required to model the sedimentation of the dimer apparently overestimates the frictional ratio of the monomer.

Sedimentation velocity experiments conducted on pure phospholipid samples and monitored using refractive index measurements show that the sedimentation of both lyso-MPG and lyso-MPC micelles is substantially slower than that of the SecA monomer under these conditions (data not shown). Therefore, an approximately constant micelle concentration is present in the protein-containing regions of the cell during the sedimentation velocity experiments. Because the phospholipid species have no absorbance at 280 nm, they do not contribute to the optical absorbance profiles used to determine the molecular mass distribution of the protein. Therefore, the hydrodynamic properties of the protein-phospholipid complex can be assessed directly from the sedimentation absorbance profiles even in the presence of the micelles.

However, the c(M) distribution (Fig. 1B) calculated for the complex depends directly on the overall partial specific volume of the hydrodynamic particle (Voverall), which will change depending on how much phospholipid is attached to the protein molecule. To estimate the influence of this effect on the inferred molecular mass distributions, the sedimentation velocity data from the experiments conducted in the presence of phospholipid micelles were reanalyzed assuming varying lipid to protein ratios in the hydrodynamic particles (shown explicitly for lyso-MPG in Fig. 1C and summarized for both phospholipid species in Table I). Because the partial specific volumes of these phospholipid species are not known, this analysis was performed assuming all reasonable values for this parameter. Most phospholipids and detergents have partial specific volumes in the range between 0.85 and 0.89 cm3/g (45-47), but the analysis was performed assuming a considerably broader range of values up to the experimental upper limit of 0.905 cm3/g (see "Materials and Methods") and down to 0.734 cm3/g (i.e. equivalent to the partial specific volume of the protein). This analysis shows that the sedimentation velocity data for SecA in the presence of 150 µM lyso-MPG are inconsistent with the hydrodynamic particle containing anything larger than a SecA monomer (Fig. 1C). Moreover, the calculated molecular mass closely matches that of the SecA monomer for the binding of amounts of lipid ranging from a single lyso-MPG monomer to a complete micelle (which has a molecular mass of 35 kDa) assuming a partial specific volume in the range from 0.85 to 0.90 cm3/g. An equivalent analysis of the sedimentation data obtained in the presence of lyso-MPC yields a similar conclusion (Table II). However, in this case, assuming that a small number of lyso-MPC monomers are bound to the protein gives a molecular mass estimate slightly higher than that of the SecA monomer, whereas a closer match is obtained assuming that one micelle (which has a molecular mass of 65 kDa) is bound to the protein molecule.

                              
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Table II
Efficacy of different detergent species in inducing monomerization of SecA
The monomerization of SecA was assayed at 24 °C in KET buffer using fluorescence anisotropy titrations equivalent to those shown in Fig. 1C (terminating at a phospholipid or detergent concentration above the CMC), and the results were verified using sedimentation velocity experiments equivalent to those reported in Table I. The parameter [detergent]1/2 represents the concentration of detergent giving 50% monomerization and was determined using nonlinear curve fitting of the anisotropy data to a standard cooperative binding equation. The apparent cooperativity was determined using a Hill plot of the data in conjunction with the parameters determined from nonlinear curve fitting. The CMC values were determined in KET buffer in situ in the fluorimeter for all of the detergent and phospholipid species reported here (as described under "Materials and Methods").

Evaluation of the Concentration Dependence of Monomerization Using Fluorescence Anisotropy Spectroscopy-- Steady-state fluorescence anisotropy measurements offer a convenient means to monitor the oligomerization state of a fluorophore-containing protein because of their sensitivity to changes in rotational correlation time (48). The intrinsic tryptophan fluorescence of E. coli SecA can therefore be used to assess the concentration dependence of the monomerization reaction induced by either lyso-MPG or lyso-MPC (triangles in Fig. 1D). A steep quenching in relative total fluorescence (lower panel in Fig. 1D) is observed in the concentration range from 25 to 150 µM when either phospholipid analogue is titrated onto SecA, coinciding approximately with the CMCs of these micelle-forming lyso-lipids (~64 µM for lyso-MPG and 68 µM for lyso-MPC). The observed fluorescence quenching indicates that a protein conformational change occurs upon phospholipid binding (26, 28-30). Because quenching decreases the excited-state lifetime of the fluorophore ensemble, it tends to cause a small increase in fluorescence anisotropy in the absence of a change in the rotational diffusion coefficient of the protein. Instead, a 30% decrease in anisotropy closely parallels the major change in relative total fluorescence in both the lyso-MPG and lyso-MPC titrations (upper panel in Fig. 1D), indicating that a substantial increase in the rotational diffusion coefficient of the protein accompanies the conformational transition. Based on the results of the sedimentation velocity experiments, most of this increase in rotational diffusion rate is attributable to monomerization of the SecA dimer.

A second apparent binding interaction is observed exclusively in the titration with the lyso-MPG micelles in the concentration range from 150 to 200 µM, causing an additional 20% quenching in relative total fluorescence (lower panel in Fig. 1D). However, this second binding event produces a small increase in anisotropy (upper panel in Fig. 1D), which could be caused either by the reduction in the lifetime of the fluorophore ensemble because of the quenching and/or by a slight reduction in the molecular rotation rate because of the binding of a second lyso-MPG micelle to the protein.

Phospholipid-induced Monomerization Is Also Observed in Chemical Cross-linking Experiments-- In the absence of phospholipids, exposure of SecA to 0.1% glutaraldehyde for 5 min at 20 °C yields primarily a covalent dimer when samples are analyzed using SDS-PAGE (lane 5 in Fig. 2A). Addition of either lyso-MPC or lyso-MPG reduces the cross-linking of the protomers and results in the protein running predominantly as a monomer even after glutaraldehyde exposure (lanes 6 and 9 in Fig. 2A).

Similar Total Fluorescence Changes during the Phospholipid-induced Monomerization and the Endothermic Transition of SecA-- Thermal titrations can be used to induce an ATP-modulated endothermic conformational transition in E. coli SecA (8, 28, 49, 50) (Fig. 1E), which produces an increase in the mobility of the alpha -helical wing domain in the protomer but not dissociation of the physiological dimer (41). This transition does produce a decrease in tryptophan anisotropy (i.e. increase in reciprocal anisotropy in the Perin plot (48) in the upper panel of Fig. 1E), but the magnitude of this anisotropy change is significantly smaller than that produced by the phospholipid-induced monomerization reaction (upper panels in Fig. 1, D and E). Nonetheless, the change in relative total fluorescence that takes place during the endothermic conformational transition (20, 28, 50) (lower panel in Fig. 1E) is very similar to the change that takes place during the phospholipid-induced monomerization (lower panel in Fig. 1D), suggesting that there may be similarities in the conformational changes that take place within the SecA protomer in the two cases. Consistent with this possibility, phospholipid-monomerized SecA does not experience any additional change in relative total fluorescence upon subsequent thermal titration (Fig. 1E). Dissection of the contribution of the individual Trp residues in SecA to the fluorescence changes shown in Fig. 1D2 also supports the conclusion that a related conformational change takes place in the protomer during phospholipid-induced monomerization and during the endothermic conformational transition, even though the physiological SecA dimer does not monomerize in the latter case.

Evaluation of Different Phospholipid and Detergent Species for the Ability to Monomerize SecA-- To characterize the chemical features of the phospholipids responsible for monomerizing the physiological dimer of SecA, fluorescence anisotropy titrations were conducted with a variety of different phospholipid and detergent species (Table II). All of the long-chain lyso-lipid species that were tested trigger dissociation of the physiological dimer of SecA, with the concentration producing 50% monomerization being consistently at or slightly below the CMC of the phospholipid species except in the case of lyso-palmitoyl-PC. In contrast, the short-chain diacylphospholipids DCPG and DCPC fail to induce monomerization of SecA at concentrations either below or above their CMCs. Whereas the nonionic detergents beta -octylglucoside, beta -dodecylmaltoside, and C12E8 (octaethylene glycol dodecyl ether) also fail to trigger monomerization at concentrations either below or above their CMCs, lauryl dimethylamineoxide does so at a concentration slightly below its CMC.

Synthetic Signal Peptide Redimerizes Phospholipid-monomerized SecA-- A synthetic analogue of the signal sequence of the LamB outer membrane protein from E. coli has been used as model preprotein substrate in a variety of biochemical and biophysical studies (19). The "KRR-LamB" synthetic signal peptide contains three extra residues (KRR) compared with the original LamB sequence to enhance its solubility, but a modification like this has been demonstrated not to perturb LamB signal sequence function in vivo (13). Sedimentation velocity experiments show that SecA molecules monomerized by the binding of lyso-MPG are redimerized in the presence of 25 µM wild-type KRR-LamB signal peptide (Fig. 3A and Table I). A small population of higher order oligomers is also observed in this experiment, but the dominant hydrodynamic species is a dimer (Fig. 3A and Table I).


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Fig. 3.   Synthetic signal peptide redimerizes phospholipid-monomerized SecA. The experiments were conducted on wild-type E. coli SecA in KET buffer either in the presence or absence of the synthetic KRR-LamB signal sequence peptide (13). A, molecular mass c(M) distribution profiles were calculated by SEDFIT (42, 43) from sedimentation velocity experiments on 1.0 µM SecA in the presence of 150 µM lyso-MPG either without (···) or with 25 µM wild-type KRR-LamB signal peptide (-·-·-). The experiments were performed at 20 °C. Equivalent results were obtained when the lyso-lipid concentration was increased to 300 µM (data not shown). B, after monomerizing 2.0 µM SecA by exposure to 250 µM lyso-MPG, titrations of either wild-type KRR-LamB signal peptide (squares) or the Delta 78 mutant peptide (circles) were monitored using tryptophan fluorescence spectroscopy. Steady-state anisotropy is shown in the top panel, whereas relative total fluorescence at 330 nm is shown in the bottom panel. The arrows indicate the values observed for the physiological dimer of SecA prior to the addition of lyso-MPG. C, Hill plot for the titration of wild-type KRR-LamB signal peptide presented in panel B based on the steady-state anisotropy data.

A significant increase in molecular mass is also observed when 25 µM wild-type KRR-LamB signal peptide is added to SecA molecules monomerized by interaction with lyso-MPC (Table I). In this case, the apparent molecular mass of the complex formed in the presence of the signal peptide is slightly lower than that expected for a protein dimer (~165 kDa versus slightly greater than 200 kDa). This observation suggests that the redimerization of SecA may be incomplete under these conditions. Higher concentrations of signal peptide yield a complex of the same molecular mass (data not shown), indicating that the lack of complete redimerization in lyso-MPC is not because of incomplete saturation of the signal peptide binding site. Therefore, the equilibrium constant for the redimerization of the SecA-signal peptide complex with lyso-MPC appears to be lower than that for the equivalent complex with lyso-MPG.

When the concentration dependence of the redimerization of lyso-MPG-bound SecA by the wild-type KRR-LamB signal peptide is assessed using tryptophan fluorescence anisotropy spectroscopy, a sigmoidal change in fluorescence anisotropy is observed with a Kd of 14 µM (Fig. 3B) and a Hill coefficient of 2 (Fig. 3C), consistent with the occurrence of a cooperative dimerization reaction involving the binding of one signal peptide per monomer. The Delta 78 variant of the KRR-LamB signal peptide contains a 4-residue deletion that has been observed to severely impair the function of the corresponding signal sequence in vivo (51). The specificity of the signal peptide-induced redimerization is demonstrated by the fact that an equivalent titration of lyso-MPG-monomerized SecA with the KRR-LamB-Delta 78 mutant signal peptide produces only minor changes in fluorescence anisotropy (Fig. 3B).

As opposed to the large fluorescence quenching that is observed upon phospholipid-induced monomerization of SecA, only a minimal increase in total fluorescence is observed upon redimerization by the wild-type KRR-LamB peptide (Fig. 3B). Moreover, the anisotropy level of the redimerized protein is lower than that of the physiological dimer prior to phospholipid exposure. Because the binding of the KRR-LamB peptide to the physiological dimer of SecA produces only minimal changes in either total Trp fluorescence (data not shown) or anisotropy (Fig. 4B, below), both of these observations suggest that the conformation of the KRR-LamB-bound SecA dimer formed in the presence of lyso-MPG might differ from that of the original physiological protein dimer.


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Fig. 4.   Synthetic signal peptide induces polymerization of the high temperature domain-dissociated conformation of SecA. Experiments were performed on E. coli SecA in KET buffer. A, molecular mass distribution profiles were calculated by SEDFIT from sedimentation velocity experiments conducted on 1.0 µM wild-type SecA either in the absence (---) or presence of 25 µM wild-type KRR-LamB signal peptide (···). The experiments were performed at 20 °C. B, thermal titrations of 0.25 µM wild-type SecA were monitored using tryptophan fluorescence spectroscopy in the absence of signal peptide (---) or in the presence of a 25 µM concentration of either wild-type KRR-LamB signal peptide (···) or the Delta 78 mutant peptide (-·-·-). Perin plots (48) of reciprocal anisotropy are shown in the top panel, whereas plots of relative total fluorescence at 330 nm are shown in the bottom panel. C, thermal titrations were conducted in the same manner as in panel B on wild-type SecA (---) as well as the Y134C (---), A373V (-·-·-), and A507V (-··-··-) prlD suppressor mutants (52, 53) in the presence of 25 µM wild-type KRR-LamB signal peptide. D, steady-state tryptophan fluorescence anisotropy data showing dissociation of signal peptide-induced SecA polymers specifically by phospholipids producing monomerization of the physiological dimer (i.e. by lyso-MPG above its CMC but not by DCPG). The A373V variant of SecA was heated to 37.5 °C to induce domain dissociation and allowed to equilibrate. This variant was used because the lower temperature of the endothermic transition gives efficient signal peptide-induced polymerization at a reduced temperature. Addition of wild-type KRR-LamB signal peptide (arrows on the left) causes a rapid increase in anisotropy reflecting protein polymerization. After 5 min, phospholipids were added at the indicated concentrations (arrows on the right). To facilitate visualization of the results, an arbitrary offset has been added to the data from the DCPG experiment but not the lyso-MPG experiment. There were minimal changes in the total fluorescence during these experiments other than a small amount of photooxidation (data not shown).

Glutaraldehyde cross-linking experiments support the conclusion that signal peptide binding induces redimerization of SecA molecules monomerized by either lyso-MPG or lyso-MPC, based on the increase in the level of dimer observed when cross-linking is conducted in the presence of the wild-type KRR-LamB signal peptide but not the Delta 78 variant (lanes 6-11 in Fig. 2A).

Conformationally Specific Polymerization of SecA Dimers by Synthetic Signal Peptide-- Addition of 25 µM wild-type KRR-LamB signal peptide to a solution containing physiological dimers of SecA at 20 °C produces only a small increase in the apparent molecular mass of the protein, concomitant with an increase in the width of the molecular mass distribution, as determined by sedimentation velocity measurements (Fig. 4A). Therefore, signal peptide binding to SecA dimers in the compact conformational ground state induces a modest tendency to self-associate (that is also observed in the glutaraldehyde cross-linking experiment in lane 4 in Fig. 2A) but without producing a significant shift of the population into the form of higher order oligomers. Consistent with this conclusion, at most minor changes in total Trp fluorescence (lower panel in Fig. 4B and additional data not shown) or anisotropy (upper panel in Fig. 4B) are observed when 25 µM wild-type KRR-LamB signal peptide is added to SecA at 24 °C (Fig. 4B). However, a precipitous decrease is observed in the Perin plot (48) of reciprocal anisotropy versus temperature when such samples undergo thermal titration (upper panel in Fig. 4B). This increase in Trp fluorescence anisotropy coincides with the onset of the endothermic conformational transition as detected by quenching of total fluorescence (lower panel in Fig. 4B). Based on several lines of evidence, this anisotropy change corresponds to the formation of higher order oligomers by the SecA dimer, indicating that signal peptide induces protein polymerization when it binds to the domain-dissociated conformation adopted by SecA at temperatures above that of the endothermic transition.

The first line of evidence supporting the conformationally specific polymerization of SecA derives from the detailed properties of the observed fluorescence changes. The change in total fluorescence observed in Fig. 4B derives almost entirely from the protein conformational change that occurs during the endothermic transition. When signal peptide is added to SecA samples after first heating them to a temperature high enough to induce the endothermic transition, the strong increase in anisotropy occurs in the absence of any significant change in total fluorescence (data not shown), establishing that the anisotropy change does not derive from an alteration in fluorescence lifetime and must instead derive from an increase in the rotational correlation time of the Trp ensemble (48). Theoretically, this increase could be caused either by a protein conformational change leading to slower rotation of the physiological dimer or by formation of higher order oligomers of SecA, which would rotate more slowly than the physiological dimer. However, the large change in rotational correlation time required to produce the observed 60% increase in anisotropy seems unlikely to derive from a conformational change and much more likely to derive from higher order oligomerization. This conclusion is supported by the observation of detectable turbidity indicative of light scattering in the samples exposed to elevated temperature in the presence of signal peptide but not in those exposed to the same temperature in the absence of signal peptide (data not shown). Light scattering requires the presence of particles that are large compared with the wavelength of visible light and therefore indicates the formation of higher order protein complexes. This conclusion is also supported by cross-linking experiments, which yield primarily dimer when WT SecA is exposed to glutaraldehyde at 37 °C in the absence of signal peptide but high molecular weight species that do not enter the gel when cross-linking is performed in the presence of the wild-type KRR-LamB signal peptide at the same temperature (lanes 2-4 in Fig. 2B). Finally, the polymerization of domain-dissociated SecA in the presence of signal peptide is also supported by analytical ultracentrifugation experiments, which show continued steady progression of the sedimentation boundary in SecA samples at 37 °C but rapid clearance of the protein from the sample cell at the same temperature in the presence of signal peptide (data not show), indicating the formation of large protein complexes.

When thermal titration of SecA is conducted in the presence of an equivalent concentration of the KRR-LamB-Delta 78 mutant signal peptide, polymerization is still observed but only at substantially higher temperatures than with the wild-type signal peptide (Fig. 4B). There is a latent kinetic component in thermal titrations of this kind, so that the higher temperature at which the major change in anisotropy is observed could reflect slower and less efficient polymerization of SecA by the mutant compared with wild-type signal peptide. The ability of SecA to mediate processive preprotein transport suggests that its binding site for transport substrate is capable of recognizing and binding a great diversity of polypeptide sequences. In this context, some degree of interaction between SecA and a mutated signal peptide is not surprising. Tighter binding of wild-type signal sequences to the polypeptide transport site of SecA could help ensure efficient initiation of preprotein translocation.

Because SecA retains a dimeric structure during the endothermic transition (41), the polymerization reaction indicates that an additional intersubunit interface is likely to be formed between protomers when they bind signal peptide in the domain-dissociated conformation. The formation of an equivalent interface between phospholipid-bound SecA monomers could be responsible for their signal peptide-dependent dimerization given the evidence discussed above for the related conformational properties of the SecA protomer following either phospholipid-induced monomerization or endothermic domain dissociation combined with the evidence for possible conformational differences between the physiological dimer and signal peptide-redimerized SecA.

The Effect of prlD Mutations in SecA on Signal Peptide-induced Polymerization-- PrlD mutations in SecA are selected based on their ability to suppress secretion defects caused by mutations in the signal sequence of a preprotein in vivo (52, 53). These alleles generally facilitate the endothermic conformational transition of SecA and shift its Tm to lower temperature (50). When thermal titrations are conducted on a series of prlD alleles of SecA in the presence of 25 µM wild-type KRR-LamB signal peptide, the onset of the polymerization reaction moves to lower temperature, tracking the onset of the endothermic conformational transition in each allele as monitored by total fluorescence spectroscopy (Fig. 4C). This correspondence establishes that the polymerization reaction is controlled by the conformational state of SecA rather than deriving from the thermodynamic properties of the signal peptide itself. When thermal titrations of this set of SecA variants are conducted in the presence of the KRR-LamB-Delta 78 mutant signal peptide, the prlD alleles also shift the polymerization reaction to lower temperature so that its thermal dependence more closely resembles that of wild-type SecA with wild-type signal peptide (data not shown). Therefore, the prlD alleles enhance the efficiency of the interaction of SecA with a defective signal peptide in this in vitro assay.

Lyso-lipids Reverse the Signal Peptide-induced Polymerization of SecA-- To verify that the signal peptide-induced polymerization does not represent some form of irreversible aggregation, the ability of different lipid species to reverse the polymerization was evaluated using steady-state tryptophan fluorescence anisotropy experiments (Fig. 4D). After heating a SecA sample to a temperature high enough to induce the endothermic conformational transition and domain dissociation, the addition of wild-type KRR-LamB signal peptide causes a rapid increase in anisotropy indicating polymerization (arrows on the left in Fig. 4D). Addition of a 250 µM sub-CMC concentration of DCPG produces no change in Trp anisotropy (arrow on the right in the upper trace in Fig. 4D). However, addition of an equal concentration of lyso-MPG, which is above its CMC, reduces the anisotropy to a similar level to that observed prior to signal peptide addition (arrow on the right in the lower trace in Fig. 4D), consistent with reversion to a dimeric form. Thus, dissociation of the signal peptide-induced polymers is achieved by introduction of a phospholipid species at a concentration that induces monomerization of the physiological dimer of SecA, but not by the introduction of an equivalent concentration of a phospholipid species with the same head group structure and similar hydrocarbon content that is not capable of monomerizing SecA. Additional experiments show that the anisotropy level of signal peptide-induced SecA polymers is reduced by the introduction of lyso-MPC at a concentration above its CMC that induces monomerization of SecA but not by an equivalent concentration of DCPC that does not induce monomerization (data not shown). However, whereas lyso-MPC fully reverses modest signal peptide-induced anisotropy changes (reflecting lower degrees of polymerization), it only partially reverses stronger anisotropy changes of the kind shown in Fig. 4D. Therefore, the lyso-PG species seems to be somewhat more effective that the lyso-PC species in mediating SecA subunit dissociation under these conditions.

Glutaraldehyde cross-linking experiments yield similar results, showing reversal of the signal peptide-induced polymerization of SecA by lipids specifically when they are used under conditions that induce monomerization of the physiological dimer. A 2 mM concentration of lyso-MPG that is above the threshold required to induce monomerization produces a strong increase in the amount of monomeric SecA entering the gel, whereas an equivalent concentration of DCPG that does not induce monomerization has little effect on the signal peptide-induced polymerization (lanes 5 and 6 in Fig. 2B). The failure to obtain glutaraldehyde cross-linked dimers in this experiment in the presence of lyso-MPG and signal peptide, even though such dimers were observed after glutaraldehyde cross-linking in the presence of these ligands at 20 °C (lane 7 in Fig. 2A), must be attributable to the different conditions used in this experiment (i.e. either the higher temperature or the shorter cross-linking time). However, the efficient cross-linking of the physiological dimer under identical solution conditions (lane 3 in Fig. 2B) provides further evidence that there are differences in the structure of the intersubunit interface in the SecA dimer when both lyso-MPG and signal peptide are bound.

The reversibility of the signal peptide-induced polymerization of SecA makes it unlikely that this phenomenon is caused by protein aggregation. The data showing that this reversal only occurs when phospholipid analogues are used under conditions that produce monomerization of the physiological dimer of SecA reinforce this conclusion.

    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
REFERENCES

The SecA translocation ATPase is know to have complex oligomeric behavior in aqueous solutions (33-36). Although a dimer is the predominant species present in purified SecA samples in the absence of other proteins, the protein has a tendency to form higher order oligomers or dissociate into monomers that depends on protein concentration, temperature, and the composition of the buffer. In this paper, we show that ligands that will be encountered by SecA in the course of protein translocation strongly modulate its oligomeric behavior.

The protein translocation reaction is believed to be initiated by the binding of SecA to the N-terminal signal peptide that targets proteins for export from the cytoplasm (6, 9, 12-21). Because the signal peptide is cleaved by a protease with a periplasmic active site, at least its C-terminal region must be translocated across the cytoplasmic membrane, a process that presumably occurs when SecA binds to SecYEG. The data presented in this paper show that signal peptide binding tends to produce oligomerization of SecA in a manner that is modulated by the conformational state of the protein, with the tendency being weak in the conformational ground state but strongly enhanced in the high temperature domain-dissociated state (8, 28, 41, 49, 50) of the physiological dimer or after monomerization by lyso-lipids. In this context, changes in oligomeric interactions could occur at specific steps in the conformational reaction cycle of the SecA-SecYEG complex (1-9) in a manner controlled by the presence or absence of the preprotein transport substrate. The results presented in this paper therefore raise the possibility that ligand-triggered changes in oligomeric interactions between SecA protomers may play a role in the complex dynamics of the preprotein translocation reaction (9, 10).

SecA appears to be shielded from the hydrophobic region of the bilayer when stably inserted into SecYEG (14, 32). However, it does interact directly with phospholipid bilayers including their hydrophobic cores in the absence of SecYEG (27). The ability of SecA to interact with the hydrocarbon region of phospholipids in bilayer membranes is also supported by several experiments conducted using vesicles containing acidic phospholipids (26, 28-30), and these interactions are enhanced (28) in the high temperature domain-dissociated conformation that is the product of the endothermic conformational transition in SecA. Because preprotein translocation requires cycles of SecA insertion and retraction from SecYEG (1-5), SecA will not be stably inserted into SecYEG at all stages of the productive translocation cycle. When it is retracted from SecYEG, SecA could interact directly with the phospholipid bilayer, which would then have the opportunity to drive conformationally specific changes in SecA that could contribute to a carefully controlled progression of the overall conformational reaction cycle. Such interactions could account for the acceleration in the rate of preprotein translocation in the presence of bilayer destabilizing lipids (26), which increase the solvent exposure of the hydrocarbon moieties of the phospholipids (29).

The monomerization of SecA by certain phospholipid and detergent species that is established in this paper is of uncertain physiological relevance. We believe that monomerization is mediated by the interaction of SecA with hydrophobic moieties exposed on the surface of the micelles formed by the active species. Because DCPG and DCPC fail to induce monomerization of SecA even at super-CMC up to 35 mM, the phospholipid head groups cannot be responsible for inducing the monomerization of SecA. Whereas lauryl dimethylamineoxide induces monomerization of SecA, two other detergents with equivalent 12-carbon aliphatic chains (beta -dodecylmaltoside and C12E8) do not, indicating that having a hydrocarbon chain of a given length is not sufficient for an amphiphile to be active. Whereas this pattern could be attributable to a complex interplay of requirements for head group and hydrocarbon structures, it could also be explained by requirements for the physiochemical properties of the micelle formed by the amphiphile.

Based on two lines of evidence, the active species responsible for subunit dissociation in SecA are likely to be micelles and/or proto-micellar aggregates. First, there is a strong correlation between the CMC of the amphiphile and the concentration required to produce monomerization of SecA (Table II), which is readily explained if some kind of micellar aggregate is the active species. Second, the apparent cooperativity of the monomerization reaction varies from ~3 to ~8 for the different active species (Table II). This number gives the minimum number of amphiphile molecules bound during the reaction (54), so the data indicate that more than one amphiphile molecule per monomer is required to drive monomerization in all cases. Whereas these data do not exclude the possibility that a small but variable number of molecules could drive the monomerization of SecA for the different amphiphiles, they could also be explained based on variations in the apparent cooperativity of the micellization reaction (55-57) for the different amphiphiles if micelle formation is involved in driving monomerization. In the case of a micelle containing a large number of monomers (as is the case for all of the species examined here), an ideal micellization process would involve a very high degree of cooperativity associated with the formation of micelles starting at the CMC. However, high sensitivity titration calorimetry studies show that real micellization reactions show very substantial deviations from ideality (55-59), including the formation of protomicellar aggregates of heterogeneous structure at concentrations in the vicinity of the nominal CMC (i.e. both below and above it). Because of these species, the apparent cooperativity of the micellization process is generally considerably lower than the aggregation number of the micelle (55-57) and can be in the range observed for the apparent cooperativity of the monomerization of SecA by the different amphiphiles (Table II). Monomerization of SecA by protomicellar aggregates formed at concentrations below the CMC could therefore explain the results observed with lyso-lauryl-PC and lauryl dimethylamineoxide, which trigger the dissociation reaction with different apparent cooperativities at slightly sub-CMC concentrations.

The calorimetric studies indicate that the protomicellar aggregates formed near the CMC expose more hydrocarbon to the aqueous environment than the fully formed micelles present at limiting concentrations above the CMC (55, 57, 58). The likelihood that such species are involved in inducing the monomerization of SecA by some of the amphiphiles suggests that surface exposure of hydrocarbon groups on the aggregates could be an important molecular parameter in mediating the effect. In this context, it is noteworthy that the nonionic detergents that fail to induce monomerization have comparatively larger head groups that will tend to shield the hydrocarbon chains more thoroughly in the corresponding micelles, giving further support to the hypothesis that the level of static or dynamic exposure of hydrophobic moieties on the surface of the micelle could potentially be a critical parameter in determining the efficacy of the species in driving monomerization of SecA.

This requirement would echo the activity of bilayer-destabilizing phospholipids in stimulating the conformational reaction cycle of SecA (26, 29). Therefore, the micelle-induced monomerization of SecA characterized in this article might reflect what happens to SecA when interacting with destabilized regions of the phospholipid bilayer between successive rounds of insertion into SecYEG. Thus, the ability of certain phospholipid and detergent micelles to drive subunit dissociation of SecA could reflect the ability of phospholipid membranes in the correct microenvironment to drive changes in the interactions between SecA protomers at a specific stage of its conformational reaction cycle when engaged with SecYEG. If this hypothesis is correct, oligomeric interactions of SecA could be reciprocally controlled by signal peptide interaction and phospholipid interaction at different stages of the translocation cycle.

Each cycle of ATP-dependent binding and release of SecA from the SecYEG translocon is believed to drive the translocation of about 40 residues of preprotein (11). Therefore, to achieve processive translocation of an entire preprotein, there must be some mechanism by which the translocation of each successive 40-residue polypeptide segment is efficiently coordinated (10). It is possible that a single SecA dimer could re-bind to C-terminal segments of a translocating preprotein molecule following delivery of an N-terminal segment of the same preprotein to SecYEG. In this case, the probability of rebinding to a proximal segment of the preprotein could be enhanced by keeping SecA partially bound to SecYEG between the pumping cycles. However, the data presented in this paper raise the possibility that processivity could be achieved using a different mechanism. The observation of conformationally specific, signal peptide-dependent higher order oligomerization of SecA suggests that a SecA protomer with bound preprotein could recruit additional SecA molecules to mediate translocation of the C-terminal segments of the same preprotein molecule. Subunit recruitment would likely be temporally coupled to the delivery of the currently bound preprotein segment to the translocon because entry into the high temperature domain dissociated conformation where subunit recruitment occurs is likely to gate the binding of SecA to SecYEG (20, 50, 60). The phospholipid-induced monomerization of SecA reported in this paper could then mediate subunit release and recycling.

The tandem motor domains in SecA bear some sequence homology (61) and strong structural homology (8, 41) to those in ATP-dependent superfamily I and II helicases, with the closest relationship being observed with the DEAD-box family of RNA helicases (62, 63). These enzymes mediate the processive unwinding of nucleic acid duplexes, and two competing models have been advanced to explain how processivity is achieved in this reaction. The "inchworm" model proposes that unwinding is mediated by the unidirectional translation of a helicase protomer along a single strand of a nucleic acid polymer, which pushes the duplex open at its leading edge (64, 65). The "rolling" model proposes that unwinding is mediated when one protomer bound to a single-stranded segment of the nucleic acid polymer recruits a second protomer to bind to the upstream segment of the strand in an equivalent manner, thereby stabilizing it in the single-stranded state (66-68). The first model assumes that a helicase monomer is the functionally active species, whereas the second model assumes that oligomerization plays a fundamental role in mediating processivity. Proponents of the inchworm model cite a 1-base displacement of a bound oligonucleotide observed in comparing nucleotide-free and ATP-bound structures of the PcrA superfamily I helicase (64). They also point out that no consistent pattern of oligomerization has been observed in the existing helicase crystal structures, including multiple representatives from both superfamilies I and II (65, 69). Proponents of the rolling model cite the fact that both the Rep (68) and NS3 (70) helicases have both been shown to dimerize upon binding specific substrate DNA structures and therefore in a conformationally specific manner. The results presented in this paper suggest that SecA could achieve processivity in polypeptide transport using a subunit recruitment mechanism similar to that invoked in the rolling model for the mechanism of the structurally homologous ATP-dependent helicases.

While this paper was under review, Or et al. (71) reported related results. In that work, chemical cross-linking and fluorescence resonance energy transfer results were presented showing that the physiological dimer of E. coli SecA is dissociated by interaction with phospholipids and some analogues. These results are mostly consistent with the results reported here. However, Or et al. (71) also presented chemical cross-linking data suggesting that SecA monomerizes upon binding the KRR-LamB signal peptide, directly contrary to the results reported here. This discrepancy could possibly reflect differences in the behavior of SecA in the cross-linking buffer used by these authors, although consistent behavior is observed in our fluorescence and cross-linking experiments despite the fact that there are greater differences in the compositions of the buffers used in these experiments. On the other hand, the intersubunit cross-linking efficiency is very low in the SecA dimer in the experiments reported by Or et al. (71), and its reduction in the presence of signal peptide could potentially be explained by effects unrelated to a change in the oligomeric state of SecA. For instance, a protein conformational change upon signal peptide binding could reduce the efficiency of the cross-linking reaction even in the absence of dissociation of the physiological dimer.

Or et al. (71) also reported isolation of a mutant form of E. coli SecA with a strongly reduced tendency to form the physiological dimer. Based on the fact that this variant retains a small fraction of the activity exhibited by the wild-type protein in an in vitro preprotein translocation assay, they argue that SecA is likely to function fundamentally as a monomer and to use an inchworm mechanism to mediate processivity in preprotein transport (71). However, they do not characterize the quantitative change in the equilibrium constant for dimerization so that some degree of dimerization of this variant is still possible at specific stages of the transport reaction. Furthermore, it is unclear whether the in vitro assay employed in their studies would be sensitive to defects in the processivity of the SecA-mediated component of the preprotein translocation reaction, which is coupled jointly to the ATPase activity of SecA and also to the proton-motive force (7) (in the absence of uncoupling reagents that block the formation of transmembrane electrochemical potential gradients). Most importantly, the monomeric variant of SecA exhibits only a few percent of the protein translocation mediated by wild-type dimers under equivalent conditions with wild-type SecYEG, suggesting to us that the reduced ability to form the physiological dimer could be causing a severe defect in translocation activity. In this context, we believe that additional studies will be required to determine whether subunit recruitment plays a role in mediating processivity in preprotein transport.

    ACKNOWLEDGEMENTS

We thank D. B. Oliver for providing the prlD mutants of SecA, J. E. Gouaux and R. Olson for access to the analytical ultracentrifuge and advice on its use, and M. Crawford of Yale University for performing quantitative amino acid analyses.

    FOOTNOTES

* This work was supported by National Institutes of Health Grants GM58549 (to J. F. H.) and GM34962 (to L. M. G.), a startup grant from Columbia University (to J. F. H.), and a long-term postdoctoral fellowship from the European Molecular Biology Organization (to J. B.). The Columbia analytical ultracentrifuge facility was supported by National Institutes of Health shared equipment Grant S10RR12848.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.

§ These authors contributed equally to the results reported in this paper.

|| To whom correspondence should be addressed. Tel.: 212-854-5443; Fax: 212-865-8246; E-mail: hunt@sid.bio.columbia.edu.

Published, JBC Papers in Press, October 27, 2002, DOI 10.1074/jbc.M205992200

2 J. J. Fak, A. Itkin, D. D. Nicolae, C. M. Golsaz, and J. F. Hunt, manuscript in preparation.

    ABBREVIATIONS

The abbreviations used are: lyso-MPG, lyso-myristoylphosphatidylglycerol; lyso-MPC, lyso-myristoylphosphatidylcholine; CMC, critical micelle concentration; DCPG, dicaproylphosphatidylglycerol; DCPC, dicaproylphosphatidylcholine.

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ABSTRACT
INTRODUCTION
MATERIALS and METHODS
RESULTS
DISCUSSION
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