Integration of SecA protein into the Escherichia coli inner membrane is regulated by its amino-terminal ATP-binding domain

Binding of SecA ATPase monomers and dimers to lipid vesicles

The Escherichia coli SecA ATPase motor protein is essential for secretion of proteins through the SecYEG translocon into the periplasmic space. Its function relies upon interactions with the surrounding lipid bilayer as well as SecYEG translocon. That negatively charged lipids are required for bilayer binding has been known for >25 years, but little systematic quantitative data is available. We have carried out an extensive investigation of SecA partitioning into large unilamellar vesicles (LUV) using a wide range of lipid and electrolyte compositions, including the principal cytoplasmic salt of E. coli, potassium glutamate, which we have shown stabilizes SecA. The water-to-bilayer transfer free energy is about -7.5 kcal mol^-1 for typical E. coli lipid compositions. Although it has been established that SecA is dimeric in the cytoplasm, we find that the most widely cited dimer form (PDB 1M6N) binds only weakly to LUVs formed from E. coli lipids.

The dispensability and requirement of SecA N-terminal aminoacyl residues for complementation, membrane binding, lipid-specific domains and channel activities

SecA is an essential multifunctional protein for the translocation of proteins across bacterial membranes. Though SecA is known to function in the membrane, the detailed mechanism for this process remains unclear. In this study we constructed a series of SecA N-terminal deletions and identified two specific domains crucial for initial SecA/membrane interactions. The first small helix, the linker and part of the second helix (Δ2-22) were found to be dispensable for SecA activity in complementing the growth of a SecA ts mutant. However, deletions of N-terminal aminoacyl residues 23-25 resulted in severe progressive retardation of growth. Moreover, a decrease of SecA activity caused by N-terminal deletions correlated to the loss of SecA membrane binding, formation of lipid-specific domains and channel activity. All together, the results indicate that the N-terminal aminoacyl residues 23-25 play a critical role for SecA binding to membranes and that the N-terminal limit of SecA for activity is at the 25th amino acid.

SecAAA trimer is fully functional as SecAA dimer in the membrane: existence of higher oligomers?

SecA is an essential ATPase in bacterial Sec-dependent protein translocation pathway, and equilibrates between monomers and dimers in solution. The question of whether SecA functions as monomers or dimers in membranes during the protein translocation is controversial. We previously constructed a tail-to-head SecAA tandem dimer, and showed it is fully functional by complementation in vivo and protein translocation in vitro, indicating that SecA can function at least as a dimer in the membrane without dissociating into monomers. In this study, we further constructed genetically a tail-to-head SecAAA trimer, which is functional in complementing a temperature-sensitive secA mutant. The purified SecAAA trimer per protomer is fully active as SecAA tandem dimers in ATPase activity, in protein translocation in vitro and in ion channel activities in the oocytes. With these functional tail-to-head trimer SecAAA and tandem SecAA, we examined their surface topology in the presence of liposomes using AFM. As expected, the soluble SecAAA without lipids are larger than SecAA. However, the ring/pore structures of SecAAA trimers were, surprisingly, almost identical to the SecA 2-monomers and SecAA dimers, raising the intriguing possibility that the SecA may exist and function as hexamer ring-structures in membranes. Cross-linking with formaldehyde showed that SecA, SecAA and SecAAA could form larger oligomers, including the hexamers. The molecular modeling simulation shows that both tail-to-head and tail-to-tail hexamers in the membranes are possible.

In vivo membrane topology of Escherichia coli SecA ATPase reveals extensive periplasmic exposure of multiple functionally important domains clustering on one face of SecA

The Sec-dependent protein translocation pathway promotes the transport of proteins into or across the bacterial plasma membrane. SecA ATPase has been shown to be a nanomotor that associates with its protein cargo as well as the SecYEG channel complex and to undergo ATP-driven cycles of membrane insertion and retraction that promote stepwise protein translocation. Previous studies have shown that both the 65-kDa N-domain and 30-kDa C-domain of SecA appear to undergo such membrane cycling. In the present study we performed in vivo sulfhydryl labeling of an extensive collection of monocysteine secA mutants under topologically specific conditions to identify regions of SecA that are accessible to the trans side of the membrane in its membrane-integrated state. Our results show that distinct regions of five of six SecA domains were labeled under these conditions, and such labeling clusters to a single face of the SecA structure. Our results demarcate an extensive face of SecA that interacts with SecYEG and is in fluid contact with the protein-conducting channel. The observed domain-specific labeling patterns should also provide important constraints on model building efforts in this dynamic system.

Membrane binding of the bacterial signal recognition particle receptor involves two distinct binding sites

Cotranslational protein targeting in bacteria is mediated by the signal recognition particle (SRP) and FtsY, the bacterial SRP receptor (SR). FtsY is homologous to the SRα subunit of eukaryotes, which is tethered to the membrane via its interaction with the membrane-integral SRβ subunit. Despite the lack of a membrane-anchoring subunit, 30% of FtsY in Escherichia coli are found stably associated with the cytoplasmic membrane. However, the mechanisms that are involved in this membrane association are only poorly understood. Our data indicate that membrane association of FtsY involves two distinct binding sites and that binding to both sites is stabilized by blocking its GTPase activity. Binding to the first site requires only the NG-domain of FtsY and confers protease protection to FtsY. Importantly, the SecY translocon provides the second binding site, to which FtsY binds to form a carbonate-resistant 400-kD FtsY–SecY translocon complex. This interaction is stabilized by the N-terminal A-domain of FtsY, which probably serves as a transient lipid anchor.

Probing the affinity of SecA for signal peptide in different environments

SecA, the peripheral subunit of the Escherichia coli preprotein translocase, interacts with a number of ligands during export, including signal peptides, membrane phospholipids, and nucleotides. Using fluorescence resonance energy transfer (FRET), we studied the interactions of wild-type (WT) and mutant SecAs with IAEDANS-labeled signal peptide, and how these interactions are modified in the presence of other transport ligands. We find that residues on the third alpha-helix in the preprotein cross-linking domain (PPXD) are important for the interaction of SecA and signal peptide. For SecA in aqueous solution, saturation binding data using FRET analysis fit a single-site binding model and yielded a Kd of 2.4 microM. FRET is inhibited for SecA in lipid vesicles relative to that in aqueous solution at a low signal peptide concentration. The sigmoidal nature of the binding curve suggests that SecA in lipids has two conformational states; our results do not support different oligomeric states of SecA. Using native gel electrophoresis, we establish signal peptide-induced SecA monomerization in both aqueous solution and lipid vesicles. Whereas the affinity of SecA for signal peptide in an aqueous environment is unaffected by temperature or the presence of nucleotides, in lipids the affinity decreases in the presence of ADP or AMP-PCP but increases at higher temperature. The latter finding is consistent with SecA existing in an elongated form while inserting the signal peptide into membranes.

Dimeric SecA is essential for protein translocation

SecA facilitates bacterial protein translocation by its association with presecretory or membrane proteins and the SecYEG translocon channel. Once assembled, SecA ATPase undergoes cycles of membrane insertion and retraction at SecYEG that drive protein translocation in a stepwise fashion. SecA exists in equilibrium between a monomer and dimer, and association with its translocation ligands shifts this equilibrium dramatically. Here, we examined the proposal that protein translocation can occur by means of a SecA monomer. We produced a mutant SecA protein lacking residues 2-11, which was found to exist mostly as a monomer, and it was unable to complement a conditional-lethal secA mutant, was inactive for in vitro protein translocation, and was poorly active for translocation ATPase activity. Furthermore, we developed a technique termed membrane trapping, where wild-type SecA subunits became trapped within the membrane by overproduction of membrane-stuck mutant SecA proteins, and, in one case, a membrane-associated SecA heterodimer was demonstrated. Finally, we examined both endogenous and reconstituted membrane-bound SecA and found a significant level of SecA dimer in both cases, as assessed by chemical crosslinking. Collectively, our results strongly suggest that membrane-bound SecA dimer is critical for the protein translocation cycle, although these results cannot exclude participation of SecA monomer at some stage in the translocation process. Our findings have important implications regarding SecA motor function and translocon assembly and activation.

Conformational State of the SecYEG-Bound SecA Probed by Single Tryptophan Fluorescence Spectroscopy

The SecYEG complex is a membrane-embedded channel that permits the passage of precursor proteins (preproteins) across the inner membrane of Escherichia coli. SecA is a molecular motor that associates with the SecYEG pore and drives the stepwise translocation of preproteins across the membrane through multiple cycles of ATP binding and hydrolysis. We have investigated the conformational state of soluble and SecYEG-bound SecA using single tryptophan mutants of SecA. The fluorescence spectral properties of the single tryptophans of SecA and their accessibility to the quencher acrylamide demonstrate that SecA undergoes a conformational change that results in a more compact structure upon binding of ATP and binding to the SecYEG pore. In addition, SecYEG-bound SecA undergoes ATP-dependent conformational changes that are not observed for soluble SecA. These data support a model in which binding to the SecYEG channel has a major impact on the SecA conformation.

Role of a conserved glutamate residue in the Escherichia coli SecA ATPase mechanism

Escherichia coli SecA uses ATP to drive the transport of proteins across cell membranes. Glutamate 210 in the "DEVD" Walker B motif of the SecA ATP-binding site has been proposed as the catalytic base for ATP hydrolysis (Hunt, J. F., Weinkauf, S., Henry, L., Fak, J. J., McNicholas, P., Oliver, D. B., and Deisenhofer, J. (2002) Science 297, 2018-2026). Consistent with this hypothesis, we find that mutation of glutamate 210 to aspartate results in a 90-fold reduction of the ATP hydrolysis rate compared with wild type SecA, 0.3 s(-1) versus 27 s(-1), respectively. SecA-E210D also releases ADP at a slower rate compared with wild type SecA, suggesting that in addition to serving as the catalytic base, glutamate 210 might aid turnover as well. Our results contradict an earlier report that proposed aspartate 133 as the catalytic base (Sato, K., Mori, H., Yoshida, M., and Mizushima, S. (1996) J. Biol. Chem. 271, 17439-17444). Re-evaluation of the SecA-D133N mutant used in that study confirms its loss of ATPase and membrane translocation activities, but surprisingly, the analogous SecA-D133A mutant retains full activity, revealing that this residue does not play a key role in catalysis.

Nucleotide exchange from the high-affinity ATP-binding site in SecA is the rate-limiting step in the ATPase cycle of the soluble enzyme and occurs through a specialized conformational state

We have characterized the kinetic and thermodynamic consequences of adenine nucleotide interaction with the low-affinity and high-affinity nucleotide-binding sites in free SecA. ATP binds to the hydrolytically active high-affinity site approximately 3-fold more slowly than ADP when SecA is in its conformational ground state, suggesting that ATP binding probably occurs when the enzyme is in another conformational state during the productive ATPase/transport cycle. The steady-state ATP hydrolysis rate is equivalent to the rate of ADP release from the high-affinity site under a number of conditions, indicating that this process is the rate-limiting step in the ATPase cycle of the free enzyme. Because efficient protein translocation requires at least a 100-fold acceleration in the ATPase rate, the rate-limiting process of ADP release from the high-affinity site is likely to play a controlling role in the conformational reaction cycle of SecA. This release process involves a large enthalpy of activation, suggesting that it involves a protein conformational change, and two observations indicate that this conformational change is different from the well-characterized endothermic conformational transition believed to gate the binding of SecA to SecYEG. First, nucleotide binding to the low-affinity site strongly inhibits the endothermic transition but does not reduce the rate of ADP release. Second, removal of Mg(2+) from an allosteric binding site on SecA does not perturb the endothermic transition but produces a 10-fold acceleration in the rate of ADP release. These divergent effects suggest that a specialized conformational transition mediates the rate-limiting ADP-release process in SecA. Finally, ADP, 2'-O-(N-methylanthraniloyl)-adenosine-5'-diphosphate (MANT-ADP), and adenosine 5'-O-(3-thiotriphosphate) (ATP-gamma-S) bind with similar affinities to the high-affinity site and also to the low-affinity site as inferred from their consistent effects in inhibiting the endothermic transition. In contrast, adenosine 5'-(beta,gamma-imino)triphosphate (AMPPNP) shows 100-fold weaker affinity than ADP for the high-affinity site and no detectable interaction with the low-affinity site at concentrations up to 1 mM, suggesting that this nonhydrolyzable analogue may not be a faithful mimic of ATP in its interactions with SecA.

Ring-like pore structures of SecA: implication for bacterial protein-conducting channels

SecA, an essential component of the general protein secretion pathway of bacteria, is present in Escherichia coli as soluble and membrane-integral forms. Here we show by electron microscopy that SecA assumes two characteristic forms in the presence of phospholipid monolayers: dumbbell-shaped elongated structures and ring-like pore structures. The ring-like pore structures with diameters of 8 nm and holes of 2 nm are found only in the presence of anionic phospholipids. These ring-like pore structures with larger 3- to 6-nm holes (without staining) were also observed by atomic force microscopic examination. They do not form in solution or in the presence of uncharged phosphatidylcholine. These ring-like phospholipid-induced pore-structures may form the core of bacterial protein-conducting channels through bacterial membranes.

Nucleotide control of interdomain interactions in the conformational reaction cycle of SecA

The SecA adenosine triphosphatase (ATPase) mediates extrusion of the amino termini of secreted proteins from the eubacterial cytosol based on cycles of reversible binding to the SecYEG translocon. We have determined the crystal structure of SecA with and without magnesium-adenosine diphosphate bound to the high-affinity ATPase site at 3.0 and 2.7 angstrom resolution, respectively. Candidate sites for preprotein binding are located on a surface containing the SecA epitopes exposed to the periplasm upon binding to SecYEG and are thus positioned to deliver preprotein to SecYEG. Comparisons with structurally related ATPases, including superfamily I and II ATP-dependent helicases, suggest that the interaction geometry of the tandem motor domains in SecA is modulated by nucleotide binding, which is shown by fluorescence anisotropy experiments to reverse an endothermic domain-dissociation reaction hypothesized to gate binding to SecYEG.

Escherichia coli SecA helicase activity is not required in vivo for efficient protein translocation or autogenous regulation

SecA is an essential ATP-driven motor protein that binds to preproteins and the translocon to promote protein translocation across the eubacterial plasma membrane. Escherichia coli SecA contains seven conserved motifs characteristic of superfamily II of DNA and RNA helicases, and it has been shown previously to possess RNA helicase activity. SecA has also been shown to be an autogenous repressor that binds to its translation initiation region on secM-secA mRNA, thereby blocking and dissociating 30 S ribosomal subunits. Here we show that SecA is an ATP-dependent helicase that unwinds a mimic of the repressor helix of secM-secA mRNA. Mutational analysis of the seven conserved helicase motifs in SecA allowed us to identify mutants that uncouple SecA-dependent protein translocation activity from its helicase activity. Helicase-defective secA mutants displayed normal protein translocation activity and autogenous repression of secA in vivo. Our studies indicate that SecA helicase activity is nonessential and does not appear to be necessary for efficient protein secretion and secA autoregulation.

Tyr-326 plays a critical role in controlling SecA-preprotein interaction

SecA is an essential ATP-dependent motor protein that interacts with the preprotein and translocon to drive protein translocation across the eubacterial plasma membrane. A region containing residues 267-340 has been proposed to comprise the preprotein binding site of Escherichia coli SecA. To elucidate the function of this region further, we isolated mutants using a combination of region-specific polymerase chain reaction (PCR) mutagenesis and a genetic and biochemical screening procedure. Although this region displayed considerable plasticity based on phylogenetic and genetic analysis, Tyr-326 was found to be critical for SecA function. secA mutants with non-conservative substitutions at Tyr-326 showed strong protein secretion defects in vivo and were completely defective for SecA-dependent translocation ATPase activity in vitro. The SecA-Y326 mutant proteins were normal in their membrane, SecYE and nucleotide-binding properties. However, they exhibited a reduced affinity for preprotein and were defective in preprotein release, as assessed by several biochemical assays. Our results indicate that the region containing Tyr-326 functions as a conformational response element to regulate the preprotein binding and release cycle of SecA.

Distinct membrane binding properties of N- and C-terminal domains of Escherichia coli SecA ATPase

SecA is a motor protein that drives protein translocation at the Escherichia coli translocon. SecA membrane binding has been shown to occur with high affinity at SecYE and low affinity at anionic phospholipids. To dissect SecA-membrane interaction with reference to SecA structure, the membrane binding properties of N- and C-terminal SecA domains, denoted SecA-N664 and SecA-619C, respectively, were characterized. Remarkably, only SecA-N664 bound to the membrane with high affinity, whereas SecA-619C bound with low affinity in a nonsaturable manner through partitioning with phospholipids. Moreover, SecA-N664 and SecA-619C associated with each other to reconstitute wild type binding affinity. Corroborative results were also obtained from membrane binding competition and subcellular fractionation studies along with binding studies to membranes prepared from strains overproducing SecYE protein. Together, these findings indicate that the specific interaction of SecA with SecYE occurs through its N-terminal domain and that the C-terminal domain, although important in SecA membrane cycling at a later stage of translocation, appears to initially assist SecA membrane binding by interaction with phospholipids. These results provide the first evidence for distinct membrane binding characteristics of the two SecA primary domains and their importance for optimal binding activity, and they are significant for understanding SecA dynamics at the translocon.

Escherichia coli translocase: the unravelling of a molecular machine

Protein translocation across the bacterial cytoplasmic membrane has been studied extensively in Escherichia coli. The identification of the components involved and subsequent reconstitution of the purified translocation reaction have defined the minimal constituents that allowed extensive biochemical characterization of the so-called translocase. This functional enzyme complex consists of the SecYEG integral membrane protein complex and a peripherally bound ATPase, SecA. Under translocation conditions, four SecYEG heterotrimers assemble into one large protein complex, forming a putative protein-conducting channel. This tetrameric arrangement of SecYEG complexes and the highly dynamic SecA dimer together form a proton-motive force- and ATP-driven molecular machine that drives the stepwise translocation of targeted polypeptides across the cytoplasmic membrane. Recent findings concerning the translocase structure and mechanism of protein translocation are discussed and shine new light on controversies in the field.

Nucleotide binding activity of SecA homodimer is conformationally regulated by temperature and altered by prlD and azi mutations

SecA ATPase is critical for protein translocation across the Escherichia coli inner membrane. To understand this activity further, the high affinity nucleotide binding activity of SecA was characterized. We found that at 4 degrees C SecA homodimer binds one ADP molecule with high affinity. This nucleotide binding activity was conformationally regulated by temperature: at low temperature SecA affinity for ADP was high with a slow exchange rate, whereas at high temperature the converse was true. Azi- and PrlD-SecA proteins that confer azide-resistant and signal sequence suppressor phenotypes were found to have reduced affinity for ADP and accelerated exchange rates compared with wild type SecA. Consistent with this observation, fluorescence and proteolysis studies indicated that these proteins had a conformationally relaxed state at a reduced temperature compared with SecA. The level of Azi- and PrlD-SecA protein was also elevated in inverted membrane vesicles where it displayed higher membrane ATPase activity. These results provide the first direct evidence for conformational regulation of the SecA-dependent nucleotide cycle, its alteration in azi and prlD mutants, and its relevance to in vivo protein export.

SecA: the ubiquitous component of preprotein translocase in prokaryotes

SecA is an obligatory component of the complex hetero-septameric translocase of prokaryotes. It is unique in that it exists as two forms within the holoenzyme; first, as a structural component of the preprotein channel and second, as an ATP-dependent membrane cycling factor facilitating the translocation of a broad class of proteins across the cytoplasmic membrane. While the translocase activity of SecA appears to be functionally conserved, it is not clear whether the mechanisms of regulation of the secA gene are similarly maintained. The recent characterization of an ATP-dependent RNA helicase activity of SecA offers a unique mechanism for SecA to communicate the secretion status of the cell to the appropriate regulatory circuits simply by the unwinding of an appropriate RNA target. Resolution of these two activities through combined biochemical, genetic, and biophysical studies should lead to a better understanding of the role of SecA in bacterial secretion.

Differential dependence of levansucrase and alpha-amylase secretion on SecA (Div) during the exponential phase of growth of Bacillus subtilis

SecA, the translocation ATPase of the preprotein translocase, accounts for 0.25% of the total protein in a degU32(Hy) Bacillus subtilis strain in logarithmic phase. The SecA level remained constant irrespective of the demand for exoprotein production but dropped about 12-fold during the late stationary phase. Modulation of the level of functional SecA during the exponential phase of growth affected differently the secretion of levansucrase and alpha-amylase overexpressed under the control of the sacB leader region. The level of SecA was reduced in the presence of sodium azide and in the div341 thermosensitive mutant at nonpermissive temperatures. Overproduction of SecA was obtained with a multicopy plasmid bearing secA. The gradual decrease of the SecA level reduced the yield of secreted levansucrase with a concomitant accumulation of unprocessed precursor in the cells, while an increase in the SecA level resulted in an elevation of the production of exocellular levansucrase. In contrast, alpha-amylase secretion was almost unaffected by high concentrations of sodium azide or by very low levels of SecA. Secretion defects were apparent only under conditions of strong SecA deprivation of the cell. These data demonstrate that the alpha-amylase and levansucrase precursors markedly differ in their dependency on SecA for secretion. It is suggested that these precursors differ in their binding affinities for SecA.

secG and temperature modulate expression of azide-resistant and signal sequence suppressor phenotypes of Escherichia coli secA mutants

SecA is a dynamic protein that undergoes ATP-dependent membrane cycling to drive protein translocation across the Escherichia coli inner membrane. To understand more about this process, azide-resistant (azi) and signal sequence suppressor (prlD) alleles of secA were studied. We found that azide resistance is cold sensitive because of a direct effect on protein export, suggesting that SecA-membrane interaction is regulated by an endothermic step that is azide inhibitable. secG function is required for expression of azide-resistant and signal sequence suppressor activities of azi and prlD alleles, and in turn, these alleles suppress cold-sensitive and export-defective phenotypes of a secG null mutant. These remarkable genetic observations support biochemical data indicating that SecG promotes SecA membrane cycling and that this process is dependent on an endothermic change in SecA conformation.

Regulation of Escherichia coli secA by cellular protein secretion proficiency requires an intact gene X signal sequence and an active translocon

secA is translationally regulated by the protein secretion proficiency state of the Escherichia coli cell. This regulation was explored by making signal sequence mutations in the gene upstream of secA, gene X, which promotes secA translational coupling. Gene X signal sequence mutants were constitutive for secA expression, while prlA alleles partially restored secA regulation. These results show that interaction of the pre-gene X protein with the translocon is required for proper secA regulation. Furthermore, gene X signal sequence mutations disrupted secA regulation only in the cis configuration. We propose that nascent pre-gene X protein interacts with the translocon during its secretion to constitute the secretion sensor.

Requirements for the translocation of elongation-arrested, ribosome-associated OmpA across the plasma membrane of Escherichia coli

An oligodeoxynucleotide-dependent method to generate nascent polypeptide chains was adopted for use in a cell-free translation system prepared from Escherichia coli. In this way, NH2-terminal pOmpA fragments of distinct sizes were synthesized. Because most of these pOmpA fragments could be covalently linked to puromycin, precipitated with cetyltrimethylammonium bromide, and were enriched by sedimentation, they represent a population of elongation-arrested, ribosome-associated nascent chains. Translocation of these nascent pOmpA chains into inside-out membrane vesicles of E. coli required SecA and (depending on size) SecB. Whereas their translocation was strictly dependent on the H+-motive force of the vesicles, no indication for the involvement of the bacterial signal recognition particle was obtained. SecA and SecB, although required for translocation, did not mediate binding of the ribosome-associated pOmpA to membrane vesicles. However, SecA and SecB cotranslationally associated with nascent pOmpA, since they could be co-isolated with the ribosome-associated nascent chains and as such catalyzed translocation subsequent to the release of the ribosome. These results indicate that in E. coli, SecA also functionally interacts with preproteins before they are targeted to the translocase of the plasma membrane.

Identification and characterization of protease-resistant SecA fragments: secA has two membrane-integral forms

We have identified and characterized the protease-resistant SecA fragments (X. Chen, H. Xu, and P. C. Tai, J. Biol. Chem. 271:29698-29706, 1996) through immunodetection with region-specific antibodies, chemical extraction, and sequencing analysis. The 66-, 36-, and 27-kDa proteolytic fragments in the membranes all start at Met1, whereas the 48-kDa fragment starts at Glu361. The overlapping of the sequences of the 66- and 48-kDa fragments indicates that they are derived from different SecA molecules. These two fragments were generated differently in response to ATP hydrolysis and protein translocation. Furthermore, the presence of membrane is required for the generation of the 48-kDa fragment but not for that of the 66-kDa fragment. These data suggest that there are two different integral forms of SecA in the membrane: SecA(S) and SecA(M). The combination of these two forms of SecA has several membrane-interacting domains. Both forms of SecA are integrated in the membrane, since both the 48- and 66-kDa fragments could be derived from urea- or Na2CO3-washed membranes. Moreover, all fragments are resistant to extraction with a high concentration of salt or with heparin, but the membrane-specific 48-kDa SecA domain is more sensitive to Na2CO3 or urea extraction. This suggests that this domain may interact with other membrane proteins in an aqueous microenvironment and therefore may form a part of the protein-conducting channel.

Targeting of GroEL to SecA on the cytoplasmic membrane of Escherichia coli

Chaperonin GroEL has been found to interact with isolated cytoplasmic membrane of Escherichia coli. Interaction requires Mg ions, whereas MgATP inhibits, and inhibition is stronger in the presence of co-chaperonin GroES. "Heat-shock" of the membrane at 45 degrees C destroys irreversibly its ability to bind GroEL. The binding of GroEL is characterized by saturation with a maximum of about 100 pmol GroEL bound per mg of total membrane protein, indicating a limited capacity and specificity of the membrane to bind GroEL. According to results of immunoblotting analysis and cleavable photoactivable cross-linking, a membrane target of GroEL is SecA, a protein known as a central component of the translocation machinery. Moreover, in some cases GroEL could modulate a cycle of association of SecA with the membrane by stimulating release of SecA from the membrane. A physiological role of targeting of GroEL in or close to the protein-conducting membrane apparatus is discussed.

Chloroplast SecA functions as a membrane-associated component of the Sec-like protein translocase of pea chloroplasts

Protein cross-linking studies with a thylakoid membrane translocation intermediate were used to demonstrate that chloroplast SecA functions as a membrane-associated component of the Sec-like ATP-dependent protein translocase of pea chloroplasts. In assays with isolated thylakoids, it was observed that translocation of the 33-kDa protein of the oxygen-evolving complex of photosystem II (OE33) decreased when the ATP concentration was low, and that the protein accumulated as a bound precursor. The bound precursor was able to be translocated into the lumen when the ATP concentration was raised, indicating that the precursor was bound to the translocation apparatus. Inclusion of apyrase in the import reaction prevented translocation but did not affect precursor binding to the membrane. When this translocation intermediate was treated with the cross-linking agent disuccinimidyl suberate, a single predominant cross-linked product of 120 kDa was produced. This conjugate could be immunoprecipitated with antibodies to pea chloroplast SecA, identifying the cross-linking partner as SecA. This provides direct evidence for a functional interaction between a thylakoid precursor protein and a component of the thylakoid protein-translocation apparatus.

Topology of the integral membrane form of Escherichia coli SecA protein reveals multiple periplasmically exposed regions and modulation by ATP binding

SecA insertion and integration into the Escherichia coli inner membrane is a critical step for the catalysis of protein translocation across this layer. To understand this step further, SecA topology was investigated. To determine which regions of SecA are periplasmically exposed, right-side out membrane vesicles were prepared from strains synthesizing monocysteine SecA variants produced by mutagenesis and probed with a membrane-impermeant sulfhydryl-labeling reagent. To determine which regions of SecA contain membrane-integration determinants, inverted inner membrane vesicles were subjected to proteolysis, and integral-membrane fragments of SecA were identified with region-specific antibodies. The membrane association properties of various truncated SecA species produced in vivo were also determined. Our analysis indicates that the membrane topology of SecA is complex with amino-terminal, central, and carboxyl-terminal regions of SecA integrated into the membrane where portions are periplasmically accessible. Furthermore, the insertion and penetration of the amino-terminal third of SecA, which includes the proposed preprotein-binding domain, is subject to modulation by ATP binding. The importance of these studies to the cycle of membrane insertion and de-insertion of SecA that promotes protein translocation and SecA's proximity to the preprotein channel are discussed.

Comparative characterization of SecA from the alpha-subclass purple bacterium Rhodobacter capsulatus and Escherichia coli reveals differences in membrane and precursor specificity

We have cloned the secA gene of the alpha-subclass purple bacterium Rhodobacter capsulatus, a close relative to the mitochondrial ancestor, and purified the protein after expression in Escherichia coli. R. capsulatus SecA contains 904 amino acids with 53% identity to E. coli and 54% identity to Caulobacter crescentus SecA. In contrast to the nearly equal partitioning of E. coli SecA between the cytosol and plasma membrane, R. capsulatus SecA is recovered predominantly from the membrane fraction. A SecA-deficient, cell-free synthesis-translocation system prepared from R. capsulatus is used to demonstrate translocation activity of the purified R. capsulatus SecA. This translocation activity is then compared to that of the E. coli counterpart by using various precursor proteins and inside-out membrane vesicles prepared from both bacteria. We find a preference of the R. capsulatus SecA for the homologous membrane vesicles whereas E. coli SecA is active with either type of membrane. Furthermore, the two SecA proteins clearly select between distinct precursor proteins. In addition, we show here for the first time that a bacterial c-type cytochrome utilizes the canonical, Sec-dependent export pathway.

Identification of a region of interaction between Escherichia coli SecA and SecY proteins

SecA ATPase promotes Escherichia coli protein translocation by its association with the preprotein or preprotein-SecB complex, anionic phospholipids, and the other core component of translocase, integral membrane protein SecYEG. Using ligand affinity blotting we demonstrate a direct interaction of SecA with SecY protein. Proteolysis and gene truncation or fusion studies were used to further define this interaction. Our results demonstrate that the carboxyl-terminal third of SecA protein binds to the amino-terminal 107 amino acid residues of SecY protein. The direct demonstration of these interactions culminate studies that have inferred an interaction between SecA and SecYEG, and they are consistent with studies suggesting that this region of SecA interacts with the inner membrane.

Characterization of membrane and protein interaction determinants of the Agrobacterium tumefaciens VirB11 ATPase

The VirB11 ATPase is a putative component of the transport machinery responsible for directing the export of nucleoprotein particles (T complexes) across the Agrobacterium tumefaciens envelope to susceptible plant cells. Fractionation and membrane treatment studies showed that approximately 30% of VirB11 partitioned as soluble protein, whereas the remaining protein was only partially solubilized with urea from cytoplasmic membranes of wild-type strain A348 as well as a Ti-plasmidless strain expressing virB11 from an IncP replicon. Mutations in virB11 affecting protein function were mapped near the amino terminus (Q6L, P13L, and E25G), just upstream of a region encoding a Walker A nucleotide-binding site (F154H;L155M), and within the Walker A motif (P170L, K175Q, and delta GKT174-176). The K175Q and delta GKT174-176 mutant proteins partitioned almost exclusively with the cytoplasmic membrane, suggesting that an activity associated with nucleotide binding could modulate the affinity of VirB11 for the cytoplasmic membrane. The virB11F154H;L155M allele was transdominant over wild-type virB11 in a merodiploid assay, providing strong evidence that at least one form of VirB11 functions as a homo- or heteromultimer. An allele with a deletion of the first half of the gene, virB11 delta1-156, was transdominant in a merodiploid assay, indicating that the C-terminal half of VirB11 contains a protein interaction domain. Products of both virB11 delta1-156 and virB11 delta158-343, which synthesizes the N-terminal half of VirB11, associated tightly with the A. tumefaciens membrane, suggesting that both halves of VirB11 contain membrane interaction determinants.

Identification of elements on GeneX-secA RNA of Escherichia coli required for SecA binding and secA auto-regulation

The protein translocation ATPase of Escherichia coli, SecA protein, auto-regulates its translation by binding to its translation initiation region in geneX-secA mRNA. To analyze this regulation further the secondary structure of this portion of geneX-secA RNA was investigated utilizing structure-specific nucleases and chemical probing approaches. The results of this analysis were consistent with the existence of two adjacent helices, helix I and the lower portion of helix II, whose function in secA activation and repression, respectively, has been demonstrated. Binding of SecA protein to geneX-secA RNA or various mutant derivatives of this RNA was studied by measurement of affinity constants, RNA footprint analysis, and quantitation of auto-repression in vivo. This analysis showed that the SecA-binding site in geneX-secA RNA was remarkably large spanning a region of 96 nucleotides including a 3' portion of helix II, the secA translation initiation region and distal sequences. From the size of the SecA-binding site and the plasticity of its response to mutational alteration, it is suggested that SecA protein contains two distinct RNA-binding sites. Finally, it was shown that SecA binding was not sufficient to promote auto-regulation and that sequences both upstream (helix I) and within the binding site can contribute to auto-regulation without affecting SecA-binding affinity.

Dual regulation of Escherichia coli secA translation by distinct upstream elements

The regulation of the Escherichia coli secA gene, whose translation is auto-repressed except when protein secretion becomes limiting, was investigated using a combination of genetic and biochemical approaches. Oligonucleotide-directed deletion and point mutagenesis was used to show that only the last quarter of the upstream gene, geneX, and the geneX-secA intergenic are essential for proper regulation. This region previously shown to contain a secretion-responsive element contains two predicted helices, helix I and II, the latter of which would occlude the secA Shine-Dalgarno sequence. Mutations that destabilized the lower portion of helix II increased secA basal expression, reduced auto-repression by SecA protein, but retained a normal pattern of derepression of secA expression during a protein export block. The introduction of compensatory mutations into helix II that were predicted to restore base-pairing restored secA regulation to wild-type levels or nearly so, suggesting that this helix does play a role in secA auto-regulation in vivo. In contrast, mutations in the lower portion of helix I decreased secA basal expression, reduced auto-repression by SecA protein, and abolished the responsiveness of secA expression to a protein export block. In this latter case introduction of compensatory mutations into helix I that were predicted to restore base-pairing did not restore proper secA regulation, indicating that specific nucleotides in this region are required for normal secA regulation. Primer-extension inhibition (toeprint) analysis with 30 S ribosoma subunits, tRNAMet, and a model segment of geneX-secA RNA carrying the relevant mutations was used to show that mutations that destabilized helix II increased ribosome binding at the secA translation initiation site, while mutations that perturbed helix I decreased ribosome binding at this site. Our results suggest strongly that there is a system of dual regulation of secA translation, whereby helix I serves as an activator element while helix II serves as a repressor element.

Separable ATPase and membrane insertion domains of the SecA subunit of preprotein translocase

The SecA subunit of preprotein translocase drives ATP-dependent translocation of preproteins across the bacterial inner membrane concomitant with cycles of membrane insertion and de-insertion (Economou, A., and Wickner, W. (1994) Cell 78, 835-843). We have identified the membrane-inserting region of SecA as a 30-kDa domain in the C-terminal third of the protein beginning at aminoacyl residue 610. Limited proteolysis in the absence of translocation ligands indicates that the SecA monomer is composed of two primary structural domains, the 30-kDa membrane-inserting domain and an N-terminal 65-kDa ATPase domain. This limited protease treatment of SecA results in constitutive ATPase activity, indicating that intramolecular constraints between the two domains may play a role in the regulation of ATP hydrolysis by SecA.

A significant fraction of functional SecA is permanently embedded in the membrane. SecA cycling on and off the membrane is not essential during protein translocation

SecA has been suggested to cycle on and off the cytoplasmic membrane of Escherichia coli during protein translocation. We have reconstituted 35S-SecA onto SecA-depleted membrane vesicles and followed the fate of the membrane-associated 35S-SecA during protein translocation. Some 35S-SecA was released from the membranes in a translocation-independent manner. However, a significant fraction of 35S-SecA remained on the membranes even after incubation with excess SecA. This fraction of 35S-SecA was shown to be integrated into the membrane and was active in protein translocation, indicating that SecA cycling on and off membrane is not required for protein translocation. Proteolysis experiments did not support the model of SecA insertion and deinsertion during protein translocation; instead, a major 48-kDa domain was found persistently embedded in the membrane regardless of translocation status. Thus, in addition to catalyzing ATP hydrolysis, certain domains of SecA probably play an important structural role in the translocation machinery, perhaps forming part of the protein-conducting channels.