The SecA subunit of Escherichia coli preprotein translocase is exposed to the periplasm

SecA undergoes conformational changes during translocation, inserting domains into and across the membrane or enhancing the protease resistance of these domains. We now show that some SecA bound at SecYEG is accessible from the periplasm to a membrane-impermeant probe in cells with a permeabilized outer membrane but an intact plasma membrane.     

The SecA and SecY subunits of translocase are the nearest neighbors of a translocating preprotein, shielding it from phospholipids

To study the environment of a preprotein as it crosses the plasma membrane of Escherichia coli, unique cysteinyl residues were introduced into proOmpA and the genes for these mutant preproteins were fused to the gene of dihydrofolate reductase (Dhfr). A photoactivable, radiolabeled and reducible cross-linker was then attached to the unique cysteinyl residue of each purified protein. Partially translocated polypeptides were generated and arrested in their membrane transit by the folded structure of the dihydrofolate reductase domain. After photolysis to label their nearest neighbors and reduction of the disulfide bond between proOmpA-Dhfr and the cross-linker, radiolabeled cross-linker was selectively recovered with the SecA and SecY subunits of preprotein translocase. Strikingly, neither the SecE nor Band 1 subunits were cross-linked to any of the constructs and the membrane phospholipids were almost entirely shielded from cross-linking. The fact that SecY and SecA are the only membrane proteins cross-linked to the translocating chains suggests that they may form an entirely proteinaceous pathway through which secreted proteins pass during membrane transit.     

The SecDFyajC domain of preprotein translocase controls preprotein movement by regulating SecA membrane cycling

Escherichia coli preprotein translocase comprises a membrane-embedded hexameric complex of SecY, SecE, SecG, SecD, SecF and YajC (SecYEGDFyajC) and the peripheral ATPase SecA. The energy of ATP binding and hydrolysis promotes cycles of membrane insertion and deinsertion of SecA and catalyzes the movement of the preprotein across the membrane. The proton motive force (PMF), though not essential, greatly accelerates late stages of translocation. We now report that the SecDFyajC domain of translocase slows the movement of preprotein in transit against both reverse and forward translocation and exerts this control through stabilization of the inserted form of SecA. This mechanism allows the accumulation of specific translocation intermediates which can then complete translocation under the driving force of the PMF. These findings establish a functional relationship between SecA membrane insertion and preprotein translocation and show that SecDFyajC controls SecA membrane cycling to regulate the movement of the translocating preprotein.     

In vivo analyses of interactions between SecE and SecY, core components of the Escherichia coli protein translocation machinery

We have carried out structure-function studies on the cytoplasmic membrane protein, SecE, a component of the Escherichia coli secretion machinery. SecE, along with SecY, form a complex in the cytoplasmic membrane essential for protein translocation. By directed mutagenesis, we altered highly conserved residues of the second cytoplasmic domain (CD2) and of the COOH-terminal periplasmic region (PD2) of SecE. These mutants, as well as previously constructed mutations in the third membrane-spanning segment of SecE (MSS3), were tested for their ability to complement a secE null mutation, for their effects on protein export in vivo, and for their ability to form a stable complex with SecY. Most single mutations at the conserved positions in CD2 caused secretion defects, but had little effect on growth at 37 degrees C. Double mutations in CD2, or the introduction or removal of proline residues, affected growth and protein translocation more severely. Co-immunoprecipitations of SecE and SecY revealed that all mutant proteins, except those altered in PD2, destabilized the SecE-SecY complex. These results suggest that several regions contribute to the formation of a stable SecE-SecY complex but the elimination of a single contact point does not necessarily affect the functionality of the complex.     

The catalytic cycle of the escherichia coli SecA ATPase comprises two distinct preprotein translocation events

Poly(ADP-ribosyl)transferase (pADPRT) is a nuclear protein which catalyzes the polymerization of ADP-ribose using NAD+ as substrate, as well as the transfer of ADP-ribose polymers to itself and other protein acceptors. The catalytic activity of pADPRT strictly depends on the presence of DNA single-strand breaks. In this report, protein-protein interaction of pADPRT was found to depend on both the extent of automodification with poly(ADP-ribose) and the presence of DNA. Specific binding of radiolabeled pADPRT to transblotted proteins was first tested in blot overlay experiments. For radiolabeling, use was made of the ability of the enzyme to incorporate [32P]ADP-ribose from [32P]NAD+. Varying the concentration of NAD+, two different forms of automodified pADPRT were obtained: oligo(ADP-ribosyl)ated pADPRT with less than 20 ADP-ribose units per chain, and poly(ADP-ribosyl)ated pADPRT with polymer lengths of up to 200 ADP-ribose residues. Interaction of these probes with transblotted HeLa nuclear extracts, purified histones, and distinct regions of recombinant pADPRT was investigated. While the oligo(ADP-ribosyl)ated enzyme associated preferentially with transblotted purified histones, or pADPRT present in HeLa nuclear extracts, poly(ADP-ribosyl)ated pADPRT bound to a variety of transblotted proteins in the nuclear extracts. In the presence of DNA, both the oligo- and the poly(ADP-ribosyl)ated enzymes bound to the transblotted recombinant zinc finger domain of pADPRT even at high salt concentrations. In the absence of DNA, the transblotted automodification domain of pADPRT appeared to be the region involved in self-association. In another set of experiments, unmodified or poly(ADP-ribosyl)ated pADPRT was immobilized on Sepharose. Affinity precipitation of recombinant pADPRT domains confirmed the specific interaction of pADPRT with its zinc finger region and the automodification domain, whereas no interaction was observed with the NAD+ binding domain. Affinity precipitation of HeLa nuclear extracts with poly(ADP-ribosyl)ated pADPRT-Sepharose led to the enrichment of a number of proteins, whereas nuclear proteins bound to the unmodified pADPRT-Sepharose in a smaller extent. The results suggest that protein-protein interaction of the human pADPRT is governed by its functional state.     

Domain interactions of the peripheral preprotein Translocase subunit SecA

The homodimeric SecA protein is the peripheral subunit of the preprotein translocase in bacteria. It binds the preprotein and promotes its translocation across the bacterial cytoplasmic membrane by nucleotide modulated coinsertion and deinsertion into the membrane. SecA has two essential nucleotide binding sites (NBS; Mitchell & Oliver, 1993): The high-affinity NBS-I resides in the amino-terminal domain of the protein, and the low-affinity NBS-II is localized at 2/3 of the protein sequence. The nucleotide-bound states of soluble SecA were studied by site directed tryptophan fluorescence spectroscopy, tryptic digestion, differential scanning calorimetry, and dynamic light scattering. A nucleotide-induced conformational change of a carboxy-terminal domain of SecA was revealed by Trp fluorescence spectroscopy. The Trp fluorescence of a single Trp SecA mutant containing Trp775 decreased and increased upon the addition of NBS-I saturating concentrations of ADP or AMP-PNP, respectively. DSC measurements revealed that SecA unfolds as a two domain protein. Binding of ADP to NBS-I increased the interaction between the two domains whereas binding of AMP-PNP did not influence this interaction. When both NBS-I and NBS-II are bound by ADP, SecA seems to have a more compact globular conformation whereas binding of AMP-PNP seems to cause a more extended conformation. It is suggested that the compact ADP-bound conformation resembles the membrane deinserted state of SecA, while the more extended ATP-bound conformation may correspond to the membrane inserted form of SecA.     

Characterization of the secA gene of Streptomyces lividans encoding a protein translocase which complements and Escherichia coli mutant defective in the ATPase activity of SecA

The secA gene of Streptomyces lividans was cloned using as probe a 57-mer oligonucleotide based on conserved sequences of the Escherichia coli secA and the Bacillus subtilis div genes. It encodes a protein of 946 amino acids (aa) with a deduced M(r) of 106,079, with high similarity to all known SecA proteins. All the previously described conserved motifs of SecA proteins were conserved in the S. lividans protein. The secA gene of S. lividans restored sensitivity to sodium azide in E. coli SecA4 (AzR) a mutant with an azide-resistant (ATPase defective) SecA protein. However, it did not complement the temperature-sensitive mutation in E. coli MM52 (SecAts) (a conditional lethal mutant defective in protein translocation) allowing only poor growth at the nonpermissive temperature. secA homologous sequences were present in 11 different species of Streptomyces and Nocardia.     

The preprotein translocase of the mitochondrial inner membrane: function and evolution

Growing mitochondria acquire most of their proteins by the uptake of mitochondrial preproteins from the cytosol. To mediate this protein import, both mitochondrial membranes contain independent protein transport systems: the Tom machinery in the outer membrane and the Tim machinery in the inner membrane. Transport of proteins across the inner membrane and sorting to the different inner mitochondrial compartments is mediated by several protein complexes which have been identified in the past years. A complex containing the integral membrane proteins Tim17 and Tim23 constitutes the import channel for preproteins containing amino-terminal hydrophilic presequences. This complex is associated with Tim44 which serves as an adaptor protein for the binding of mtHsp70 to the membrane. mtHsp70, a 70 kDa heat shock protein of the mitochondrial matrix, drives the ATP-dependent import reaction of the processed preprotein after cleavage of the presequence. Preproteins containing internal targeting information are imported by a separate import machinery, which consists of the intermembrane-space proteins Tim9, Tim10, and Tim12, and the inner membrane proteins Tim22 and Tim54. The proteins Tim17, Tim22, and Tim23 have in common a similar topology in the membrane and a homologous amino acid sequence. Moreover, they show a sequence similarity to OEP16, a channel-forming amino acid transporter in the outer envelope of chloroplasts, and to LivH, a component of a prokaryotic amino acid permease, defining a new PRAT-family of preprotein and amino acid transporters.     

Interacting helical faces of subunits a and c in the F1Fo ATP synthase of Escherichia coli defined by disulfide cross-linking

Subunits a and c of Fo are thought to cooperatively catalyze proton translocation during ATP synthesis by the Escherichia coli F1Fo ATP synthase. Optimizing mutations in subunit a at residues A217, I221, and L224 improves the partial function of the cA24D/cD61G double mutant and, on this basis, these three residues were proposed to lie on one face of a transmembrane helix of subunit a, which then interacted with the transmembrane helix of subunit c anchoring the essential aspartyl group. To test this model, in the present work Cys residues were introduced into the second transmembrane helix of subunit c and the predicted fourth transmembrane helix of subunit a. After treating the membrane vesicles of these mutants with Cu(1, 10-phenanthroline)2SO4 at 0 degrees, 10 degrees, or 20 degreesC, strong a-c dimer formation was observed at all three temperatures in membranes of 7 of the 65 double mutants constructed, i.e., in the aS207C/cI55C, aN214C/cA62C, aN214C/cM65C, aI221C/cG69C, aI223C/cL72C, aL224C/cY73C, and aI225C/cY73C double mutant proteins. The pattern of cross-linking aligns the helices in a parallel fashion over a span of 19 residues with the aN214C residue lying close to the cA62C and cM65C residues in the middle of the membrane. Lesser a-c dimer formation was observed in nine other double mutants after treatment at 20 degreesC in a pattern generally supporting that indicated by the seven landmark residues cited above. Cross-link formation was not observed between helix-1 of subunit c and helix-4 of subunit a in 19 additional combinations of doubly Cys-substituted proteins. These results provide direct chemical evidence that helix-2 of subunit c and helix-4 of subunit a pack close enough to each other in the membrane to interact during function. The proximity of helices supports the possibility of an interaction between Arg210 in helix-4 of subunit a and Asp61 in helix-2 of subunit c during proton translocation, as has been suggested previously.     

Protein translocation functions of Escherichia coli SecY: in vitro characterization of cold-sensitive secY mutants

Activated macrophages are among the major constituents of the periapical granuloma. Their state of activation may persist for long periods after the local irritant is removed and may delay resolution and repair of the lesion. The effect of activated macrophages on fibroblast growth was studied in vitro. Circular fibroblast colonies were formed using a drop containing 7.5 x 10(5) murine dermal fibroblasts and allowed to grow for 7 days. When peritoneal exudate macrophages were added (0.5-3.0 x 10(6) cells/dish) and activated in vitro by LPS (1 microgram/ml), the fibroblast colony's growth was suppressed. LPS alone, at the concentration used, had no effect on the fibroblast growth. Hydrocortisone (> or = 10(-7) M) totally reversed the suppression, when added either simultaneously with or 6, 24, or 48 h after the LPS. The efficacy of late hydrocortisone treatment suggests that its effect was through prevention of the expression of the LPS activation of the macrophages. These findings may provide a possible clue to a pharmacological modulation of the healing processes that occur in the periapical lesion once its infective source had been eliminated.     

In vitro and in vivo redox states of the Escherichia coli periplasmic oxidoreductases DsbA and DsbC

DsbC is a periplasmic protein of Escherichia coli that was previously identified by a genetic selection that rescued sensitivity to dithiothreitol in Tn10 mutagenized cells. The Erwinia chrysanthemi dsbC gene was identified in a previous genetic screen to restore motility in a dsbA null strain. In order to analyze the biochemical role of E. coli DsbC, the protein was overexpressed, purified, and compared with DsbA in terms of disulfide isomerization, thiol oxidation, and in vivo redox state. In vitro, DsbC and DsbA have an equivalent kcat for disulfide isomerization with the model substrate, misfolded insulin-like growth factor-1. However, DsbA is a more effective oxidant than DsbC of protein dithiols. In vivo, DsbA is found exclusively in the oxidized state in wild-type strains grown in rich media. On the other hand, in vivo DsbC has one pair of cysteines oxidized and one pair reduced. DsbD is required to maintain this reduced pair of cysteines, confirming previous genetic results. A dsbC deletion strain showed decreases in the production of some, but not all, heterologous proteins containing multiple disulfide bonds. Notably, those proteins affected by the dsbC deletion do not have the cysteines paired consecutively.     

In vivo and in vitro characterization of Escherichia coli protein CheZ gain- and loss-of-function mutants

Bacterial chemotaxis results from the ability of flagellated bacteria to control the frequency of switching between smooth-swimming and tumbling episodes in response to changes in concentration of extracellular substances. High levels of phosphorylated CheY protein are the intracellular signal for inducing the tumbling mode of swimming. The CheZ protein has been shown to control the level of phosphorylated CheY by regulating its rate of dephosphorylation. To identify functional domains in the CheZ protein, we made mutants by random mutagenesis of the cheZ gene and constructed a series of deletions. The map position and the in vivo and in vitro activity of the resulting gain- or loss-of-function mutant proteins define separate functional domains of the CheZ protein.     

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.     

Lysine 106 of the putative catalytic ATP-binding site of the Bacillus subtilis SecA protein is required for functional complementation of Escherichia coli secA mutants in vivo

The SecA protein is a major component of the cellular machinery that mediates the translocation of proteins across the Escherichia coli plasma membrane. The secA gene from Bacillus subtilis was cloned and expressed in E. coli under the control of the lac or trc promoter. The temperature-sensitive growth and secretion defects of various E. coli secA mutants were complemented by the B. subtilis SecA protein, provided the protein was expressed at moderate levels. Under overproduction conditions, no complementation was observed. One of the main features of the SecA protein is the translocation ATPase activity which, together with the protonmotive force, drives the movement of proteins across the plasma membrane. A putative ATP-binding motif can be identified in the SecA protein resembling the consensus Walker A type motif. Replacement of a lysine residue at position 106, which corresponds to an invariable amino acid residue, in the consensus motif by asparagine (K106N) resulted in the loss of the ability of the B. subtilis SecA protein to complement the growth and secretion defects of E. coli secA mutants. In addition, the presence of the K106N SecA protein interfered with protein translocation, most likely at an ATP-requiring step. We conclude that lysine 106 is part of the catalytic ATP-binding site of the B. subtilis SecA protein, which is required for protein translocation in vivo.     

In vivo cloning of genes of Escherichia coli K12 by means of homologue recombination

OBJECTIVES: This study was conducted to compare microleakage of two new dentin bonding agents on freshly extracted teeth, cryopreserved teeth, or teeth stored in water containing 0.5% chloramine at 4 degrees C. METHODS: Rectangular Class V cavity preparations were made on the buccal and the lingual surface of wisdom teeth. They were filled with either Scotchbond Multi-Purpose and Z100 (3M Dental Products) or with Gluma 2000 and Pekafill (Bayer Dental). After thermocycling, silver staining penetration was evaluated under a light microscope. SEM examination and EDX analysis were performed to evaluate the microleakage pattern. The results were analyzed by the use of a two-way analysis of variance. RESULTS: Cryopreservation for 13 wk or 12 d refrigeration did not produce changes in the amount of microleakage. However, 48 d or longer of refrigeration increased microleakage. There was no correlation between changes in microleakage and storage time. Specimens prepared with both dentin bonding agents exhibited the same microleakage values and the same microleakage pattern. SIGNIFICANCE: Refrigeration at 4 degrees C in 0.5% chloramine for 48 d or longer may cause an increase in microleakage. Cryopreservation for 13 wk or short-term refrigeration did not affect the microleakage.     

Activation by fusion of the glutaminase and synthetase subunits of Escherichia coli carbamyl-phosphate synthetase

Escherichia coli carbamyl-phosphate synthetase consists of two subunits that act in concert to synthesize carbamyl phosphate. The 40-kDa subunit is an amidotransferase (GLN subunit) that hydrolyzes glutamine and transfers ammonia to the 120-kDa synthetase subunit (CPS subunit). The enzyme can also catalyze ammonia-dependent carbamyl phosphate synthesis if provided with exogenous ammonia. In mammalian cells, homologous amidotransferase and synthetase domains are carried on a single polypeptide chain called CAD. Deletion of the 29-residue linker that bridges the GLN and CPS domains of CAD stimulates glutamine-dependent carbamyl phosphate synthesis and abolishes the ammonia-dependent reaction (Guy, H. I., and Evans, D. R. (1997) J. Biol. Chem. 272, 19906-19912), suggesting that the deletion mutant is trapped in a closed high activity conformation. Since the catalytic mechanisms of the mammalian and bacterial proteins are the same, we anticipated that similar changes in the function of the E. coli protein could be produced by direct fusion of the GLN and CPS subunits. A construct was made in which the intergenic region between the contiguous carA and carB genes was deleted and the sequences encoding the carbamyl-phosphate synthetase subunits were fused in frame. The resulting fusion protein was activated 10-fold relative to the native protein, was unresponsive to the allosteric activator ornithine, and could no longer use ammonia as a nitrogen donor. Moreover, the functional linkage that coordinates the rate of glutamine hydrolysis with the activation of bicarbonate was abolished, suggesting that the protein was locked in an activated conformation similar to that induced by the simultaneous binding of all substrates.     

Mitochondrial permeability transition as induced by cross-linking of the adenine nucleotide translocase

Non-invasive assessment of vascularity is a new diagnostic approach to characterise tumours. Vascular assessment is based on the pathophysiology of tumour angiogenesis and its diagnostic implications for tumour biology, prognosis and therapy response. Two current techniques investigating vascular features in addition to morphology are Doppler ultrasonography and contrast-enhanced MRI. Diagnostic differentiation has been shown to be possible with Doppler, and a high degree of observed vascularity could be linked to an aggressive course of the disease. Dynamic MRI using gadolinium chelates is already used clinically to detect and differentiate tumours. The histological correlation shows that capillary permeability is increased in malignant tumours and is the best criterion for differentiation from benign processes. Permeability and perfusion factors seem to be more diagnostic than overall vessel density. New clinical applications are currently being established for therapy monitoring. Further instrumental developments will bring harmonic imaging in Doppler, and faster imaging techniques, higher spatial resolution and novel pharmacokinetic concepts in MRI. Upcoming contrast agents for both Doppler and MRI will further improve estimation of intratumoural blood volume and vascular permeability.     

Syd, a SecY-interacting protein, excludes SecA from the SecYE complex with an altered SecY24 subunit

Syd is an Escherichia coli cytosolic protein that interacts with SecY. Overproduction of this protein causes a number of protein translocation-related phenotypes, including the strong toxicity against the secY24 mutant cells. Previously, this mutation was shown to impair the interaction between SecY and SecE, the two fundamental subunits of the membrane-embedded part of protein translocase. We have now studied in vitro the mechanisms of the Syd-directed inhibition of protein translocation. Pro-OmpA translocation into inverted membrane vesicles (IMVs) prepared from the secY24 mutant cells as well as the accompanied translocation ATPase activity of SecA were rapidly inhibited by purified Syd protein. In the course of protein translocation, high affinity binding of preprotein-bearing SecA to the translocase on the IMV is followed by ATP-driven insertion of the 30-kDa SecA segment into the membrane. Our experiments using 125I-labeled SecA and the secY24 mutant IMV showed that Syd abolished both the high affinity SecA binding and the SecA insertion. Syd was even able to release the inserted form of SecA that had been stabilized by a nonhydrolyzable ATP analog. Syd affected markedly the proteolytic digestion pattern of the IMV-integrated SecY24 protein, suggesting that Syd exerts its inhibitory effect by interacting directly with the SecY24 protein. In accordance with this notion, a SecY24 variant with a second site mutation (secY249) resisted the Syd action both in vivo and in vitro. Thus, Syd acts against the SecY24 form of translocase, in which SecY-SecE interaction has been compromised, to exclude the SecA motor protein from the SecYE channel complex.     

In vivo evidence for the involvement of anionic phospholipids in initiation of DNA replication in Escherichia coli

In vitro, anionic phospholipids can reactivate inactivated DnaA protein, which is essential for initiation of DNA replication at the oriC site of Escherichia coli [Sekimizu, K. & Kornberg, A. (1988) J. Biol. Chem. 263, 7131-7135]. Mutations in the pgsA gene (encoding phosphatidylglycerophosphate synthase) limit the synthesis of the major anionic phospholipids and lead to arrest of cell growth. We report herein that a mutation in the rnhA gene (encoding RNase H) that bypasses the need for the DnaA protein through induction of constitutive stable DNA replication [Kogoma, T. & von Meyenburg, K. (1983) EMBO J. 2, 463-468] also suppressed the growth arrest phenotype of a pgsA mutant. The maintenance of plasmids dependent on an oriC site for replication, and therefore DnaA protein, was also compromised under conditions of limiting anionic phospholipid synthesis. These results provide support for the involvement of anionic phospholipids in normal initiation of DNA replication at oriC in vivo by the DnaA protein.