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.     

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.     

Cloning of a lectin cDNA and seasonal changes in levels of the lectin and its mRNA in the inner bark of Robinia pseudoacacia

E. coli cells harboring pCG169 containing the secD secF locus possessed SecA protein almost entirely in an integral membrane form in which it displayed normal protein translocation activity. These results imply that integral membrane SecA is the catalytically active form of this enzyme and that products of the secD secF locus regulate SecA association with the inner membrane. Protease and biotinylation accessibility studies of right side-out and inside-out membrane vesicles derived from this strain revealed that SecA was exposed to the periplasmic surface of the inner membrane. These studies suggest a model of bacterial protein secretion, whereby insertion of SecA into the inner membrane and its association with SecY/E/G promotes assembly of active protein-conducting channels comprised in part of integral membrane SecA protein, and products of the secD secF locus regulate the channel assembly-disassembly reaction by modulating the SecA insertion-deinsertion step.     

The endogenous agonist quinolinic acid and the non endogenous homoquinolinic acid discriminate between NMDAR2 receptor subunits

The polysialic acid (polySia) capsule of Escherichia coli K1 is a key virulence determinant of the organism, allowing it to evade host defenses. The proteins necessary for expression of the capsule are encoded by the 17 kb kps gene cluster. This cluster contains two genes, kpsM and kpsT, that are required for polySia transport across the cytoplasmic membrane. KpsM is a hydrophobic integral inner membrane protein, while KpsT is a peripheral inner membrane protein that binds ATP. They belong to the ATP-binding cassette (ABC) superfamily of transporters. To study the role of KpsT in polySia translocation, we used PCR mutagenesis to isolate dominant negative mutations of plasmid-encoded kpsT. All mutations mapped to the same glutamic acid residue at position 150, adjacent to Walker motif B of KpsT. Wild-type (kps+) cells harboring one such allele, E150G, did not transport polySia to the cell surface but accumulated intracellular polysaccharide and produced small colonies containing cells that grew as long filaments. The E150G protein still bound ATP as shown by 8-azidoATP photolabeling assays. We combined the E150G allele with each of five mutations isolated previously in kpsT. Mutations that disrupt ATP-binding (K44E) or alter regions of the protein thought to interact with KpsM (G84D, S126F) suppressed the dominant negative phenotype while mutations in the C-terminal portion of the protein (C163Y, H181Y) did not suppress. These studies have allowed the development of a working model for the role of KpsT in polySia chain translocation.     

In vivo cross-linking of the SecA and SecY subunits of the Escherichia coli preprotein translocase

Precursor protein translocation across the Escherichia coli inner membrane is mediated by the translocase, which is composed of a heterotrimeric integral membrane protein complex with SecY, SecE, and SecG as subunits and peripherally bound SecA. Cross-linking experiments were conducted to study which proteins are associated with SecA in vivo. Formaldehyde treatment of intact cells results in the specific cross-linking of SecA to SecY. Concurrently with the increased membrane association of SecA, an elevated amount of cross-linked product was obtained in cells harboring overproduced SecYEG complex. Cross-linked SecA copurified with hexahistidine-tagged SecY and not with SecE. The data indicate that SecA and SecY coexist as a stable complex in the cytoplasmic membrane in vivo.     

Lethality of the covalent linkage between mislocalized major outer membrane lipoprotein and the peptidoglycan of Escherichia coli

The major outer membrane lipoprotein (Lpp) of Escherichia coli possesses serine at position 2, which is thought to function as the outer membrane sorting signal, and lysine at the C terminus, through which Lpp covalently associates with peptidoglycan. Arginine (R) is present before the C-terminal lysine in the wild-type Lpp (LppSK). By replacing serine (S) at position 2 with aspartate (D), the putative inner membrane sorting signal, and by deleting lysine (K) at the C terminus, Lpp mutants with a different residue at either position 2 (LppDK) or the C terminus (LppSR) or both (LppDR) were constructed. Expression of LppSR and LppDR little affected the growth of E. coli. In contrast, the number of viable cells immediately decreased when LppDK was expressed. Prolonged expression of LppDK inhibited separation of the inner and outer membranes by sucrose density gradient centrifugation, whereas short-term expression did not. Pulse-labeled LppDK and LppDR were localized in the inner membrane, indicating that the amino acid residue at position 2 functions as a sorting signal for the membrane localization of Lpp. LppDK accumulated in the inner membrane covalently associated with the peptidoglycan and thus prevented the separation of the two membranes. Globomycin, an inhibitor of lipoprotein-specific signal peptidase II, was lethal for E. coli only when Lpp possessed the C-terminal lysine. Taken together, these results indicate that the inner membrane accumulation of Lpp per se is not lethal for E. coli. Instead, a covalent linkage between the inner membrane Lpp having the C-terminal lysine and the peptidoglycan is lethal for E. coli, presumably due to the disruption of the cell surface integrity.     

Mutant ATP-binding RNA aptamers reveal the structural basis for ligand binding

A nuclear mutant of maize, tha1, which exhibited defects in the translocation of proteins across the thylakoid membrane, was described previously. A transposon insertion at the tha1 locus facilitated the cloning of portions of the tha1 gene. Strong sequence similarity with secA genes from bacteria, pea and spinach indicates that tha1 encodes a SecA homologue (cp-SecA). The tha1-ref allele is either null or nearly so, in that tha1 mRNA is undetectable in mutant leaves and cp-SecA accumulation is reduced > or = 40-fold. These results, in conjunction with the mutant phenotype described previously, demonstrate that cp-SecA functions in vivo to facilitate the translocation of OEC33, PSI-F and plastocyanin but does not function in the translocation of OEC23 and OEC16. Our results confirm predictions for cp-SecA function made from the results of in vitro experiments and establish several new functions for cp-SecA, including roles in the targeting of a chloroplast-encoded protein, cytochrome f, and in protein targeting in the etioplast, a nonphotosynthetic plastid type. Our finding that the accumulation of properly targeted plastocyanin and cytochrome f in tha1-ref thylakoid membranes is reduced only a few-fold despite the near or complete absence of cp-SecA suggests that cp-SecA facilitates but is not essential in vivo for their translocation across the membrane.     

Biotinylation in vivo as a sensitive indicator of protein secretion and membrane protein insertion

Escherichia coli biotin ligase is a cytoplasmic protein which specifically biotinylates the biotin-accepting domains from a variety of organisms. This in vivo biotinylation can be used as a sensitive signal to study protein secretion and membrane protein insertion. When the biotin-accepting domain from the 1.3S subunit of Propionibacterium shermanii transcarboxylase (PSBT) is translationally fused to the periplasmic proteins alkaline phosphatase and maltose-binding protein, there is little or no biotinylation of PSBT in wild-type E. coli. Inhibition of SecA with sodium azide and mutations in SecB, SecD, and SecF, all of which slow down protein secretion, result in biotinylation of PSBT. When PSBT is fused to the E. coli inner membrane protein MalF, it acts as a topological marker: fusions to cytoplasmic domains of MalF are biotinylated, and fusions to periplasmic domains are generally not biotinylated. If SecA is inhibited by sodium azide or if the SecE in the cell is depleted, then the insertion of the MalF second periplasmic domain is slowed down enough that PSBT fusions in this part of the protein become biotinylated. Compared with other protein fusions that have been used to study protein translocation, PSBT fusions have the advantage that they can be used to study the rate of the insertion process.     

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.     

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.     

Outcomes of acute myocardial infarction in the Department of Veterans Affairs: does regionalization of health care work?

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.     

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.     

Coupled structure changes of SecA and SecG revealed by the synthetic lethality of the secAcsR11 and delta secG::kan double mutant

An Escherichia coli strain carrying either the secAcsR11 or delta secG::kan mutation is unable to grow at low temperature owing to cold-sensitive protein translocation but grows normally at 37 degree C. However, introduction of the two mutations into the same cells caused a severe defect in protein translocation and the cells were unable to grow at any temperature examined, indicating that secG is essential for the secAcsR11 mutant. The mutant SecA (csSecA) was found to possess a single amino acid substitution in the precursor-binding region and was defective in the interaction with the precursor protein. Furthermore, the membrane insertion of SecA and the membrane topology inversion of SecG, both of which took place upon the initiation of protein translocation, were significantly retarded even at 37 degree C, when csSecA was used instead of the wild-type SecA. The insertion of the wild-type SecA was also significantly defective when SecG-depleted membrane vesicles were used in place of SecG-containing ones. No insertion of csSecA occurred into SecG-depleted membrane vesicles. Examination of in vitro protein translocation at 37 degree C revealed that SecG is essential for csSecA-dependent protein translocation. We conclude that SecG and SecA undergo a coupled structure change, that is critical for efficient protein translocation.     

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.     

The Escherichia coli SRP and SecB targeting pathways converge at the translocon

Two distinct protein targeting pathways can direct proteins to the Escherichia coli inner membrane. The Sec pathway involves the cytosolic chaperone SecB that binds to the mature region of pre-proteins. SecB targets the pre-protein to SecA that mediates pre-protein translocation through the SecYEG translocon. The SRP pathway is probably used primarily for the targeting and assembly of inner membrane proteins. It involves the signal recognition particle (SRP) that interacts with the hydrophobic targeting signal of nascent proteins. By using a protein cross-linking approach, we demonstrate here that the SRP pathway delivers nascent inner membrane proteins at the membrane. The SRP receptor FtsY, GTP and inner membranes are required for release of the nascent proteins from the SRP. Upon release of the SRP at the membrane, the targeted nascent proteins insert into a translocon that contains at least SecA, SecY and SecG. Hence, as appears to be the case for several other translocation systems, multiple targeting mechanisms deliver a variety of precursor proteins to a common membrane translocation complex of the E.coli inner membrane.     

Evidence that a globular conformation is not compatible with FhaC-mediated secretion of the Bordetella pertussis filamentous haemagglutinin

The 220 kDa Bordetella pertussis filamentous haemagglutinin (FHA) is the major extracellular protein of this organism. It is exported using a signal peptide-dependent pathway, and its secretion depends on one specific outer membrane accessory protein, FhaC. In this work, we have investigated the influence of conformation on the FhaC-mediated secretion of FHA using an 80kDa N-terminal FHA derivative, Fha44. In contrast to many signal peptide-dependent secretory proteins, no soluble periplasmic intermediate of Fha44 could be isolated. In addition, cell-associated Fha44 synthesized in the absence of FhaC did not remain competent for extracellular secretion upon delayed expression of FhaC, indicating that the translocation steps across the cytoplasmic and the outer membrane might be coupled. A chimeric protein, in which the globular B subunit of the cholera toxin, CtxB, was fused at the C-terminus of Fha44, was not secreted in B. pertussis or in Escherichia coli expressing FhaC. The hybrid protein was only secreted when both disulphide bond-forming cysteines of CtxB were replaced by serines or when it was produced in DsbA- E. coli. The Fha44 portion of the secretion-incompetent hybrid protein was partly exposed on the cell surface. These results argue that the Fha44-CtxB hybrid protein transited through the periplasmic space, where disulphide bond formation is specifically catalysed, and that secretion across the outer membrane was initiated. The folded CtxB portion prevented extracellular release of the hybrid, in contrast to the more flexible CtxB domain devoid of cysteines. We propose a secretion model whereby Fha44 transits through the periplasmic space on its way to the cell surface and initiates its translocation through the outer membrane before being released from the cytoplasmic membrane. Coupling of Fha44 translocation across both membranes would delay the acquisition of its folded structure until the protein emerges from the outer membrane. Such a model would be consistent with the extensive intracellular proteolysis of FHA derivatives in B. pertussis.     

Regulation of the Escherichia coli secA gene is mediated by two distinct RNA structural conformations

Expression from the secA gene, encoding a key component of the general secretory pathway of Escherichia coli, is influenced by the secretion status of the cell, autogenous translational repression, and translational coupling to the upstream gene, X. SecA binds to its mRNA in a region overlapping its ribosome binding site, thus competing with ribosomes that would initiate secA translation. Mapping of the geneX-secA mRNA secondary structure has demonstrated that the RNA can adopt two distinct conformations in solution. The first conformation arises from the base-pairing of the secA Shine-Dalgarno (SD) sequence with the geneX terminus. The second conformation, in which the secA SD sequence is no longer paired with the geneX terminus, contains a GC-rich stem upstream of the secA SD sequence. The presence of this GC-rich stem is supported by structure mapping of a mutant RNA containing a deletion in the geneX terminus. The former structure appears to be involved in translational coupling by directly linking the geneX and secA sequences, where geneX translation activates secA translational initiation through the unpairing and unmasking of the secA SD sequence. As indicated by SecA-RNA binding assays, the latter structure is probably involved in SecA binding and translational repression of the secA gene. The stabilizing effect of magnesium ions toward occlusion of the secA SD sequence supports the presence of RNA tertiary structure in this regulatory domain.     

Molecular characterization of a heme-binding protein of Bacteroides fragilis BE1

An iron-repressible 44-kDa outer membrane protein plays a crucial role in the acquisition of heme by the anaerobic bacterium Bacteroides fragilis. The DNA sequence of the gene encoding the 44-kDa protein (hupA) was determined. The hupA gene encodes a protein of 431 amino acid residues with a calculated molecular mass of 48,189 Da. The hupA gene is preceded by an open reading frame of 480 bp that probably encodes a protein with a calculated molecular mass of 18,073 Da. hupA and this open reading frame are likely organized in an operon, and a sequence homologous to the Escherichia coli consensus Fur box was present in the putative promoter region of the operon. Heme-binding studies showed that HupA binds heme. Analysis of the deduced amino acid sequence revealed signature heme-binding consensus motifs, characteristic of heme lyases. Subcellular localization studies in E. coli revealed that HupA was mainly found in the cytoplasmic membrane but not in the outer membrane of E. coli. This suggested that B. fragilis uses another strategy for the translocation of this outer membrane protein across its cell envelope than E. coli does. HupA did not have significant homology with other putative bacterial heme receptors.     

Translocation of N-terminal tails across the plasma membrane

Previously we have shown that the first hydrophobic domain of leader peptidase (lep) can function to translocate a short N-terminal 18 residue antigenic peptide from the phage Pf3 coat protein across the plasma membrane of Escherichia coli. We have now examined the mechanism of insertion of N-terminal periplasmic tails and have defined the features needed to translocate these regions. We find that short tails of up to 38 residues are efficiently translocated in a SecA- and SecY-independent manner while longer tails are very poorly inserted. Efficient translocation of a 138 residue tail is restored and is Sec-dependent by the addition of a leader sequence to the N-terminus of the protein. We also find that while there is no amphiphilic helix requirement for N-terminal translocation, there is a charge requirement that is needed within the tail; an arginine and lysine residue can inhibit or completely block translocation when introduced into the tail region. Intriguingly, the membrane potential is required for insertion of a 38 residue tail but not for a 23 residue tail.