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.

Conformational stabilization and crystallization of the SecA translocation ATPase from Bacillus subtilis.

SecA is the peripheral membrane-associated subunit of the enzyme complex 'preprotein translocase' which assists the selective transport of presecretory proteins into and across bacterial membranes. The SecA protein acts as the molecular motor that drives the translocation of presecretory proteins through the membrane in a stepwise fashion concomitant with large conformational changes accompanying its own membrane insertion/retraction reaction cycle coupled to ATPase activity. The high flexibility of SecA causes a dynamic conformational heterogeneity which presents a barrier to growth of crystals of high diffraction quality. As shown by fluorescence spectroscopy, the T(m) of the endothermic transition of cytosolic SecA from Bacillus subtilis is shifted to higher temperatures in the presence of 30% glycerol, indicating stabilization of the protein in its compact membrane-retracted conformational state. High glycerol concentrations are also necessary to obtain three-dimensional crystals suitable for X-ray diffraction analysis, suggesting that stabilization of the conformational dynamics of SecA may be required for effective crystallization. The SecA crystals grow as hexagonal bipyramids in the trigonal space group P3(1)12; they possess unit-cell parameters a = 130.8, b = 130.8, c = 150.4 A at 100 K and diffract X-rays to approximately 2.70 A using a high-flux synchrotron-radiation source.

Characterization of Borrelia burgdorferi BlyA and BlyB proteins: a prophage-encoded holin-like system.

The conserved cp32 plasmid family of Borrelia burgdorferi was recently shown to be packaged into a bacteriophage particle (C. H. Eggers and D. S. Samuels, J. Bacteriol. 181:7308-7313, 1999). This plasmid encodes BlyA, a 7.4-kDa membrane-interactive protein, and BlyB, an accessory protein, which were previously proposed to comprise a hemolysis system. Our genetic and biochemical evidence suggests that this hypothesis is incorrect and that BlyA and BlyB function instead as a prophage-encoded holin or holin-like system for this newly described bacteriophage. An Escherichia coli mutant containing the blyAB locus that was defective for the normally cryptic host hemolysin SheA was found to be nonhemolytic, suggesting that induction of sheA by blyAB expression was responsible for the hemolytic activity observed previously. Analysis of the structural features of BlyA indicated greater structural similarity to bacteriophage-encoded holins than to hemolysins. Consistent with holin characteristics, subcellular localization studies with E. coli and B. burgdorferi indicated that BlyA is solely membrane associated and that BlyB is a soluble protein. Furthermore, BlyA exhibited a holin-like function by promoting the endolysin-dependent lysis of an induced lambda lysogen that was defective in the holin gene. Finally, induction of the cp32 prophage in B. burgdorferi dramatically stimulated blyAB expression. Our results provide the first evidence of a prophage-encoded holin within Borrelia.

Bacteriophages of spirochetes.

Historically, a number of bacteriophage-like particles have been observed in association with members of the bacterial order Spirochetales, the spirochetes. In the last decade, several spirochete bacteriophages have been isolated and characterized at the molecular level. We have recently characterized a bacteriophage of the Lyme disease agent, Borrelia burgdorferi, which we have designated phiBB-1. Here we review the history of the association between the spirochetes and their bacteriophages, with a particular emphasis on phiBB-1 and its prophage, the 32-kb circular plasmid family of B. burgdorferi.

Lyme disease-causing Borrelia species encode multiple lipoproteins homologous to peptide-binding proteins of ABC-type transporters.

To identify cell envelope proteins of Borrelia burgdorferi, the causative agent of Lyme disease, we constructed a library of B. burgdorferi genes fused to the Escherichia coli phoA gene, which expresses enzymatically active alkaline phosphatase. One such gene, oppA-1, encodes a predicted polypeptide with significant similarities to various peptide-binding proteins of ABC-type transporters. Immediately downstream of oppA-1 are two genes, oppA-2 and oppA-3, whose predicted polypeptide products show strong similarities in their amino acid sequences to OppA-1, including a sequence that resembles the most highly conserved region in peptide-binding proteins. By labeling with [3H]palmitate, OppA-1, OppA-2, and OppA-3 were shown to be lipoproteins. DNA hybridization analysis showed that the oppA-1 oppA-2 oppA-3 region is located on the linear chromosome of B. burgdorferi, and the genes are conserved among different Borrelia species that cause Lyme disease (B. burgdorferi, B. garinii, and B. afzelli), suggesting that all three homologous genes are important to the maintenance of Lyme disease spirochetes in one or more of their hosts.

Cloning and analysis of a Borrelia burgdorferi membrane-interactive protein exhibiting haemolytic activity.

We cloned the gene encoding a membrane-interactive protein of Borrelia burgdorferi by means of its haemolytic activity in Escherichia coli. The haemolytic activity was erythrocyte-species specific, with progressively decreasing activity for erythrocytes from horse, sheep, and rabbit, respectively. Genetic analysis of the haemolytic determinant revealed two borrelia haemolysin genes, blyA and blyB, that are part of a predicted four-gene operon which is present in multiple copies on the 30 kb circular plasmid(s) of B. burgdorferi B31. blyA encodes a predicted alpha-helical 7.4 kDa protein with a hydrophobic central region and a positively charged C-terminus, which is structurally homologous to a large group of pore-forming toxins with cytolytic activity. blyB encodes a soluble protein which stabilized BlyA and enhanced haemolytic activity. While the majority of BlyA in E. coli was membrane-associated, only soluble protein was haemolytically active. The haemolytic activity was shown to be highly protease sensitive, heat labile, independent of divalent cations, and extremely dependent on protein concentration, consistent with a requirement for oligomerization as the mechanism of action. BlyA was highly purified from E. coli in a single step utilizing Triton X-114 phase partitioning. Genetic analysis of blyA and blyB mutants indicated that the stability, membrane association, and activity of BlyA was dependent on subtle changes in its sequence and on the BlyB protein. The bly genes were found to be expressed at a very low level in cultured B. burgdorferi.

SecA membrane cycling at SecYEG is driven by distinct ATP binding and hydrolysis events and is regulated by SecD and SecF.

The SecA subunit of E. coli preprotein translocase promotes protein secretion during cycles of membrane insertion and deinsertion at SecYEG. This process is regulated both by nucleotide binding and hydrolysis and by the SecD and SecF proteins. In the presence of associated preprotein, the energy of ATP binding at nucleotide-binding domain 1 (NBD1) drives membrane insertion of a 30 kDa domain of SecA, while deinsertion of SecA requires the hydrolysis of this ATP. SecD and SecF stabilize the inserted state of SecA. ATP binding at NBD2, though needed for preprotein translocation, is not needed for SecA insertion or deinsertion.

Escherichia coli SecY and SecE proteins appear insufficient to constitute the SecA receptor.

In order to test whether SecY and SecE proteins constitute the SecA receptor inside out membrane vesicles where prepared from strains producing greatly different levels of these two proteins, and their SecA binding activity was quantitated. Substantial overproduction of SecE or SecY and SecE proteins resulted in no increase or only 50% increase, respectively, in the number of high affinity SecA binding sites. These results suggest that SecY and SecE proteins appear insufficient to constitute the primary SecA receptor. The existence of a cycle of SecA association with the inner membrane and its modulation by particular integral membrane proteins is discussed.

SecA protein: autoregulated ATPase catalysing preprotein insertion and translocation across the Escherichia coli inner membrane.

Recent insight into the biochemical mechanisms of protein translocation in Escherichia coli indicates that SecA ATPase is required both for the initial binding of preproteins to the inner membrane as well as subsequent translocation across this structure. SecA appears to promote these events by direct recognition of the preprotein or preprotein-SecB complex, binding to inner-membrane anionic phospholipids, insertion into the membrane bilayer and association with the preprotein translocator, SecY/SecE. ATP binding appears to control the affinity of SecA for the various components of the system and ATP hydrolysis promotes cycling between its different biochemical states. As a component likely to catalyse a rate-determining step in protein secretion, SecA synthesis is co-ordinated with the activity of the protein export pathway. This form of negative regulation appears to rely on SecA protein binding to its mRNA and repressing translation if conditions of rapid protein secretion prevail within the cell. A precise biochemical scheme for SecA-dependent catalysis of protein export and the details of secA regulation appear to be close at hand. The evolutionary conservation of SecA protein among eubacteria as well as the general requirement for translocation ATPases in other protein secretion systems argues for a mechanistic commonality of all prokaryotic protein export pathways.

Electron microscopy of thin-sectioned three-dimensional crystals of SecA protein from Escherichia coli: structure in projection at 40 A resolution.

SecA is a single-chain, membrane-associated polypeptide (102 kDa) which functions as an essential component of the protein export machinery of Escherichia coli. SecA has been crystallized from ammonium sulfate as small, three-dimensional bipyramidal crystals (0.1 x 0.1 x 0.05 mm). These crystals did not demonstrate detectable diffraction of X-rays from rotating anode sources. For study by electron microscopy, individual crystals were cross-linked in glutaraldehyde and OsO4 solutions, dehydrated, embedded in epoxy resin, and sectioned normal to crystallographic axial directions inferred from the external morphology of the crystals. Fourier transformation of processed images of untilted thin sections stained with uranyl acetate and lead citrate show reflections extending to 31 A resolution. Diffraction data and reconstructed images of the projected density of the unit cell contents indicate that the bipyramidal SecA crystals belong to orthorhombic space group C222(1) with unit cell dimensions a = 414 A, b = 381 A, and c = 243 A. Filtered images and density maps of mutually orthogonal projections of the unit cell contents are consistent with a three-dimensional model in which the asymmetric unit contains eight SecA monomers. The large unit cell dimensions and packing of protein monomers suggest that SecA is crystallizing as an oligomer of either dimers or tetramers.

Deep penetration of a portion of Escherichia coli SecA protein into model membranes is promoted by anionic phospholipids and by partial unfolding.

SecA protein, a principal component of the protein export machinery of Escherichia coli, is found both in the cytoplasm and inner membrane of cells. Previous in vitro and in vivo studies demonstrated that the interaction of SecA with the inner membrane requires the presence of physiological levels of anionic (acidic) phospholipids. In this report the degree of SecA insertion into model membranes and the conformational changes associated with this event have been examined. The extent of association of SecA with model membranes was determined by photolabeling with a hydrophobic reagent, and the depth of insertion of the protein into the phospholipid bilayer was determined by the amount of quenching of SecA fluorescence by both brominated and spin-labeled phospholipids. These methods demonstrated that SecA penetrates deep within the acyl chain region of the phospholipid bilayer. It was also found that SecA penetration into vesicles was associated with a major conformational change in the protein. This change can be induced by higher temperatures and involves a partial unfolding event as judged by differential scanning calorimetry, SecA fluorescence and increased sensitivity to proteolysis. These properties suggest the induction of a molten-globule-like conformation in a portion of the SecA polypeptide. This change was also induced at lower temperatures by the presence of membranes containing a physiological amount of the anionic phospholipid, phosphatidylglycerol. The partial unfolding and concomitant deep insertion of SecA into membranes may aid in the insertion of precursor proteins into the inner membrane and may influence possible interactions between SecA and the integral membrane export machinery components.

Characterization of membrane-associated and soluble states of SecA protein from wild-type and SecA51(TS) mutant strains of Escherichia coli.

The subcellular localization of SecA, a protein essential for the catalysis of general protein export, was studied to better understand its state(s) and function(s) within Escherichia coli cells. In a wild-type strain approximately half of the cellular SecA content was found to be associated with the inner membrane, while the remainder was soluble. Association of SecA protein with the inner membrane required the presence of anionic phospholipids and was modulated by ATP. A fraction of the membrane-bound SecA was found to be integrally associated with the membrane. In the secA51(Ts) mutant 75-95% of SecA protein was found to be membrane associated, independent of the protein export status of the cell, implying that the partitioning of this protein between the cell membrane and cytoplasm may play an important role in its function. secA-lacZ fusions were used to map a membrane association determinant to the amino-terminal quarter of SecA protein sequence. When this portion of SecA protein was expressed within cells, it was found solely in membrane fractions and complemented the growth and protein secretion defect of the secA51(Ts) mutant. This indicates that the membrane is the site of the limiting defect in this mutant and suggests that either SecA functions can be divided into at least two separable activities or that productive interaction between SecA and the amino-terminal fragment can occur in vivo.

Characterization of Escherichia coli SecA protein binding to a site on its mRNA involved in autoregulation.

In order to understand further the autogenous regulation of Escherichia coli secA translation, we have set up a purified system to study the binding of SecA protein to portions of its mRNA. Specific SecA protein-RNA binding was demonstrated by UV cross-linking, filter binding, and gel shift assays. Use of the filter binding assay allowed optimization of binding, which was influenced by Mg2+ and ATP concentrations, and a measurement of the affinity of this interaction. A nested series of RNAs lacking either 5' or 3' portions of geneX-secA sequences were used to localize the SecA protein binding site to sequences around the geneX-secA intergenic region. These studies imply that SecA protein directly regulates its own translation by a specific RNA binding activity that presumably blocks translational initiation.

The first gene in the Escherichia coli secA operon, gene X, encodes a nonessential secretory protein.

TnphoA insertions in the first gene of the Escherichia coli secA operon, gene X, were isolated and analyzed. Studies of the Gene X-PhoA fusion proteins showed that gene X encodes a secretory protein, since the fusion proteins possessed normal alkaline phosphatase activity and a substantial portion of this activity was found in the periplasm. In addition, the Gene X-PhoA fusion proteins were initially synthesized with a cleavable signal peptide. A gene X::TnphoA insertion was used to construct a strain containing a disrupted chromosomal copy of gene X. Analysis of this strain indicated that gene X is nonessential for cell growth and viability and does not appear to play an essential role in the process of protein export.

Regulation of Escherichia coli secA mRNA translation by a secretion-responsive element.

The Escherichia coli secA gene, whose translation is responsive to the proficiency of protein export within the cell, is the second gene in a three-gene operon and is flanked by gene X and mutT. By using gene fusion and oligonucleotide-directed mutagenesis techniques, we have localized this translationally regulated site to a region at the end of gene X and the beginning of secA. This region has been shown to bind SecA protein in vitro. These studies open the way for a direct investigation of the mechanism of secA regulation and its coupling to the protein secretion capability of the cell.

Isolation and analysis of dominant secA mutations in Escherichia coli.

The secA gene product is an autoregulated, membrane-associated ATPase which catalyzes protein export across the Escherichia coli plasma membrane. Previous genetic selective strategies have yielded secA mutations at a limited number of sites. In order to define additional regions of the SecA protein that are important in its biological function, we mutagenized a plasmid-encoded copy of the secA gene to create small internal deletions or duplications marked by an oligonucleotide linker. The mutagenized plasmids were screened in an E. coli strain that allowed the ready detection of dominant secA mutations by their ability to derepress a secA-lacZ protein fusion when protein export is compromised. Twelve new secA mutations were found to cluster into four regions corresponding to amino acid residues 196 to 252, 352 to 367, 626 to 653, and 783 to 808. Analysis of these alleles in wild-type and secA mutant strains indicated that three of them still maintained the essential functions of SecA, albeit at a reduced level, while the remainder abolished SecA translocation activity and caused dominant protein export defects accompanied by secA depression. Three secA alleles caused dominant, conditional-lethal, cold-sensitive phenotypes and resulted in some of the strongest defects in protein export characterized to date. The abundance of dominant secA mutations strongly favors certain biochemical models defining the function of SecA in protein translocation. These new dominant secA mutants should be useful in biochemical studies designed to elucidate SecA protein's functional sites and its precise role in catalyzing protein export across the plasma membrane.

Azide-resistant mutants of Escherichia coli alter the SecA protein, an azide-sensitive component of the protein export machinery.

Escherichia coli azi mutants, whose growth is resistant to millimolar concentrations of sodium azide, were among the earliest E. coli mutants isolated. Genetic complementation, mapping, and DNA sequence analysis now show that these mutations are alleles of the secA gene, which is essential for protein export across the E. coli plasma membrane. We have found that sodium azide is an extremely rapid and potent inhibitor of protein export in vivo and that azi mutants are more resistant to such inhibition. Furthermore, SecA-dependent in vitro protein translocation and ATPase activities are inhibited by sodium azide, and SecA protein prepared from an azi mutant strain is more resistant to such inhibition. These studies point to the utility of specific inhibitors of protein export, such as sodium azide, in facilitating the dissection of the function of individual components of the protein export machinery.

SecA protein: autoregulated initiator of secretory precursor protein translocation across the E. coli plasma membrane.

Several classes of secA mutants have been isolated which reveal the essential role of this gene product for E. coli cell envelope protein secretion. SecA-dependent, in vitro protein translocation systems have been utilized to show that SecA is an essential, plasma membrane-associated, protein translocation factor, and that SecA's ATPase activity appears to play an essential but as yet undefined role in this process. Cell fractionation studies suggested that SecA protein is in a dynamic state within the cell, occurring in soluble, peripheral, and integral membraneous states. These data have been used to argue that SecA is likely to promote the initial insertion of secretory precursor proteins into the plasma membrane in a manner dependent on ATP hydrolysis. The protein secretion capability of the cell has been shown to translationally regulate secA expression with SecA protein serving as an autogenous repressor, although the exact mechanism and purpose of this regulation need to be defined further.

Isolation of a secY homologue from Bacillus subtilis: evidence for a common protein export pathway in eubacteria.

Genetic and biochemical studies have shown that the product of the Escherichia coli secY gene is an integral membrane protein with a central role in protein secretion. We found the Bacillus subtilis secY homologue within the spc-alpha ribosomal protein operon at the same position occupied by E. coli secY. B. subtilis secY coded for a hypothetical product 41% identical to E. coli SecY, a protein thought to contain 10 membrane-spanning segments and 11 hydrophilic regions, six of which are exposed to the cytoplasm and five to the periplasm. We predicted similar segments in B. subtilis SecY, and the primary sequences of the second and third cytoplasmic regions and the first, second, fourth, fifth, seventh, and tenth membrane segments were particularly conserved, sharing greater than 50% identity with E. coli SecY. We propose that the conserved cytoplasmic regions interact with similar cytoplasmic secretion factors in both organisms and that the conserved membrane-spanning segments actively participate in protein export. Our results suggest that despite the evolutionary differences reflected in cell wall architecture, Gram-negative and Gram-positive bacteria possess a similar protein export apparatus.

SecA protein autogenously represses its own translation during normal protein secretion in Escherichia coli.

The Escherichia coli secA gene, whose expression is responsive to the protein secretion status of the cell, is the second gene in an operon. We found that both the basal and induced levels of SecA biosynthesis are dependent on prior translation of the upstream gene, gene X, and identified two large gene X-secA transcripts. The 10-fold derepression of secA expression by protein export defects was at the translational level since no further increases in gene X or secA mRNA levels were detected during this period, and a secA-lacZ protein fusion but not an operon fusion was appropriately derepressed. Furthermore, overexpression of the SecA protein severely reduced expression of only the secA-lacZ protein fusion, indicating that SecA autogenously represses its own translation.