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

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.

Elevated cytosolic concentrations of SecA compensate for a protein translocation defect in Escherichia coli cells with reduced levels of negatively charged phospholipids

Cellular extracts from cells with reduced synthesis of negatively charged phospholipids were found to support in vitro translocation of the precursor of the outer membrane protein PhoE with increased efficiency. Analysis of these extracts revealed that they contain increased levels of SecA. SecA depletion resulted in a loss of the translocation stimulatory activity, which could be restored by re-addition of purified SecA. We conclude that elevated cytosolic levels of SecA counteract the reduction of translocation efficiency due to low levels of negatively charged phospholipids in the inner membrane.

Bacterial protein translocation: kinetic and thermodynamic role of ATP and the protonmotive force

The energetic mechanism of preprotein export in Escherichia coli has been a source of controversy for many years. In vitro studies of translocation reactions that use purified soluble and membrane components have not clarified the main features of this mechanism. Translocation occurs through consecutive steps which each have distinct energy requirements. Initiation of translocation requires ATP and the SecA protein. Most of the further steps can be driven by the protonmotive force (delta p).

Protein secretion in Gram-positive bacteria

Gram-positive bacteria often secrete large amounts of proteins into the surrounding medium. This feature makes them attractive as hosts for the industrial production of extracellular enzymes. Compared to Escherichia coli, relatively little is known about the mechanism of protein secretion in these organisms. However, the recent identification of Bacillus subtilis genes whose gene products are highly homologous to some of the Sec (secretion) proteins of E. coli strongly suggests that important principles of protein translocation across the plasma membrane might be highly conserved. In contrast, the steps following the actual translocation event might be different in Gram-positive and Gram-negative bacteria. The scope of this review is to outline the recent progress that has been made in the elucidation of the secretion pathway in Gram-positive bacteria and to discuss potential applications in strain improvement for the industrial production of extracellular proteins.

Autogenous translation regulation by Escherichia coli ATPase SecA may be mediated by an intrinsic RNA helicase activity of this protein

The seven conserved motifs typical of the helicase superfamily II have been identified in the sequences of Escherichia coli protein SecA, an ATPase mediating protein translocation across the inner membrane of the bacterium, and its Bacillus subtilis homolog Div. It is hypothesized that SecA and Div possess an RNA helicase activity and may couple ATP hydrolysis both to membrane translocation of proteins, and to hairpin unwinding in their own mRNAs, leading to the known autogenous regulation of translation.

SecA insertion into phospholipids is stimulated by negatively charged lipids and inhibited by ATP: a monolayer study

SecA-lipid interactions are believed to be important for the translocation of precursor proteins across the inner membrane of Escherichia coli [Lill, R., Dowhan, W., & Wickner, W. (1990) Cell 60, 271-280]. SecA insertion into the phospholipid bilayer could a role in this process. We investigated this possibility by studying the interactions between SecA and different phospholipids using the monolayer technique. It was established that SecA is surface-active and can insert into lipid monolayers. This insertion was greatly enhanced by the negatively charged lipids DOPG and Escherichia coli cardiolipin. Insertion of SecA into these negatively charged lipids could be detected up to initial surface pressures of 34 mN/m for DOPG and 36 mN/m for Escherichia coli cardiolipin, implying a possible role for negatively charged lipids in the insertion of SecA in biological membranes. High salt concentrations did not inhibit the SecA insertion into DOPG monolayers, suggesting not only an electrostatic but also a hydrophobic interaction of SecA with the lipid monolayer. ATP decreased both the insertion (factor 2) and binding (factor 3) of SecA to DOPG monolayers. ADP and phosphate gave a decrease in the SecA insertion to the same extent as ATP, but the binding of SecA was only slightly reduced. AMP-PNP and ATP-gamma-S did not have large effects on the insertion or on the binding of SecA to DOPG monolayers. The physiological significance of these results in protein translocation is discussed.

Skp is a periplasmic Escherichia coli protein requiring SecA and SecY for export

Skp of Escherichia coli (OmpH of Salmonella typhimurium) is a protein whose precise function has been obscured by its ubiquity in a wide range of subcellular fractions such as those containing DNA, ribosomes, and outer membranes. Combining in vitro and in vivo techniques we show that Skp is synthesized as a larger precursor that is processed upon translocation across the plasma membrane. Translocation is dependent on the H(+)-gradient, ATP, SecA, and SecY. Upon cellular subfractionation (avoiding non-specific electrostatic interactions) Skp partitions with beta-lactamase into the fraction of soluble, periplasmic proteins. In the context of the export factor properties of Skp previously demonstrated in vitro it is conceivable that this protein is involved in the later steps of protein translocation across the plasma membrane and/or sorting to the outer membrane.

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.

Identification of a gene fragment which codes for the 364 amino-terminal amino acid residues of a SecA homologue from Bacillus subtilis: further evidence for the conservation of the protein export apparatus in gram-positive and gram-negative bacteria

A DNA fragment that codes for the 364 amino-terminal amino acid residues of a putative Bacillus subtilis SecA homologue has been cloned using the Escherichia coli secA gene as a probe. The deduced amino acid sequence showed 58% identity to the amino-terminus of the E. coli SecA protein. A DNA fragment which codes for 275 amino-terminal amino acid residues of the B. subtilis SecA homologue was expressed in E. coli and the corresponding gene product was shown to be recognized by anti-E. coli SecA antibodies. This polypeptide, although only about 30% the size of the E. coli SecA protein, also restored growth of E. coli MM52 (secAts) at the non-permissive temperature and the translocation defect of proOmpA in this mutant was relieved to a substantial extent.

Reconstitution of a protein translocation system containing purified SecY, SecE, and SecA from Escherichia coli

Reconstitution of the translocation machinery for secretory proteins from purified constituents was performed. SecY was solubilized from SecY/SecE-overproducing Escherichia coli cells and purified by chromatography on ion-exchange and size-exclusion columns. Proteoliposomes active in protein translocation were reconstituted from the purified preparations of SecY and SecE. The reconstituted translocation activity was SecA- and ATP-dependent. Although the purified preparations of SecY and SecE were still contaminated with minute amounts of other proteins, the elution profiles of SecY and SecE on column chromatographies coincided with the elution profiles of reconstituted translocation activity, indicating that SecY and SecE are the indispensable components in these preparations. We conclude that SecY, SecE, and SecA are essential components of the protein secretion machinery and that translocation activity can be reconstituted from only these three proteins and phospholipids.

SecY is an indispensable component of the protein secretory machinery of Escherichia coli

Using a reconstitution system for protein translocation, the involvement of SecY in the translocation of secretory proteins across the cytoplasmic membrane of Escherichia coli was studied. Anti-SecY antibodies raised against the N- and C-terminal sequences prevented the functional reconstitution of the translocation system. Depletion of SecY from the solubilized membrane preparation was performed by treatment with anti-SecY IgG, followed by removal of IgG with protein A-agarose. The SecY-depleted preparation was inactive as to functional reconstitution. However, reconstitution with it was demonstrated in the presence of a protein fraction, which was released from the anti-SecY immunoprecipitate upon addition of the SecY fragment used to raise the antibody. Reconstitution with the SecY-depleted membrane fraction was also demonstrated in the presence of a purified SecY preparation. OmpT proteinase specifically cleaved SecY in the solubilized membrane preparation. The cleavage was accompanied by a decrease in the reconstituted activity. Based on these findings we conclude that SecY is an indispensable component of the secretory machinery.

Recognition of nascent polypeptides for targeting and folding

A major difference between the refolding of proteins in vitro and the in vivo folding process, in which we include localization and assembly, is the need for additional factors in vivo, apart from the protein product itself. Thus, the amino acid sequence of a naturally selected protein contains not only the information specifying its three-dimensional structure, but also the information that enables these factors to recognize the nascent polypeptide. In this review, we consider how this latter information may be encoded and, in turn, interpreted by binding species.

SecA, an essential component of the secretory machinery of Escherichia coli, exists as homodimer

Size exclusion chromatography of the cytosolic fraction of SecA-overproducing cells of Escherichia coli suggested that SecA, an essential component of the secretory machinery, exists as an oligomer. The subunit structure of SecA was then studied using a purified specimen. Estimation of the molecular mass by means of ultracentrifugation and chemical crosslinking analysis revealed that SecA exists as a homodimer. The purified SecA was denatured in 6 M guanidine-HCl and renatured to a dimer, which was fully active in terms of translocation, even in the presence of 1 mM dithiothreitol. It is suggested that the dimeric structure is not critically maintained by disulfide bonding between the two subunits, each of which contains four cysteine residues.

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.

The genetics of protein secretion in E. coli

Genetic studies have identified six genes whose products comprise the general protein secretion machinery of Escherichia coli. Insights from mutant analysis and the biochemical properties of the purified components allows the secretion pathway to be described in some detail. The picture emerging provides a useful paradigm for similar pathways in other organisms.