Export of Escherichia coli alkaline phosphatase attached to an integral membrane protein, SecY

The SecY protein is a membrane-bound factor required for bacterial protein export and embedded in the cytoplasmic membrane by its 10 transmembrane segments. We previously proposed a topology model for this protein by adapting the Manoil-Beckwith TnphoA approach, a genetic method to assign local disposition of a membrane protein from the enzymatic activity of the alkaline phosphatase (PhoA) mature sequence attached to the various regions. SecY-PhoA hybrid proteins with the PhoA domain exported to the periplasmic side of the membrane have been obtained at the five putative periplasmic domains of the SecY sequence. We now extended this method to apply it to follow export of the newly synthesized PhoA domain. Trypsin treatment of detergent-solubilized cell extracts digested the internalized (unfolded) PhoA domain but not those exported and correctly folded. One of the hybrid proteins was cleaved in vivo after export to the periplasm, providing a convenient indication for the export. Results of these analyses indicate that export of the PhoA domain attached to different periplasmic regions of SecY occurs rapidly and requires the normal functioning of the secY gene supplied in trans. Thus, this membrane protein with multiple transmembrane segments contains multiple export signals which can promote rapid and secY-dependent export of the PhoA mature sequence attached to the carboxyl-terminal sides.     

Sequence homology between the tetracycline-resistance determinants of Tn10 and pBR322

The Tn10 tetracycline resistance gene, tetA, encodes a tetracycline-inducible protein with an apparent Mr of 36 X 10(3). We have determined the nucleotide sequence of the Tn10 tetA gene. The extent of the tetA gene was determined by analysis of amino-terminal and carboxy-terminal deletion mutants. We conclude that a single Tn10 gene, the tetA gene, is sufficient to confer tetracycline resistance. The predicted Mr of the tetA protein is 43.2 X 10(3). The sequence homology between the Tn10 tetA gene and the pBR322 tetracycline resistance determinant (49% nucleotide homology, 44% amino acid homology) indicates that these phenotypically distinct tetracycline-resistance determinants must have evolved from a common ancestral sequence. The markedly hydrophobic character of the predicted amino acid sequences of the Tn10 tetA and pBR322 tet-coded proteins suggests that a substantial portion of these proteins may be embedded within the cytoplasmic membrane.     

A positively charged region is a determinant of the orientation of cytoplasmic membrane proteins in Escherichia coli

Basic amino acid residues were introduced into an extracellular (periplasmic) domain, preceding a membrane-spanning hydrophobic domain, of SecY, an integral cytoplasmic membrane protein. The localization of the domain was monitored as to the alkaline phosphatase activity of TnPhoA fused adjacent to the domain. The alkaline phosphatase activity of such Escherichia coli cells drastically decreased when positive charges were introduced, indicating that on the introduction the SecY domain showed a change in localization from the periplasm to the cytoplasm. In another experiment, positive charges were introduced to the same periplasmic domain of another SecY-PhoA fusion protein, in which PhoA is fused to the cytoplasmic domain of SecY following the particular hydrophobic domain. The alkaline phosphatase activity increased drastically when positive charges were introduced, indicating that the SecY domain fused to PhoA showed a change in localization from the cytoplasm to the periplasm. In both experiments, the removal of a large amino-terminal portion of the SecY domain did not alter the effect of the positive charge introduction. Changes in localization of SecY domains thus demonstrated were also supported by a protease accessibility test on spheroplasts. It is proposed that a positively charged region adjacent to a membrane-embedded hydrophobic region tends to be stabilized on the cytoplasmic surface of the membrane, which in turn endows the hydrophobic region with the ability to act as a stop-transfer sequence or a signal sequence and consequently determines the orientation of the hydrophobic region in the membrane.     

Export of FepA::PhoA fusion proteins to the outer membrane of Escherichia coli K-12.

A library of fepA::phoA gene fusions was generated in order to study the structure and secretion of the Escherichia coli K-12 ferric enterobactin receptor, FepA. All of the fusion proteins contained various lengths of the amino-terminal portion of FepA fused in frame to the catalytic portion of bacterial alkaline phosphatase. Localization of FepA::PhoA fusion proteins in the cell envelope was dependent on the number of residues of mature FepA present at the amino terminus. Hybrids containing up to one-third of the amino-terminal portion of FepA fractionated with their periplasm, while those containing longer sequences of mature FepA were exported to the outer membrane. Outer membrane-localized fusion proteins expressed FepA sequences on the external face of the outer membrane and alkaline phosphatase moieties in the periplasmic space. From sequence determinations of the fepA::phoA fusion joints, residues within FepA which may be exposed on the periplasmic side of the outer membrane were identified.     

Characterization of Escherichia coli expressing an Lpp’OmpA(46-159)-PhoA fusion protein localized in the outer membrane

 The Lpp′OmpA(46–159) hybrid protein can serve as an efficient targeting vehicle for localizing a variety of procaryotic and eucaryotic soluble proteins onto the E. coli surface, thus providing a system for several possible biotechnology applications. Here we show that fusions between Lpp′OmpA(46–159) and bacterial alkaline phosphatase (PhoA), a normally periplasmic dimeric enzyme, are also targeted to the outer membrane. However, protease accessibility experiments and immunoelectron microscopy revealed that, unlike other periplasmic proteins, the PhoA domain of these fusions is not exposed on the cell surface in cells having an intact outer membrane. Conditions that affect the formation of disulfide bonds and the folding of the PhoA domain in the periplasm not only did not facilitate targeting to the cell surface but led to lethality when the fusion was expressed from a high-copy-number plasmid. Furthermore, E. coli expressing the Lpp′OmpA(46–159)-PhoA fusion exhibited strain- and temperature-dependent alterations in outer-membrane permeability. Our results are consistent with previous studies with other vehicles indicating that PhoA is not displayed on the surface when fused to cell-surface expression vectors. Presumably, the enzyme rapidly assumes a tightly folded dimeric conformation that cannot be transported across the outer membrane. The large size and quaternary structure of PhoA may define a limitation of the Lpp′OmpA(46– 159) fusion system for the display of periplasmic proteins on the cell surface. Alkaline phosphatase is a unique protein among a group of five periplasmic proteins (β-lactamase, alkaline phosphatase, Cex cellulase, Cex cellulose-binding domain, and a single-chain Fv antibody fragment), which have been tested as passengers for the Lpp′OmpA(46–159) expression system to date, since it was the only protein not displayed on the surface. Received: 23 March 1995/Received revision: 29 July 1995/Accepted: 22 August 1995     

Topology analysis of the colicin V export protein CvaA in Escherichia coli.

The antibacterial protein toxin colicin V is secreted from Escherichia coli cells by a dedicated export system that is a member of the multicomponent ATP-binding cassette (ABC) transporter family. At least three proteins, CvaA, CvaB, and TolC, are required for secretion via this signal sequence-independent pathway. In this study, the subcellular location and transmembrane organization of membrane fusion protein CvaA were investigated. First, a series of CvaA-alkaline phosphatase (AP) protein fusions was constructed. Inner and outer membrane fractionations of cells bearing these fusions indicated that CvaA is inner membrane associated. To localize the fusion junctions, the relative activities of the fusion proteins, i.e., the amounts of phosphatase activity normalized to the rate of synthesis of each protein, as well as the stability of each fusion, were determined. These results indicated that all of the fusion junctions occur on the same side of the inner membrane. In addition, the relative activities were compared with that of native AP, and the protease accessibility of the AP moieties in spheroplasts and whole cells was analyzed. The results of these experiments suggested that the fusion junctions occur within periplasmic regions of CvA. We conclude that CvaA is an inner membrane protein with a single transmembrane domain near its N terminus; the large C-terminal region extends into the periplasm. This study demonstrates the application of AP fusion analysis to elucidate the topology of a membrane-associated protein having only a single transmembrane domain.     

Intracistronic complementation of the tetracycline resistance membrane protein of Tn10.

The structural gene region for tetracycline resistance on Tn10 consists of two complementation groups, tetA and tetB (M. S. Curiale and S. B. Levy, J. Bacteriol. 151:209-215, 1982). Using a series of deletion mutants, we have determined that the tetA region is 450 to 600 base pairs long and that the tetB region, which is adjacent to tetA, is 600 to 750 base pairs long. Point mutations in either tetA or tetB affected the amount and size of the inducible inner-membrane Tet protein synthesized in Escherichia coli maxicells. Moreover, deletions in these regions led to the synthesis of an appropriately smaller Tet protein. A single tetracycline-inducible RNA of about 1,200 bases was detected that was homologous with the tetracycline resistance structural gene region. These results indicate that the tetA and tetB complementation regions represent two parts of a single gene encoding two domains of the tetracycline resistance protein Tet.     

Requirements for translocation of periplasmic domains in polytopic membrane proteins.

Periplasmic domains of cytoplasmic membrane proteins require export signals for proper translocation. These signals were studied by using a MalF-alkaline phosphatase fusion in a genetic selection that allowed the isolation of mislocalization mutants. In the original construct, alkaline phosphatase is fused to the second periplasmic domain of the membrane protein, and its activity is thus confined exclusively to the periplasm. Mutants that no longer translocated alkaline phosphatase were selected by complementation of a serB mutation. A total of 11 deletions in the amino terminus were isolated, all of which spanned at least the third transmembrane segment. This domain immediately precedes the periplasmic domain to which alkaline phosphatase was fused. Our results obtained in vivo support the model that amino-terminal membrane-spanning segments are required for translocation of large periplasmic domains. In addition, we found that the inability to export the alkaline phosphatase domain could be suppressed by a mutation, prlA4, in the secretion apparatus.     

Identification and characterization of an Escherichia coli gene required for the formation of correctly folded alkaline phosphatase, a periplasmic enzyme.

Tn5 insertion mutations of Escherichia coli were isolated that impaired the formation of correctly folded alkaline phosphatase (PhoA) in the periplasm. The PhoA polypeptide synthesized in the mutants was translocated across the cytoplasmic membrane but not released into the periplasmic space. It was susceptible to degradation by proteases in vivo and in vitro. The wild-type counterpart of this gene (named ppfA) has been sequenced and shown to encode a periplasmic protein with a pair of potentially redox-active cysteine residues. PhoA synthesized in the mutants indeed lacked disulfide bridges. These results indicate that the folding of PhoA in vivo is not spontaneous but catalyzed at least at the disulfide bond formation step.     

Analysis of Escherichia coli TonB membrane topology by use of PhoA fusions.

Alkaline phosphatase (PhoA) fusions to TonB amino acids 32, 60, 125, 207, and 239 (the carboxy terminus) all showed high PhoA activity; a PhoA fusion to TonB amino acid 12 was inactive. The full-length TonB-PhoA fusion protein was associated with the cytoplasmic membrane and retained partial TonB function. These results support a model in which TonB is anchored in the cytoplasmic membrane by its hydrophobic amino terminus, with the remainder of the protein, including its hydrophobic carboxy terminus, extending into the periplasm.     

Analysis of tetracycline resistance encoded by transposon Tn10: deletion mapping of tetracycline-sensitive point mutations and identification of two structural genes

Deletions in the tet genes derived from Tn10 were formed from different tet::Tn5 insertion mutations by removing DNA sequences located between a HindIII site in Tn5 and a HindIII site adjacent to the tet genes. Tetracycline-sensitive point mutations were mapped in recombination tests with the deletions and were thus aligned with the genetic and physical map of the tet region. Plasmids carrying point mutations were tested for complementation with derivatives of pDU938, a plasmid carrying cloned tet genes derived from Tn10 which had been inactivated by Tn5 insertions. Complementation occurred between promoter-proximal tet point mutations and distal tet::Tn5 insertions, suggesting the existence of two structural genes, tetA and tetB. These results, together with the analysis of polypeptides in minicells harboring pDU938tet::Tn5 mutants, suggested that tetA and tetB are expressed coordinately in an operon. The tetB gene encodes the previously characterized 36,000-dalton cytoplasmic membrane TET protein, but the product of tetA was not identified. Point mutations in either tetA or tetB led to the defective expression of the resistance mechanism involving tetracycline efflux. It is suggested that the tetA and tetB products interact cooperatively in the membrane to express resistance.     

Membrane topology of the pBR322 tetracycline resistance protein. TetA-PhoA gene fusions and implications for the mechanism of TetA membrane insertion.

The tetracycline resistance gene of pBR322 encodes a 41-kDa inner membrane protein (TetA) that acts as a tetracycline/H+ antiporter. Based on hydrophobicity profiles, we identified 12 potential transmembrane segments in TetA. We used oligonucleotide deletion mutagenesis to fuse alkaline phosphatase (PhoA) to the C-terminal edge of each of the predicted periplasmic and cytoplasmic segments of TetA. In general, the PhoA activities of the TetA-PhoA fusions support a TetA topology model consisting of 12 transmembrane segments with the N and C termini in the cytoplasm. However, several TetA-PhoA fusions have unexpected properties. One PhoA fusion to a predicted cytoplasmic segment (C6) has high activity. However, previous protease accessibility studies on the related Tn10 TetA protein indicated that C6 is cytoplasmically localized as predicted (Eckert, B., and Beck, C. F. (1989) J. Biol. Chem. 264, 11663-11670). PhoA fusions to three predicted periplasmic segments (P1, P2, and P5) have low to intermediate activity. In each case, the preceding transmembrane segment (TM1, TM3, and TM9) contains an aspartate (Asp17, Asp86, and Asp287). We show that these aspartates act like signal sequence mutations for PhoA export: (i) Asp----Ala mutations increase the PhoA activity of fusions to P1, P2, and P5. (ii) The signal sequence mutation suppressor prlA402 increases the PhoA activity of these same fusions. We also show that the aspartates in TM1, TM3, and TM9 are critical for wild-type TetA function; they are conserved in related TetA proteins and Asp----Ala mutations reduce or eliminate tetracycline resistance. The properties of the anomalous TetA-PhoA fusions suggest that TetA sequences C-terminal to some cytoplasmic and periplasmic segments are required for the proper localization of those segments, i.e. long range interactions may be more important in determining the membrane topology of TetA than suggested in some general models.     

Role of outer membrane barrier in efflux-mediated tetracycline resistance of Escherichia coli.

Accumulation of tetracycline in Escherichia coli was studied to determine its permeation pathway and to provide a basis for understanding efflux-mediated resistance. Passage of tetracycline across the outer membrane appeared to occur preferentially via the porin OmpF, with tetracycline in its magnesium-bound form. Rapid efflux of magnesium-chelated tetracycline from the periplasm was observed. In E. coli cells that do not contain exogenous tetracycline resistance genes, the steady-state level of tetracycline accumulation was decreased when porins were absent or when the fraction of Mg(2+)-chelated tetracycline was small. This is best explained by assuming the presence of a low-level endogenous active efflux system that bypasses the outer membrane barrier. When influx of tetracycline is slowed, this efflux is able to reduce the accumulation of tetracycline in the cytoplasm. In contrast, we found no evidence of a special outer membrane bypass mechanism for high-level efflux via the Tet protein, which is an inner membrane efflux pump coded for by exogenous tetA genes. Fractionation and equilibrium density gradient centrifugation experiments showed that the Tet protein is not localized to regions of inner and outer membrane adhesion. Furthermore, a high concentration of tetracycline was found in the compartment that rapidly equilibrated with the medium, most probably the periplasm, of Tet-containing E. coli cells, and the level of tetracycline accumulation in Tet-containing cells was not diminished by the mutational loss of the OmpF porin. These results suggest that the Tet protein, in contrast to the endogenous efflux system(s), pumps magnesium-chelated tetracycline into the periplasm. A quantitative model of tetracycline fluxes in E. coli cells of various types is presented.     

Plasmid vectors based on Tn10 DNA: gene expression regulated by tetracycline

The regulatory region of the tetracycline resistance determinant from transposon Tn10 has been used to construct plasmid vectors for gene expression regulated by tetracycline. Plasmids pRS tetBam-8 and pRS tetBam-16 include the tet regulatory region, the segment coding for the first four amino acids of the tetracycline resistance protein (tetA protein), and a linker region with SalI, HpaII, and BamHI restriction sites for gene fusions. Plasmid pTB-1, a derivative of pRS tetBam-8 and of the beta-galactosidase gene-containing plasmid pMC1403, constitutively expresses a tetA fragment-beta-galactosidase fusion protein. If a multicopy runaway replication plasmid, pMOBglII-16 that includes a 2.7-kb BglII DNA fragment from Tnl10 that provides tetR protein is present along with pTB-1, the expression of beta-galactosidase is reduced eightfold. Tetracycline acts as an inducer of the system and restores the level of beta-galactosidase activity measured in transformants containing pTB-1 alone. Plasmid mutants unable to produce active tetR protein are ineffective in reducing expression. Escherichia coli carrying plasmids that express both tetA protein and tetR protein show an increase in the tetracycline resistance level after incubation with the drug. The observations are consistent with the previously proposed mechanism of regulation of tetracycline resistance in Tn10.     

Nucleotide sequence of the tetM tetracycline resistance determinant of the streptococcal conjugative shuttle transposon Tn1545.

The nucleotide sequence of the tetracycline resistance gene tetM encoded by streptococcal conjugative shuttle transposon Tn1545 has been determined. The resistance gene was identified as a coding sequence of 1917 base pairs corresponding to a protein with a Mr of 72,500 daltons. This value is in good agreement with that, 68,000 daltons, estimated by SDS-polyacrylamide gel electrophoresis of Escherichia coli minicell extracts. The tetM gene product does not exhibit any sequence homology with either the Gram-negative (tetA, tetB and tetC), or the Bacillus and Staphylococcus tetracycline resistance proteins. The average hydropathy value of the tetM gene product (-0.21) contrasts with those calculated for the other TET proteins which are markedly hydrophobic (0.76 to 0.93). Hybridization experiments performed with an intragenic tetM probe do not support the claim [Taylor, D. (1986), J. Bact. 165, 1037-1039)] that tetracycline resistance in Campylobacter is due to acquisition of tetM.     

Probing FhuA''-''PhoA fusion proteins for the study of FhuA export into the cell envelope of Escherichia coli K12

Summary The FhuA protein (formerly TonA) is located in the outer membrane of Escherichia coli K12. Fusions between fhuA and phoA genes were constructed. They determined proteins containing a truncated but still active alkaline phosphatase of constant size and a variable FhuA portion which ranged from 11%–90% of the mature FhuA protein. The fusion sites were nearly randomly distributed along the FhuA protein. The FhuA segments directed the secretion of the truncated alkaline phosphatase across the cytoplasmic membrane. The fusion proteins were proteolytically degraded up to the size of alkaline phosphatase and no longer reacted with anti-FhuA antibodies. The fusion proteins were more stable in lon and pep mutants lacking cytoplasmic protease and peptidases, respectively. The larger fusion proteins above a molecular weight of 64000 dalton were predominantly found in the outer membrane fraction. They were degraded by trypsin when cells were converted to spheroplasts so that trypsin gained access to the periplasm. In contrast, FhuA protein in the outer membrane was largely resistant to trypsin. It is concluded that the larger FhuA-PhoA fusion proteins were associated with, but not properly integrated into, the outer membrane.     

Membrane topology of penicillin-binding protein 3 of Escherichia coli

The beta-lactamase fusion vector, pJBS633, has been used to analyse the organization of penicillin-binding protein 3 (PBP3) in the cytoplasmic membrane of Escherichia coli. The fusion junctions in 84 in-frame fusions of the coding region of mature TEM beta-lactamase to random positions within the PBP3 gene were determined. Fusions of beta-lactamase to 61 different positions in PBP3 were obtained. Fusions to positions within the first 31 residues of PBP3 resulted in enzymatically active fusion proteins which could not protect single cells of E. coli from killing by ampicillin, indicating that the beta-lactamase moieties of these fusion proteins were not translocated to the periplasm. However, all fusions that contained greater than or equal to 36 residues of PBP3 provided single cells of E. coli with substantial levels of resistance to ampicillin, indicating that the beta-lactamase moieties of these fusion proteins were translocated to the periplasm. PBP3 therefore appeared to have a simple membrane topology with residues 36 to the carboxy-terminus exposed on the periplasmic side of the cytoplasmic membrane. This topology was confirmed by showing that PBP3 was protected from proteolytic digestion at the cytoplasmic side of the inner membrane but was completely digested by proteolytic attack from the periplasmic side. PBP3 was only inserted in the cytoplasmic membrane at its amino terminus since replacement of its putative lipoprotein signal peptide with a normal signal peptide resulted in a water-soluble, periplasmic form of the enzyme. The periplasmic form of PBP3 retained its penicillin-binding activity and appeared to be truly water-soluble since it fractionated, in the absence of detergents, with the expected molecular weight on Sephadex G-100 and was not retarded by hydrophobic interaction chromatography on Phenyl-Superose.     

The dynamics of assembly of a cytoplasmic membrane protein in Escherichia coli.

The topology of integral cytoplasmic membrane proteins can be analyzed using alkaline phosphatase fusions by determining which constructs have low and which have high specific activity. We show that in all cases the enzymatic activity is due to the fraction of the alkaline phosphatase moiety of the fusion protein localized to the periplasm. We present evidence that these fusions can also be used to analyze the process of assembly of cytoplasmic proteins into the membrane. The rate of acquisition of protease resistance of the alkaline phosphatase moiety of such hybrid proteins is compared for fusions to periplasmic and cytoplasmic domains. We show that this process, which is assumed to be representative of export of alkaline phosphatase, is significantly slower for fusions to cytoplasmic and certain periplasmic domains than for most periplasmic domains. These results are discussed in the context of the normal assembly of integral membrane proteins.