Correct insertion of a simple eukaryotic plasma-membrane protein into the cytoplasmic membrane of Escherichia coli

A genetic system for directly synthesizing eukaryotic membrane proteins in Escherichia coli and assessing their ability to insert into the bacterial cytoplasmic membrane is described. The components of this system are the direct expression vector, pYZ4, and the mature beta-lactamase (BlaM) cassette plasmid, pYZ5, that can be used to generate translational fusions of BlaM to any synthesized membrane protein. The beta-subunit of sheep-kidney Na,K-ATPase (beta NKA), a class-II plasma membrane protein, was synthesized in E. coli using pYZ4, and BlaM was fused to a normally extracellular portion of it. The fusion protein conferred ampicillin resistance on individual host cells, indicating that the BlaM portion had been translocated to the bacterial periplasm, and that, by inference, the eukaryotic plasma-membrane protein can insert into the bacterial cytoplasmic membrane. A series of 31 beta NKA::BlaM fusion proteins was isolated and characterised to map the topology of the eukaryotic plasma membrane protein with respect to the bacterial cytoplasmic membrane. This analysis revealed that the organisation of the beta NKA in the E. coli cytoplasmic membrane was indistinguishable from that in its native plasma membrane.     

Membrane insertion of the Escherichia coli MalF protein in cells with impaired secretion machinery

The MalF protein is an integral membrane protein of Escherichia coli containing eight membrane-spanning stretches and a large periplasmic domain of approximately 180 amino acids. We have asked whether this protein is dependent for its membrane insertion on the bacterial secretion machinery specified by the sec genes. Using azide to inhibit the SecA protein and sec mutants to reduce the functioning of the machinery, we have studied the membrane assembly of MalF and beta-galactosidase and alkaline phosphatase fusions to MalF. In no case did we see an effect of reducing sec gene function on the insertion of MalF or fusion proteins. Selection for mutants that would cause internalization of a MalF-beta-galactosidase hybrid protein yielded no mutations in sec genes. Our results suggest that MalF can assemble in the membrane independently of the bacterial secretion machinery.     

Genetic evidence for substrate and periplasmic-binding-protein recognition by the MalF and MalG proteins, cytoplasmic membrane components of the Escherichia coli maltose transport system

We isolated mutants of Escherichia coli in which the maltose-binding protein (MBP) is no longer required for growth on maltose as the sole source of carbon and energy. These mutants were selected as Mal+ revertants of a strain which carries a deletion of the MBP structural gene, malE. In one class of these mutants, maltose is transported into the cell independently of MBP by the remaining components of the maltose system. The mutations in these strains map in either malF or malG. These genes code for two of the cytoplasmic membrane components of the maltose transport system. In some of the mutants, MBP actually inhibits maltose transport. We demonstrate that these mutants still transport maltose actively and in a stereospecific manner. These results suggest that the malF and malG mutations result in exposure of a substrate recognition site that is usually available only to substrates bound to MBP.     

A novel DnaJ-like protein in Escherichia coli inserts into the cytoplasmic membrane with a Type III topology

We describe a novel Escherichia coli protein, DjlA, containing a highly conserved J-region motif, which is present in the DnaJ protein chaperone family and required for interaction with DnaK. Remarkably, DjlA is shown to be a membrane protein, localized to the inner membrane with the unusual Type III topology (N-out, C-in). Thus, DjlA appears to present an extremely short N-terminus to the periplasm and has a single transmembrane domain (TMD) and a large cytoplasmic domain containing the C-terminal J-region. Analysis of the TMD of DjIA and recently identified homologues in Coxiella burnetti and Haemophilus influenzae revealed a striking pattern of conserved glycines (or rarely alanine), with a four-residue spacing. This motif, predicted to form a spiral groove in the TMD, is more marked than a repeating glycine motif, implicated in the dimerization of TMDs of some eukaryotic proteins. This feature of DjlA could represent a promiscuous docking mechanism for interaction with a variety of membrane proteins. DjlA null mutants can be isolated but these appear rapidly to accumulate suppressors to correct envelope and growth defects. Moderate (10-fold) overproduction of DjlA suppresses a mutation in FtsZ but markedly perturbs cell division and cell-envelope growth in minimal medium. We propose that DjlA plays a role in the correct assembly, activity and/or maintenance of a number of membrane proteins, including two-component signal-transduction systems.     

Role for Escherichia coli YidD in membrane protein insertion

YidC has an essential but poorly defined function in membrane protein insertion and folding in bacteria. The yidC gene is located in a gene cluster that is highly conserved in Gram-negative bacteria, the gene order being rpmH, rnpA, yidD, yidC, and trmE. Here, we show that Escherichia coli yidD, which overlaps with rnpA and is only 2 bp upstream of yidC, is expressed and localizes to the inner membrane, probably through an amphipathic helix. Inactivation of yidD had no discernible effect on cell growth and viability. However, compared to control cells, ΔyidD cells were affected in the insertion and processing of three YidC-dependent inner membrane proteins. Furthermore, in vitro cross-linking showed that YidD is in proximity of a nascent inner membrane protein during its localization in the Sec-YidC translocon, suggesting that YidD might be involved in the insertion process.     

Pullulanase secretion in Escherichia coli K-12 requires a cytoplasmic protein and a putative polytopic cytoplasmic membrane protein

The previously uncharacterized third and fourth genes (pulE and pulF) of the pullulanase secretion gene operon of Klebsiella oxytoca strain UNF5023 are, respectively, predicted to encode a 55 kDa polypeptide with a putative nucleotide-binding site, and a highly hydrophobic 44 kDa polypeptide that probably spans the cytoplasmic membrane several times. Expression of pulE in minicells or under the control of a strong bacteriophage T7 promoter resulted in the production of a c. 58 kDa cytoplasmic protein. A representative PulE-beta-galactosidase hybrid protein created by Tnlac mutagenesis was also found mainly in the cytoplasm. These results are in line with the predicted absence from PulE of a region of sufficient hydrophobicity to function as a signal sequence. The PulF polypeptide could not be detected either in minicells or when the gene was transcribed from the T7 promoter, but the acquirement of three pulF-lacZ gene fusions that encoded hybrid proteins with relatively high levels of beta-galactosidase activity indicates that this gene can be transcribed and translated. Gene disruption experiments indicated that both pulE and pulF are required for pullulanase secretion in Escherichia coli K-12. Both proteins exhibit considerable homology throughout their entire lengths with other proteins involved in protein secretion, pilin assembly, conjugation and transformation competence in a variety of bacteria. In addition, PulE protein has consensus sequences found in a wide variety of nucleotide-binding proteins. This study completes the initial characterization of the pullulanase secretion gene operon, which comprises 13 genes that are all essential for the transport of pullulanase across the outer membrane.     

The FtsQ protein of Escherichia coli: membrane topology, abundance, and cell division phenotypes due to overproduction and insertion mutations.

The ftsQ gene is one of several genes thought to be specifically required for septum formation in Escherichia coli. Published work on the cell division behavior of ftsQ temperature-sensitive mutants suggested that the FtsQ product is required throughout the whole process of septum formation. Here we provide additional support for this hypothesis based on microscopic observations of the cell division defects resulting from insertional and temperature-sensitive mutations in the ftsQ gene, and constitutive overexpression of its gene product. On the basis of the published, predicted amino acid sequence of the FtsQ protein and our analysis of fusion proteins of the FtsQ protein to bacterial alkaline phosphatase, we conclude that FtsQ is a simple cytoplasmic membrane protein with a approximately 25-amino-acid cytoplasmic domain and a approximately 225-amino-acid periplasmic domain. We estimate that the FtsQ protein is present at about 22 copies per cell.     

Protease IV, a cytoplasmic membrane protein of Escherichia coli, has signal peptide peptidase activity

During export of the outer membrane lipoprotein across the cytoplasmic membrane, the signal peptide of the lipoprotein undergoes two successive proteolytic attacks, cleavage of the signal peptide by signal peptidase and digestion of the cleaved signal peptide by an enzyme called signal peptide peptidase(s) (Hussain, M., Ichihara, S., and Mizushima, S. (1982) J. Biol. Chem. 257, 5177-5182; Hussain, M., Ozawa, Y., Ichihara, S., and Mizushima, S. (1982) Eur. J. Biochem. 129, 233-239). Here we report that protease IV, a cytoplasmic membrane protease, exhibits the signal peptide peptidase activity. The signal peptide peptidase activity was cofractionated with protease IV throughout the entire process of purification of the latter enzyme. Only the signal peptide was digested by the peptidase among membrane proteins. Both the signal peptide peptidase activity and the protease IV activity were inhibited to similar degrees by antipain, leupeptin, chymostatin, and elastatinal that are known to inhibit the signal peptide peptidase activity in the cell envelope. From these results we conclude that protease IV is the signal peptide peptidase that is responsible for signal peptide digestion in the cytoplasmic membrane. The peptidase attacked the signal peptide only after its release from the precursor protein.     

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.     

EnvC, a new lipoprotein of the cytoplasmic membrane of Escherichia coli

Abstract A gene product with an apparent molecular mass of approximately 39000 Da can be identified in the cytoplasmic membrane of Escherichia coli upon expression of cloned envC . In this communication we report that the product was labelled with [³H]glycerol and [³H]palmitic acid, and a precursor molecule of increased molecular mass was accumulated when cells were treated with globomycin, a specific inhibitor for the prolipoprotein signal peptidase. The same precursor molecule was encoded by an envC mutant gene, in which the cysteine residue in a pentapeptide sequence, Leu-Ile-Ala-Gly-Cys²⁴ within the amino terminal region of EnvC, was replaced by tryptophane (Trp²⁴). This protein was not labelled with [³H]glycerol. The results demonstrate that the envC gene product represents a new lipoprotein of the cytoplasmic membrane of E. coli .     

A novel membrane protein involved in protein translocation across the cytoplasmic membrane of Escherichia coli.

A novel factor, which is a membrane component of the protein translocation machinery of Escherichia coli, was discovered. This factor was found in the trichloracetic acid-soluble fraction of solubilized cytoplasmic membrane. The factor was purified to homogeneity by ion exchange column chromatographies and found to be a hydrophobic protein with a molecular mass of approximately 12 kDa. The factor caused > 20-fold stimulation of the protein translocation when it was reconstituted into proteoliposomes together with SecE and SecY. SecE, SecY, SecA and ATP were essential for the factor-dependent stimulation of the activity. The factor stimulated the translocation of all three precursor proteins examined, including authentic proOmpA. Stimulation of the translocation of proOmpF-Lpp, a model presecretory protein, was especially remarkable, since no translocation was observed unless proteoliposomes were reconstituted with the factor. Partial amino acid sequence of the purified factor was determined. An antibody raised against a synthetic peptide of this sequence inhibited the protein translocation into everted membrane vesicles, indicating that the factor is playing an important role in protein translocation into membrane vesicles. The partial amino acid sequence was found to coincide with that deduced from the reported DNA sequence of the upstream region of the leuU gene. Cloning and sequencing of the upstream region revealed the presence of a new open reading frame, which encodes a hydrophobic protein of 11.4 kDa. We propose that the factor is a general component of the protein translocation machinery of E. coli.     

Heat shock induction by a misassembled cytoplasmic membrane protein complex in Escherichia coli

We analysed the effects of the overproduction of parts or all of a multisubunit ATP-binding cassette (ABC) transporter, the MalFGK2 complex, involved in the uptake of maltose and maltodextrins in Escherichia coli . We found that production of the MalF protein alone was inducing the phtrA promoter, which is under the control of a recently discovered sigma factor, σ²⁴, involved in the response to extracytoplasmic stresses. The production level, stability and localization of MalF were not altered when produced without its partners, suggesting that the protein was correctly inserted in the membrane. Our results indicate that a large periplasmic loop located between the third and fourth transmembrane segment of MalF, the L3 loop, is responsible for phtrA induction: (i) deleted MalF proteins with no L3 loop or with a L3 loop lacking 120 amino acids do not induce the phtrA promoter; (ii) the export to the periplasm of the L3 loop alone or fused to MalE induces the phtrA promoter. Moreover, the proteolytic sensitivity of MalF is different when it is produced alone and when MalF and MalG are produced together, suggesting a change in the conformation and/or accessibility of MalF. These results suggest that some inner membrane proteins can be sensed outside the cytoplasm by a quality control apparatus or by the export machinery. Moreover, the observation of the phtrA induction by MalF could be a useful new tool for studying the insertion and assembly of the MalFGK2 complex.     

Interactions and predicted host membrane topology of the enteropathogenic Escherichia coli translocator protein EspB

Type 3 secretion systems (T3SSs) are critical for the virulence of numerous deadly Gram-negative pathogens. T3SS translocator proteins are required for effector proteins to traverse the host cell membrane and perturb cell function. Translocator proteins include two hydrophobic proteins, represented in enteropathogenic Escherichia coli (EPEC) by EspB and EspD, which are thought to interact and form a pore in the host membrane. Here we adapted a sequence motif recognized by a host kinase to demonstrate that residues on the carboxyl-terminal side of the EspB transmembrane domain are localized to the host cell cytoplasm. Using functional internal polyhistidine tags, we confirm an interaction between EspD and EspB, and we demonstrate, for the first time, an interaction between EspD and the hydrophilic translocator protein EspA. Using a panel of espB insertion mutations, we describe two regions on either side of a putative transmembrane domain that are required for the binding of EspB to EspD. Finally, we demonstrate that EspB variants incapable of binding EspD fail to adopt the proper host cell membrane topology. These results provide new insights into interactions between translocator proteins critical for virulence.     

Genetic analysis of an essential cytoplasmic domain of Escherichia coli SecY based on resistance to Syd, a SecY-interacting protein

We previously described a dominant negative secY ^-d 1 allele in Escherichia coli, whose product interferes with protein export, presumably by sequestering SecE, the stabilizing partner of SecY. Syd is the product of a multicopy suppressor of the secY ^-d 1 phenotype, and its overproduction preferentially stabilizes the wild-type SecY protein. In contrast, overproduction of Syd is toxic to the secY24 mutant, which shows a partial defect in SecY-SecE interaction. We isolated Syd-resistant revertants from the secY24 mutant. Pseudo-reversions mapped to sites at or near the secY24 mutation site (Gly240→Asp). The secY249 mutation (Ala249→Val) intragenically suppressed Syd sensitivity, but not the temperature-sensitive Sec phenotype of the secY24 mutation. The SecY249 mutant protein shows a reduced capacity to be stabilized by Syd, suggesting that the mutation weakens the SecY-Syd interaction. The other two mutations changed residue 240 (the site of the secY24 alteration) to Asn (secY245) or Ala (secY241) and restored the ability of the cell to export protein. Although the secY245 mutant retained some sensitivity?to Syd overproduction, the secY241 mutant was completely Syd-resistant. Furthermore, the secY241 mutation seemed to represent a “hyper reversion” with respect to the SecY-SecE interaction. Protein export in this mutant was no longer sensitive to SecY^-d1. When the secY ^-d 1 mutation was combined intragenically with secY241, the resulting double mutant gene (secY ^-d 1–241) showed an increased ability to interfere with protein export. On the basis of our model for SecY^-d1, these results suggest that the secY241 alteration enhances SecY-SecE interaction. These results indicate that residue 240 of SecY is crucial for the interaction between the cytosolic domains of SecY and SecE required for the establishment of the translocase complex.     

SecA-dependence of the translocation of a large periplasmic loop in the Escherichia coli MalF inner membrane protein is a function of sequence context

We have analysed the translocation of a large periplasmic loop in the Escherichia coli MalF Inner membrane protein when placed in different sequence contexts and under conditions when the function of the SecA protein is Inhibited. The results show that the degree of SecA-dependence varies with sequence context: while translocation of the large loop In its normal context Is only minimally affected by SecA Inhibition, translocation is much more sensitive to SecA inhibition when the loop is placed in the context of other inner membrane proteins. Conversely, when the large MalF loop is replaced by segments from other proteins, translocation of those segments is again very sensitive to SecA inhibition. Thus, SecA-dependence is not an all-or-none phenomenon and Is not only a simple function of, e.g. the length of a translocated segment or the hydrophobicity of the flanking transmembrane segments.     

Dual topology of the Escherichia coli TatA protein

The Escherichia coli Tat system has unusual capacity of translocating folded proteins across the cytoplasmic membrane. The TatA protein is the most abundant known Tat component and consists of a transmembrane segment followed by an amphipathic helix and a hydrophilic C terminus. To study the operation mechanism of the Tat apparatus, we analyzed the topology of TatA. Intriguingly, alkaline phosphatase (PhoA)-positive fusions were obtained at positions Gly-38, Lys-40, Asp-51, and Thr-53, which are all located at the cytoplasmic C terminus of the TatA protein. Interestingly, replacing phoA with uidA at Thr-53 led to positive beta-glucuronidase fusion, implying cytoplasmic location of the TatA C terminus. To further determine cellular localization of the TatA C terminus, we deleted the phoA gene and left 46 exogenous residues, including the tobacco etch virus (Tev) protease cleavage site (Tcs) after Thr-53, yielding TatA(T53)::Tcs. Unlike the PhoA and UidA fusions, which abolished the TatA function, the TatA(T53)::Tcs construct was able to restore the growth of tatA mutants on the minimal trimethlyamine N-oxide media. In vitro and in vivo proteolysis assay showed that the Tcs site of TatA(T53)::Tcs was accessible from both the periplasm and cytoplasm, indicating a dual topology of the TatA C terminus. Importantly, growth conditions seemed to influence the protein level of TatA and the cytoplasmic accessibility of the Tcs site of TatA(T53)::Tcs. A function-linked change of the TatA topology is suggested, and its implication in protein transport is discussed.     

Integration of the thylakoid membrane protein cytochrome b6 in the cytoplasmic membrane of Escherichia coli

An overexpression system for spinach apocytochrome b(6) as a fusion protein to a maltose-binding protein in Escherichia coli was established using the expression vector pMalp2. The fusion of the cytochrome b(6) to the periplasmic maltose-binding protein directs the cytochrome on the Sec-dependent pathway. The cytochrome b(6) has a native structure in the bacterial cytoplasmic membrane with both NH(2) and COOH termini on the same, periplasmic side of the membrane but has the opposite orientation compared to that in thylakoid. Our data also show that in the E. coli cytoplasmic membrane, apocytochrome b(6) and exogenic hemes added into a culture media spontaneously form a complex with similar spectroscopic properties to native cytochrome b(6). Reconstituted membrane-bound cytochrome b(6) contain two b hemes (alpha band, 563 nm; average E(m,7) = -61 +/- 0.84 and -171 +/- 1.27 mV).     

Purification and characterization of a signal peptide, a product of protein secretion across the cytoplasmic membrane of Escherichia coli

A signal peptide, a processing product of the precursor of the lipoprotein in the cytoplasmic membrane of Escherichia coli, has been purified through extractions with butanol and ethyl ether and chromatographies with a Sephadex LH-60 column and Sep-pak C18. Analysis of the amino acid composition and sequencing of the N- and C-termini indicate that the signal peptide was intact, suggesting that the first step of the signal peptide catabolism in the cytoplasmic membrane is the cleavage of the intact signal peptide. During the purification, the signal peptide exhibited unique features, including strong interaction with phospholipids. The possible importance of such features in the process of protein translocation across membranes is discussed.     

Membrane topology and assembly of the outer membrane protein OmpA of Escherichia coli K12

The 325-residue outer membrane protein OmpA of Escherichia coli has been proposed to consist of a membrane-embedded moiety (residues 1 to about 170) and a C-terminal periplasmic region. The former is thought to comprise eight transmembrane segments in the form of antiparallel β-strands, forming an amphiphilic β connected by exposed turns. Several questions concerning this model were addressed. Thus no experimental evidence had been presented for the turns at the inner leaflet of the membrane and it was not known whether or not the periplasmic part of the polypeptide plays a role in the process of membrane incorporation. Oligonucleotides encoding trypsin cleavage sites were inserted at the predicted turn sites of the ompA gene and it was shown that the encoded proteins indeed become accessible to trypsin at the modified sites. Together with previous results, these data also show that the turns on both sides of the membrane do not possess specifically topogenic information. In two cases one of the two expected tryptic fragments was lost and could be detected at low concentration in only one case. Therefore, bilateral proteolytic digestion of outer membranes can cause loss of β-strands and does not necessarily produce a reliable picture of protein topology. When ompA genes were constructed coding for proteins ending at residue 228 or 274, the membrane assembly of these proteins was shown to be partially defective with about 20% of the proteins not being assembled. No such defect was observed when, following the introduction of a premature stop codon, a truncated protein was produced ending with residue 171. It is concluded that (1) the proposed β-barrel structure is essentially correct and (2) the periplasmic part of OmpA does not play an active role in, but can, when present in mutant form, interfere with membrane assembly.