Overproduction of NlpE, a new outer membrane lipoprotein, suppresses the toxicity of periplasmic LacZ by activation of the Cpx signal transduction pathway

The LamB-LacZ-PhoA tripartite fusion protein is secreted to the periplasm, where it exerts a toxicity of unknown origin during high-level synthesis in the presence of the inducer maltose, a phenotype referred to as maltose sensitivity. We selected multicopy suppressors of this toxicity that allow growth of the tripartite fusion strains in the presence of maltose. Mapping and subclone analysis of the suppressor locus identified a previously uncharacterized chromosomal region at 4.7 min that is responsible for suppression. DNA sequence analysis revealed a new gene with the potential to code for a protein of 236 amino acids with a predicted molecular mass of 25,829 Da. The gene product contains an amino-terminal signal sequence to direct the protein for secretion and a consensus lipoprotein modification sequence. As predicted from the sequence, the suppressor protein is labeled with [3H]palmitate and is localized to the outer membrane. Accordingly, the gene has been named nlpE (for new lipoprotein E). Increased expression of NlpE suppresses the maltose sensitivity of tripartite fusion strains and also the extracytoplasmic toxicities conferred by a mutant outer membrane protein, LamBA23D. Suppression occurs by activation of the Cpx two-component signal transduction pathway. This pathway controls the expression of the periplasmic protease DegP and other factors that can combat certain types of extracytoplasmic stress.

Suppression of signal sequence defects and azide resistance in Escherichia coli commonly result from the same mutations in secA

The SecA protein of Escherichia coli is required for protein translocation from the cytoplasm. The complexity of SecA function is reflected by missense mutations in the secA gene that confer several different phenotypes: (i) conditional-lethal alleles cause a generalized block in protein secretion, resulting in the cytoplasmic accumulation of the precursor forms of secreted proteins; (ii) azi alleles confer resistance to azide at concentrations up to 4 mM; and (iii) prlD alleles suppress a number of signal sequence mutations in several different genes. To gain further insights into the role of SecA in protein secretion, we have isolated and characterized a large number of prlD mutations, reasoning that these mutations alter a normal function of wild-type SecA. Our results reveal a striking coincidence of signal sequence suppression and azide resistance: the majority of prlD alleles also confer azide resistance, and all azi alleles tested are suppressors. We suggest that this correlation reflects the mechanism(s) of signal sequence suppression. There are two particularly interesting subclasses of prlD and azi alleles. First, four of the prlD and azi alleles exhibit special properties: (i) as suppressors they are potent enough to allow PrlD (SecA) inactivation by a toxic LacZ fusion protein marked with a signal sequence mutation (suppressor-directed inactivation), (ii) they confer azide resistance, and (iii) they cause modest defects in the secretion of wild-type proteins. Sequence analysis reveals that all four of these alleles alter Tyr-134 in SecA, changing it to Ser, Cys, or Asn. The second subclass consists of seven prlD alleles that confer azide supersensitivity, and sequence analysis reveals that six of these alleles are changes of Ala-507 to Val. Both of the affected amino acids are located within different putative ATP-binding regions of SecA and thus may affect ATPase activities of SecA. We suggest that the four azide-resistant mutations slow an ATPase activity of SecA, thus allowing successful translocation of increased amounts of mutant precursor proteins.

The allele-specific synthetic lethality of prlA-prlG double mutants predicts interactive domains of SecY and SecE

The secretion of proteins from the cytoplasm of Escherichia coli requires the interaction of two integral inner membrane components, SecY and SecE. We have devised a genetic approach to probe the molecular nature of the SecY-SecE interaction. Suppressor alleles of secY and secE, termed prlA and prlG, respectively, were analyzed in pair-wise combinations for synthetic phenotypes. From a total of 115 combinations, we found only seven pairs of alleles that exhibit a synthetic defect when present in combination with one another. The phenotypes observed are not the result of additive defects caused by the prl alleles, nor are they the consequence of multiple suppressors functioning within the same strain. In all cases, the synthetic defect is recessive to wild-type secY or secE provided in trans. The recessive nature argues for a defective interaction between the Prl suppressors. The extreme allele specificity and topological coincidence of the mutations represented by these seven pairs of alleles identify domains of interaction between SecY/PrlA and SecE/PrlG.

The Cpx two-component signal transduction pathway of Escherichia coli regulates transcription of the gene specifying the stress-inducible periplasmic protease, DegP

DegP is a heat-shock inducible periplasmic protease in Escherichia coli. Unlike the cytoplasmic heat shock proteins, DegP is not transcriptionally regulated by the classical heat shock regulon coordinated by sigma 32. Rather, the degP gene is transcriptionally regulated by an alternate heat shock sigma factor, sigma E. Previous studies have demonstrated a signal transduction pathway that monitors the amount of outer-membrane proteins in the bacterial envelope and modulates degP levels in response to this extracytoplasmic parameter. To analyze the transcriptional regulation of degP, we examined mutations that altered transcription of a degP-lacZ operon fusion. Gain-of-function mutations in cpxA, which specifies a two-component sensor protein, stimulate transcription from degP. Defined null mutations in cpxA or the gene encoding its cognate response regulator, cpxR, decrease transcription from degP. These null mutations also prevent transcriptional induction of degP in response to overexpression of a gene specifying an envelope lipoprotein. Cpx-mediated transcription of degP is partially dependent on the activity of E sigma E, suggesting that the Cpx pathway functions in concert with E sigma E and perhaps other RNA polymerases to drive transcription of degP.

Beta-galactosidase is inactivated by intermolecular disulfide bonds and is toxic when secreted to the periplasm of Escherichia coli

The wild-type LamB-LacZ hybrid protein inhibits the export machinery upon induction when assayed by biochemical and genetic techniques, a phenotype referred to as hybrid protein jamming. This hybrid protein also renders cells sensitive to growth in the presence of the inducer maltose, presumably because of the jamming. We constructed a new version of this fusion by adding alkaline phosphatase, encoded by phoA, to the C terminus of the LamB-LacZ hybrid protein. This tripartite protein, LamB-LacZ-PhoA, is as toxic to cells as the hybrid LamB-LacZ; however, it does not jam at temperatures greater than 33 degrees C. Extreme C-terminal sequences of LacZ function as a critical folding domain and are therefore responsible for stabilizing the LacZ structure. To determine if this region of LacZ is important for jamming, we recombined a late nonsense mutation (X90) onto the hybrid construct. We found the toxicity of this new hybrid, LamB-LacZX90, to be nearly identical to that of the full-length protein, but it also does not jam the secretion machinery. This suggests that jamming is caused by LacZ folding. We found no inhibition of secretion in the tripartite and X90 fusion strains at 37 degrees C, suggesting that the toxicity of the new fusions is novel. Under these conditions, the tripartite and X90 fusion proteins form disulfide-bonded aggregates with high molecular weights in the periplasm. Accordingly, we believe that LacZ disrupts some essential function(s) in the periplasm.

OmpR mutants specifically defective for transcriptional activation

In Escherichia coli, OmpR and EnvZ comprise a two component regulatory system that controls the relative expression of the outer membrane porin proteins, OmpF and OmpC. In this system, OmpR functions as a transcriptional regulator, serving as an activator of ompC, and as both an activator and a repressor of ompF. Previous evidence suggests that OmpR-mediated transcriptional activation involves direct interaction between OmpR and the C-terminal domain of the alpha subunit of RNA polymerase. However, it has remained unclear what region(s) of OmpR is directly involved in this proposed interaction. Moreover, little else is known about how OmpR activates transcription. To identify residues important for transcriptional activation, we screened for mutations in ompR that render the protein specifically defective in its ability to activate transcription. The isolated ompR alleles were characterized through haploid and diploid analyses at both the ompF and ompC promoters, and through an in vivo DNA binding assay. Through this approach, we have identified five amino acid residues in OmpR that are specifically required for transcriptional activation; R42, P179, E193, A196 and E198. We propose that these mutations define a region(s) in OmpR that may contact the C-terminal domain of alpha to mediate transcriptional activation.

PrlA and PrlG suppressors reduce the requirement for signal sequence recognition

Selection for suppressors of defects in the signal sequence of secretory proteins has led most commonly to identification of prlA alleles and less often to identification of prlG alleles. These genes, secY/prlA and secE/prlG, encode integral membrane components of the protein translocation system of Escherichia coli. We demonstrate that an outer membrane protein, LamB, that lacks a signal sequence can be exported with reasonable efficiency in both prlA and prlG suppressor strains. Although the signal sequence is not absolutely required for export of LamB, the level of export in the absence of prl suppressor alleles is exceedingly low. Such strains are phenotypically LamB-, and functional LamB can be detected only by using sensitive infectious-center assays. Suppression of the LamB signal sequence deletion is dependent on normal components of the export pathway, indicating that suppression is not occurring through a bypass mechanism. Our results indicate that the majority of the known prlA suppressors function by an identical mechanism and, further, that the prlG suppressors work in a similar fashion. We propose that both PrlA and PrlG suppressors lack a proofreading activity that normally rejects defective precursors from the export pathway.

The essential tension: opposed reactions in bacterial two-component regulatory systems

In many different bacteria several sensory-response functions are controlled by systems of similar design. Most consist of two proteins, one of which regulates the phosphorylation of the other in response to an environmental stimulus. Regulation is achieved by balancing opposed phosphorylation and dephosphorylation reactions against each other. Remarkably, such a system can generate a signal whose strength is independent of the concentration of either component.

PrlA suppressor mutations cluster in regions corresponding to three distinct topological domains

The SecY protein of Escherichia coli and its homologues in other organisms, are integral components of the cellular protein translocation machinery. Suppressor mutations that alter SecY (the prlA alleles) broaden the specificity of this machinery and allow secretion of precursor proteins with defective signal sequences. Twenty-five prlA alleles have been characterized. These suppressor mutations were found to cluster in regions corresponding to three distinct topological domains of SecY. Based on the nature and position of the prlA mutations, we propose that transmembrane domain 7 of SecY functions in signal sequence recognition. Results suggest that this interaction may involve a right-handed supercoil of alpha-helices. Suppressor mutations that alter this domain appear to prevent signal sequence recognition, and this novel mechanism of suppression suggests a proofreading function for SecY. We propose that suppressor mutations that alter a second domain of SecY, transmembrane helix 10, also affect this proof-reading function, but indirectly. Based on the synthetic phenotypes exhibited by double mutants, we propose that these mutations strengthen the interaction with another component of the translocation machinery, SecE. Suppressor mutations were also found to cluster in a region corresponding to an amino-terminal periplasmic domain. Possible explanations for this unexpected finding are discussed.

Signal sequence processing is required for the assembly of LamB trimers in the outer membrane of Escherichia coli

Proteins destined for either the periplasm or the outer membrane of Escherichia coli are translocated from the cytoplasm by a common mechanism. It is generally assumed that outer membrane proteins, such as LamB (maltoporin or lambda receptor), which are rich in beta-structure, contain additional targeting information that directs proper membrane insertion. During transit to the outer membrane, these proteins may pass, in soluble form, through the periplasm or remain membrane associated and reach their final destination via sites of inner membrane-outer membrane contact (zones of adhesion). We report lamB mutations that slow signal sequence cleavage, delay release of the protein from the inner membrane, and interfere with maltoporin biogenesis. This result is most easily explained by proposing a soluble, periplasmic LamB assembly intermediate. Additionally, we found that such lamB mutations confer several novel phenotypes consistent with an abortive attempt by the cell to target these tethered LamB molecules. These phenotypes may allow isolation of mutants in which the process of outer membrane protein targeting is altered.

Mutations that affect separate functions of OmpR the phosphorylated regulator of porin transcription in Escherichia coli

OmpR is a member of a family of bacterial transcriptional regulators whose activity is controlled by phosphorylation. It regulates the transcription of two genes, serving as an activator of ompC, and as both an activator and a repressor of ompF. A previously isolated collection of ompR mutations was analyzed for the effect of each on the expression of both genes simultaneously. The results of this analysis indicate that the activation, repression, and DNA binding functions of OmpR can be disrupted independently, and that mutations interfering with each of these functions cluster within the sequence of the OmpR protein. The nature of these mutations is discussed in terms of the mechanisms by which OmpR regulates transcription, and potentially similar mechanisms operating within closely related response regulators.

The E. coli ffh gene is necessary for viability and efficient protein export

Homologues of the gene encoding the 54K (M(r) 54,000) subunit of the mammalian signal recognition particle have been identified in different organisms. The Escherichia coli homologue, termed ffh (for fifty-four homologue), specifies a protein (Ffh) that shares many properties with its eukaryotic counterpart, including association with mammalian 7S RNA and the ability to bind signal sequences specifically. Ffh also associates with E. coli 4.5S RNA, showing that it can form a ribonucleoprotein complex in prokaryotes. These results are intriguing because extensive genetic and biochemical characterization of E. coli failed to identify a signal recognition particle-like mechanism for protein export. Here we address this issue directly by construction of a strain in which ffh expression is arabinose-dependent. Results of depletion experiments indicate that Ffh is important in protein translocation.

Escherichia coli prlC encodes an endopeptidase and is homologous to the Salmonella typhimurium opdA gene

Mutations at the Escherichia coli prlC locus suppress the export defect of certain lamB signal sequence mutations. The Salmonella typhimurium opdA gene encodes an endoprotease that can participate in the catabolism of certain peptides and is required for normal development of phage P22. Plasmids carrying either the wild-type (pTC100 prlC+) or suppressor alleles of prlC complemented all phenotypes associated with an S. typhimurium opdA mutation. A plasmid carrying an amber mutation in prlC [prlC31(AM)] was unable to complement except in an amber suppressor background. Tn1000 insertions which eliminated the ability of pTC100 (prlC+) to complement opdA mapped to the region of the plasmid shown by deletion analysis and subcloning to contain prlC. The nucleotide sequence of a 2.7-kb fragment including this region was determined, revealing an open reading frame encoding a 77-kDa protein. The sequences of this open reading frame and its putative promoter region were very similar (84% nucleotide sequence identity and 95% amino acid identity) to those of S. typhimurium opdA, showing that these genes are homologs. The nucleotide sequence of the prlC1 suppressor allele was determined and predicts an in-frame duplication of seven amino acids, providing further confirmation that the prlC suppressor phenotype results from changes in the endopeptidase OpdA.

Suppressor analysis suggests a multistep, cyclic mechanism for protein secretion in Escherichia coli

The sec/prl gene products catalyze the translocation of precursor proteins from the cytoplasm of Escherichia coli. Recessive, conditionally lethal mutant alleles of these genes (sec mutations) cause a generalized defect in protein secretion; dominant suppressor mutant alleles (prl mutations) restore export of precursor proteins with altered signal sequences. In prl strains, a precursor protein with a defective signal sequence can be selectively targeted to the suppressor gene product. When a precursor LacZ hybrid protein is used, the targeted prl protein is inactivated by the large, toxic hybrid molecule, a result termed suppressor-directed inactivation (SDI). Using SDI, two different secretion-related complexes can be generated: a pretranslocation complex that contains a hybrid protein with an unprocessed signal sequence, and a translocation complex in which the hybrid protein is jammed in transmembrane orientation with the signal sequence cleaved. Additional Sec proteins that are contained within, and thus sequestered by, each of these complexes can be identified when their functional levels are lowered using the conditional lethal sec mutations. Results of this genetic analysis suggest a multistep pathway for protein secretion in which the translocation machinery assembles on demand.

Enhanced export of beta-galactosidase fusion proteins in prlF mutants is Lon dependent

We have used fusions of the outer membrane protein LamB to beta-galactosidase (encoded by lacZ) to study the protein export process. This LamB-LacZ hybrid protein blocks export when synthesized at high levels, as evidenced by inducer (maltose) sensitivity, a phenomenon termed LacZ hybrid jamming. The prlF1 mutation relieves LacZ hybrid jamming and allows localization of the fusion protein to a noncytoplasmic compartment. prlF1 and similar alleles are gain-of-function mutations. Null mutations in this gene confer no obvious phenotypes. Extragenic suppressors of a gain-of-function prlF allele have been isolated in order to understand how this gene product affects the export process. The suppressors are all lon null mutations, and they are epistatic to all prlF phenotypes tested. Lon protease activity has been measured in prlF1 cells and shown to be increased. However, the synthesis of Lon is not increased in a prlF1 background, suggesting a previously unidentified mechanism of Lon activation. Further analysis reveals that prlF1 activates degradation of cytoplasmically localized precursors in a Lon protease-dependent manner. It is proposed that accumulation of precursors during conditions of hybrid protein jamming titrates an essential export component(s), possibly a chaperone. Increased Lon-dependent precursor degradation would free this component, thus allowing increased protein export under jamming conditions.

Membrane-derived oligosaccharides affect porin osmoregulation only in media of low ionic strength

Gram-negative bacteria grown under conditions of low osmolarity accumulate significant amounts of periplasmic glucans, membrane-derived oligosaccharides (MDO) in Escherichia coli and cyclic glucans in members of the family Rhizobiaceae. It was reported previously (W. Fiedlder and H. Rotering, J. Biol. Chem. 263:14684-14689, 1988) that mdoA mutants unable to synthesize MDO show a number of altered phenotypes, among them a decreased expression of OmpF and an increased expression of OmpC, when grown in a Bacto Peptone medium of low osmolarity and low ionic strength. Although we confirm the findings of Fiedler and Rotering, we find that the regulation of OmpF and OmpC expression in mdoA mutants is normal in cells grown on other low-osmolarity media, eliminating the possibility that MDO itself might control porin expression. Our data suggest that a certain minimal ionic strength in the periplasm is needed for normal porin regulation. In media containing very low levels of salt, this may be contributed by anionic MDO.

EnvZ controls the concentration of phosphorylated OmpR to mediate osmoregulation of the porin genes

Osmoregulation of the bacterial porin genes ompF and ompC is controlled by a two-component regulatory system. EnvZ, the sensor component of this system, is capable both of phosphorylating and dephosphorylating OmpR, the effector component. Mutations were isolated in envZ that abolish the expression of both porin genes. These mutants appear to have lost the kinase activity of EnvZ while retaining their phosphatase activity, so that in their presence OmpR is completely unphosphorylated. The behavior of these mutants in haploid, and in diploid with other envZ alleles, is consistent with a model in which EnvZ mediates osmoregulation by controlling the concentration of a single species. OmpR-P.

Suppressor mutations in rpoA suggest that OmpR controls transcription by direct interaction with the alpha subunit of RNA polymerase

We have isolated mutations in rpoA, the gene encoding the alpha subunit of RNA polymerase, that specifically affect transcriptional control by OmpR and EnvZ, the two-component regulatory system that controls porin gene expression in Escherichia coli. Characterization of these mutations and a previously isolated rpoA allele suggests that both positive and negative regulation of porin gene transcription involves a direct interaction between OmpR and RNA polymerase through the alpha subunit. Several of the rpoA mutations cluster in the carboxy-terminal portion of the alpha protein, further suggesting that it is this domain of alpha that is involved in interaction with OmpR and perhaps other transcriptional regulators as well.

A genetic approach for analyzing the pathway of LamB assembly into the outer membrane of Escherichia coli

Results presented in this study demonstrate that a mutation which inserts an additional tyrosine between the 2 tyrosines at residues 118 and 119 of mature LamB protein results in a temperature-dependent assembly defect. This defect leads to the accumulation of an intermediate at the restrictive temperature that is most likely an assembly-defective monomer. These monomers are rapidly degraded in the wild type (htrA+) strain, and the biphasic kinetics of this degradation indicate that the mutation affects the assembly process and not the final product, i.e. stable trimers. In addition, our data show that the temperature-dependent assembly defect in the mutant strain is reversible, and therefore the accumulated monomers represent a true assembly intermediate. Fractionation studies show that the monomers, which can be accumulated in htrA (degP) mutants at the restrictive temperature, are associated with the outer membrane, indicating that trimerization of LamB is not a prerequisite for localization.

One of three transmembrane stretches is sufficient for the functioning of the SecE protein, a membrane component of the E. coli secretion machinery

The E. coli secE (prlG) gene codes for an integral cytoplasmic membrane protein which is part of the cell's secretory machinery. A deletion of nearly the entire gene renders the cell dependent on the presence of a complementing secE+ plasmid, indicating that the SecE protein is essential for growth. Deletions which remove carboxy-terminal sequences or substantial amounts near the amino-terminus of SecE can still complement the lethal deletion. This deletion analysis suggests that the essential domain of the SecE protein includes only a single one of its three hydrophobic membrane-spanning segments. Two of three dominant prlG signal sequence suppressors map to this segment. Consistent with the insensitivity of SecE to major structural changes, several cold-sensitive mutations cause lethality not because of any change in the protein, but because of a reduction in its level of expression. Our results suggest that higher levels of the protein are needed at the lower temperature. These findings are discussed in terms of the interactions between various components of the secretory machinery.

cis-acting ompF mutations that result in OmpR-dependent constitutive expression

OmpR and EnvZ differentially control the transcription of the major outer membrane porin genes, ompF and ompC, in Escherichia coli in response to the osmolarity of the medium. We have previously provided evidence that OmpR works both positively and negatively at the ompF promoter to give the characteristic switch from OmpF to OmpC production with increasing osmolarity. Here, we describe the isolation of cis-acting ompF mutations that affect negative regulation by OmpR by affecting the three-dimensional structure of the promoter region as measured by agarose gel mobility. These results further clarify the mechanism by which OmpR negatively regulates ompF expression, suggesting a model in which OmpR forms a repressive loop in the ompF promoter region.

Escherichia coli xonA (sbcB) mutants enhance illegitimate recombination

Mutations of Escherichia coli K-12 were isolated that increase the frequency of deletion formation. Three of these mutations map to the gene sbcB at 43.5 min on the E. coli chromosome. Two types of mutations at sbcB have been previously defined: sbcB-type that suppress both the UV sensitivity and recombination deficiency of recBC mutants, and xonA-type that suppress only the UV sensitivity. Both types are defective for production of exonuclease I activity. The mutations isolated here were similar to xonA alleles of sbcB because they suppressed the UV sensitivity of recBC mutants but did not restore recombination proficiency. Indeed, two previously characterized xonA alleles were shown to increase the frequency of deletion formation, although an sbcB allele did not. This result demonstrates that loss of exonuclease I activity is not sufficient to confer a high deletion phenotype, rather, the product of the sbcB gene possesses some other function that is important for deletion formation. Because deletion formation in this system is recA independent and does not require extensive DNA homology, these mutations affect a pathway of illegitimate recombination.

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.

The sec and prl genes of Escherichia coli

Two general approaches have been used to define genetically the genes that encode components of the cellular protein export machinery. One of these strategies identifies mutations that confer a conditional-lethal, pleiotropic export defect (sec, secretion). The other identifies dominant suppressors of signal sequence mutations (prl, protein localization). Subsequent characterization reveals that in at least three cases, prlA/secY, prlD/secA, and prlG/secE, both types of mutations are found within the same structural gene. This convergence is satisfying and provides compelling evidence for direct involvement of these gene products in the export process.

PrlA (SecY) and PrlG (SecE) interact directly and function sequentially during protein translocation in E. coli

Three strategies for genetic analysis show that two inner membrane components of the export machinery, PrlA (SecY) and PrlG (SecE), interact directly while catalyzing the translocation of secreted proteins across the cytoplasmic membrane of E. coli. The first, suppressor-directed inactivation (SDI), exploits the specific interaction between dominant prl suppressors of signal sequence mutations and mutant LacZ hybrid proteins. The second, Sec titration, extends SDI to allow the identification of various Sec proteins that are present in the translocation complex. The third uses the synthetic lethality of certain double-mutant strains to infer physical interactions between gene products. Biochemical data obtained with SDI strains allow the identification of two different secretory intermediates and indicate that PrlG functions before PrlA in the secretion pathway.

Heat-shock proteins DnaK and GroEL facilitate export of LacZ hybrid proteins in E. coli

The use of lacZ gene fusions, producing a hybrid protein containing an amino terminus specified by a target gene fused to the functional carboxy terminus of beta-galactosidase, has facilitated the study of protein targeting in various organisms. One of the best characterized fusions in Escherichia coli is phi(lamB-lacZ)42-1(Hyb), which produces a hybrid protein with the signal sequence and 181 N-terminal amino acids of the exported protein LamB, attached to LacZ. In common with other LacZ hybrids, the LamB-LacZ(42-1) protein is poorly exported from E. coli, conferring a Lac+ phenotype. beta-Galactosidase activity decreases markedly when cells producing the LamB-LacZ protein are grown at 42 degrees C or when a heat-shock response is induced at lower temperatures by overproducing heat-shock factor RpoH3, indicating the LacZ hybrids are being efficiently targeted to the cell envelope. We now report that the heat-shock proteins DnaK and GroEL can, in sufficient amounts, decrease beta-galactosidase activity and facilitate the export of lacZ-hybrid proteins.

Signal transduction in bacteria: kinases that control gene expression

A new paradigm, termed two-component regulatory systems, is emerging from the study of signal transduction in bacteria. A simple example of such a system is provided by the Omp regulon of Escherichia coli. This regulon, which controls the expression of the major outer membrane porin proteins OmpF and OmpC in response to changes in osmolarity, includes the inner membrane protein EnvZ (a receptor kinase) and the DNA-binding protein OmpR (a transcriptional activator). Although we do not know what "ligand" is sensed in the Omp system, we can trace the signal transduction pathway from the receptor at the cell surface directly to regulatory sequences within the DNA. Perhaps signal transduction in bacteria can serve as a simple archetype for understanding certain functions performed by receptor kinases and phosphorylated DNA-binding proteins in higher organisms.

Increased expression of the bifunctional protein PrlF suppresses overproduction lethality associated with exported beta-galactosidase hybrid proteins in Escherichia coli

We have cloned and determined the nucleotide sequence of the prlF gene. An open reading frame predicting a 111-amino-acid protein (Mr 12,351) with an acidic carboxy terminus was identified. The DNA sequence preceding this open reading frame revealed a putative promoter and a ribosome-binding site. The nucleotide sequence of the prlF1 mutation revealed a 7-base-pair duplication resulting in a slightly smaller predicted gene product of Mr 12,009 that lacked the acidic carboxy terminus. Maxicell analysis of prlF and prlF1 subclones identified peptides of sizes similar to those predicted by the nucleotide sequences. The prlF sequence was shown to be expressed in vivo by both maxicell analysis and construction of a prlF-lacZ fusion. Two kanamycin resistance insertions within the prlF open reading frame were introduced into the chromosome, replacing the wild-type gene. In contrast to the prlF1 mutation, these insertions had no detectable effect on cell growth or on the beta-galactosidase activity or maltose sensitivity (two sensitive indicators of hybrid protein export) conferred by the lamB-lacZ42-1 gene fusion. Overproduction of the wild-type prlF gene product from a plasmid carrying an active hybrid promoter, however, conferred a prlF1 phenotype. In addition, both the prlF1 mutation and both kanamycin resistance insertions increased the beta-galactosidase activity of a prlF-lacZ fusion. These results suggest that prlF is autoregulated and that overproduction of the prlF gene product increases the export efficiency of beta-galactosidase hybrid proteins from the cytoplasm.

Genetic analysis of the switch that controls porin gene expression in Escherichia coli K-12

The two-component regulatory system, OmpR and EnvZ, in Escherichia coli controls the differential expression of ompF and ompC in response to medium osmolarity. Previous studies suggest that EnvZ functions as a membrane sensor relaying information to the DNA-binding protein, OmpR, which in turn activates expression of the appropriate promoter. A strategy has been devised to isolate and characterize a collection of missense mutations in ompR that alter, but do not abolish protein function. Mutants were isolated using strains that contain the ompR and envZ genes in separate chromosomal locations yet maintain the production of both regulatory proteins at physiological levels. Such an arrangement facilitates ompR diploid analysis and tests of epistasis with known envZ mutations. The data obtained indicate that OmpR works in both a positive and negative fashion to control the transcription of ompF and this result forms the basis of a model for porin regulation that explains the switch from OmpF to OmpC production in response to increasing medium osmolarity.

Phosphorylation and dephosphorylation of a bacterial transcriptional activator by a transmembrane receptor

Signal transduction in the bacterial Omp, Che, and Ntr systems involves the phosphorylation and dephosphorylation of response regulators (OmpR, CheY and CheB, NRI) that share a homologous domain. We show that in the Omp system, the transmembrane sensor EnvZ, catalyzes both the phosphorylation of OmpR and the dephosphorylation of OmpR-P. The phosphorylation reaction proceeds by a mechanism shared with the Ntr and Che kinases, NRII, and CheA. EnvZ can phosphorylate NRI and can stimulate transcription from the glnAp2 promoter, and similarly, CheA can phosphorylate OmpR and can stimulate transcription from the ompF promoter. OmpR-P formed by either CheA or EnvZ is much more stable than CheY-P and NRI-P, but is rapidly hydrolyzed to OmpR and Pi by EnvZ in the presence of ATP, ADP, or nonhydrolyzable analogs of ATP. Because EnvZ is normally a transmembrane receptor with a periplasmic sensory domain, our results suggest that the role of EnvZ may be to control the intracellular concentration of OmpR-P in response to environmental signals.

New suppressors of signal-sequence mutations, prlG, are linked tightly to the secE gene of Escherichia coli

Analysis of more than 100 extragenic suppressors of the lamB14D signal-sequence mutation (changes Val in the hydrophobic core region at position 14 to Asp) has revealed alterations that appear to lie at prlA (secY) and secA (prlD), two loci known to be mutable to suppressor alleles, and a new suppressor termed prlG. One allele of the new suppressor class, prlG1, has been characterized in some detail. This suppressor counteracts, to some degree, the export defect conferred by a variety of signal-sequence mutations in two different genes, lamB and malE. Genetic analysis shows that the dominant suppressor mutations are linked tightly to, and probably allelic with, the gene secE. This result, coupled with data obtained with conditional-lethal alleles of secE, argues strongly that SecE is an important component of the cellular protein export machinery in Escherichia coli.

A bacterial environmental sensor that functions as a protein kinase and stimulates transcriptional activation

Transcription of the genes that encode the major outer membrane porin proteins OmpF and OmpC of Escherichia coli is regulated in response to changes in medium osmolarity by EnvZ and OmpR. EnvZ functions to sense environmental conditions and to relay this information to the DNA-binding protein OmpR. We have used a truncated EnvZ protein (EnvZ115), which is defective in sensory function but able to communicate with OmpR, to study the biochemical interactions between these two proteins and their effects on transcription from the ompF promoter. We show that purified EnvZ115 can phosphorylate OmpR in the presence of ATP. In addition, EnvZ115 stimulates the ability of OmpR to activate ompF transcription in vitro. Using antibodies specific for EnvZ, we have purified the wild-type protein and have shown that it is also an OmpR kinase. These results provide a prokaryotic example of a transmembrane sensory protein that functions as a protein kinase and suggest a mechanism by which EnvZ communicates with OmpR in signal transduction.

PrlC, a suppressor of signal sequence mutations in Escherichia coli, can direct the insertion of the signal sequence into the membrane

The prlC gene product of Escherichia coli can be altered by mutation so that it restores export of proteins with defective signal sequences. The strongest suppressor, prlC8, restores processing of a mutant signal sequence to a rate indistinguishable from the wild-type. Data obtained by changing gene dosage of the dominant suppressor and its specificity for different signal sequence mutations suggest that PrlC8 interacts directly with the hydrophobic core of the signal sequence. Despite the fact that signal sequence processing appears to be mediated by leader peptidase, the processed mature protein is not translocated efficiently from the cytoplasm. Results obtained with various double mutants indicate that PrlC8-mediated processing of mutant signal sequences does not require components of the cellular export machinery such as SecA, SecB or PrlA (SecY) and that the block in translocation from the cytoplasm occurs because PrlA (SecY) fails to recognize the defective signal sequence. We suggest that PrlC8 directs insertion of the mutant signal sequence into the membrane bilayer to an extent that processing by leader peptidase can occur. This reaction is novel in that it has not been observed previously in vivo.

PrlA is important for the translocation of exported proteins across the cytoplasmic membrane of Escherichia coli

Strains of Escherichia coli in which lacZ (specifies beta-galactosidase) is fused to genes that specify exported proteins such as LamB (lambda receptor) exhibit unusual phenotypes. In particular, such strains are killed by high-level expression of the LacZ hybrid protein. Previous results suggest that this overproduction phenotype is the consequence of a lethal jamming of the cellular protein export machinery and this hypothesis is supported by the observed accumulation of the precursor forms of many noncytoplasmic proteins within the moribund cell. Under conditions in which protein export is compromised, biochemical and immunocytochemical analyses indicate that these hybrid proteins can be found in transmembrane orientation. To identify the cellular component rendered rate-limiting by the LacZ hybrid protein under jamming conditions we have utilized signal sequence mutations, which block entry of the hybrid protein into the export pathway, and a dominant suppressor of these lesions, prlA4. Data obtained with a series of merodiploids heterozygous and homozygous for prlA+ and prlA4 show that PrlA is the component sequestered by hybrid jamming. Taken together, these results suggest that PrlA is a component of the export machinery that functions in the translocation of proteins across the cytoplasmic membrane.

The genetics of protein targeting in Escherichia coli K12

Genetic analysis of protein targeting in Escherichia coli has been facilitated by the use of lacZ gene fusions. Strains which contain a fusion between a gene specifying a noncytoplasmic protein and lacZ exhibit novel phenotypes that can be exploited to obtain export-defective mutations. Analysis of these mutations has demonstrated the importance of the signal sequence and provided some insight into the functions performed by this complex intragenic export signal. In addition, genes that specify components of the cellular protein export machinery have been identified. Three of these genes, secA, secB, and prlA/secY have been studied in some detail and results indicate that the protein products function in the translocation of exported proteins across the cytoplasmic membrane.

Two cellular components, PrlA and SecB, that recognize different sequence determinants are required for efficient protein export

We exploited the conditional-lethal phenotype of secB null mutations to demonstrate that SecB function was required for PrlA-mediated suppression of signal sequence mutations. The results of these experiments provide information about the functions performed and the sequence determinants recognized by each of these components of the protein export machinery of Escherichia coli.

EnvZ, a transmembrane environmental sensor of Escherichia coli K-12, is phosphorylated in vitro

By fusing the transcriptional and translational start signals of lacZ to envZ, we have obtained high-level synthesis of a truncated EnvZ protein (EnvZ115) in which the first 38 amino acids of EnvZ are replaced with the first 8 amino acids of LacZ. Using this construct, we have partially purified the EnvZ115 protein and demonstrated that this protein can be phosphorylated in vitro. We suggest that phosphorylation may be an important feature of EnvZ function.

Transposition of lambda placMu is mediated by the A protein altered at its carboxy-terminal end

Lambda placMu phages are derivatives of bacteriophage lambda that use the transposition machinery of phage Mu to insert into chromosomal and cloned genes. When inserted in the proper fashion, these phages yield stable fusions to the Escherichia coli lac operon in a single step. We have determined the amount of DNA from the c end of phage Mu present in one of these phages, lambda placMu3, and have shown that this phage carries a 3137-bp fragment of Mu DNA. This DNA segment carries the Mu c-end attachment site and encodes the Mu genes cts62, ner+, and gene A lacking 179 bp at its 3' end (A'). The product of this truncated gene A' retains transposase activity and is sufficient for the transposition of lambda placMu. This was demonstrated by showing that lambda placMu derivatives carrying the A am1093 mutation in the A' gene are unable to transpose by themselves in a Su- strain, but their transposition can be triggered by coinfection with lambda pMu507(A+ B+). We have constructed several new lambda placMu phages that carry the A' am1093 gene and the kan gene, which confers resistance to kanamycin. Chromosomal insertions of these new phages are even more stable than those of the previously reported lambda placMu phages, which makes them useful tools for genetic analysis.

A progenitor of the outer membrane LamB trimer

During its localization to the outer membrane, LamB possesses distinctive biochemical properties as it passes through the cytoplasmic membrane. Because LamB entered this dynamic state with an attached signal sequence and leaves after cleavage, we call this export-related form of LamB the early-translocation form (et-LamB).

EnvZ functions through OmpR to control porin gene expression in Escherichia coli K-12

The regulatory proteins OmpR and EnvZ are both required to activate expression of the genes for the major outer membrane porin proteins, OmpF and OmpC, of Escherichia coli K-12. Here we show that OmpR, under certain conditions, could activate porin expression in the complete absence of EnvZ. In addition, the pleiotropic phenotypes conferred by a particular envZ mutation (envZ473) required the presence of functional OmpR protein. These results lead us to conclude that EnvZ and OmpR act in sequential fashion to activate porin gene expression; i.e., EnvZ modifies or in some way directs OmpR, which in turn acts at the appropriate porin gene promoter.

Characterization and in vivo cloning of prlC, a suppressor of signal sequence mutations in Escherichia coli K12

The prlC gene of E. coli was originally identified as an allele, prlC1, which suppresses certain signal sequence mutations in the genes for several exported proteins. We have isolated six new alleles of prlC that also confer this phenotype. These mutations can be placed into three classes based on the degree to which they suppress the lamB signal sequence deletion, lamBs78. Genetic mapping reveals that the physical location of the mutations in prlC correlates with the strength of the suppression, suggesting that different regions of the gene can be altered to yield a suppressor phenotype. We also describe an in vivo cloning procedure using lambda placMu9H. The procedure relies on transposition and illegitimate recombination to generate a specialized transducing phage that carries prlC1. This method should be applicable to any gene for which there is a mutant phenotype.

The first 28 amino acids of mature LamB are required for rapid and efficient export from the cytoplasm

Our laboratory has been utilizing the Escherichia coli outer membrane protein LamB to study the mechanism of protein localization. Various lines of evidence suggest that, in addition to a signal sequence, regions within the mature protein are required for efficient localization. In particular, studies using LamB-LacZ hybrid proteins have identified regions between amino acids 27 and 49 of mature LamB, which may play an important role in localization. To elucidate further the function of these regions, a series of in-frame deletions that remove varying lengths of early lamB sequences was constructed. The effects of these deletions on export of a large LamB-LacZ hybrid protein, 42-1, and on export of an otherwise wild-type LamB protein were determined. We find a strong correlation between the sequences deleted and the export phenotypes these deletions impart to both LamB and the LamB-LacZ42-1 hybrid protein. On the basis of these findings, the deletions can be divided into several distinct classes that define a region within mature LamB that participates in localization. This region extends amino terminally from amino acid 28 of the mature protein and functions in the rapid and efficient localization of LamB from the cytoplasm.

Isolation of mutations in the alpha operon of Escherichia coli that suppress the transcriptional defect conferred by a mutation in the porin regulatory gene envZ

One class of mutations in the envZ gene of Escherichia coli K-12 confers a pleiotropic defect on the expression of several genes, including ompF, lamB, and phoA, that are otherwise not commonly regulated. Four second-site mutations that suppress this transcriptional defect have been isolated by using a procedure that circumvented the problem of intragenic suppressors, including true revertants. All four mutations have been mapped to the genes of the alpha operon and have been assigned tentatively to the gene rpoA, which specifies the alpha subunit of RNA polymerase. The mutations, referred to as sez (for suppressor of envZ), did not appear to confer a phenotype on an otherwise wild-type strain and did not suppress the transcriptional defects conferred by several other phenotypic classes of envZ mutations, including amber mutations. Our results led us to postulate that the alpha subunit or some other component of the alpha operon plays a role in determining the specificity of gene expression.

cis-acting sites required for osmoregulation of ompF expression in Escherichia coli K-12

OmpF and OmpC are major outer membrane proteins which form passive diffusion pores in Escherichia coli K-12. The expression of the structural genes for these proteins, ompF and ompC, is influenced by medium osmotic strength and requires the products of two regulatory genes, ompR and envZ. We have constructed a series of ompF-lacZ fusions containing different regions of ompF to determine sites involved with osmoregulation. These fusions were crossed onto a specialized transducing phage and integrated into the bacterial chromosome in unit copy. By measuring the fluctuations of beta-galactosidase activity in lysogens grown in high versus low osmolarity, we have identified three regions which are necessary. Furthermore, we have determined that, although the OmpR activation site is not sufficient, OmpR is probably essential for ompF osmoregulation.

Kinetic analysis of lamB mutants suggests the signal sequence plays multiple roles in protein export

We have developed a quantitative assay to measure the rate of processing of precursor LamB into mature protein and have used this assay to characterize 10 previously isolated and 3 new lamB signal sequence mutants. The data suggest that the LamB signal sequence serves a complex function. Our assay has revealed five types of signal sequence defect: 1) a strong kinetic defect resulting from alteration of the secondary structure in the putative alpha-helical region in the hydrophobic core, 2) a strong, or 3) a weak kinetic defect due to placement of a charged residue in the hydrophobic core, 4) decreased synthesis of LamB, and 5) both a decrease in synthesis and a strong kinetic defect. The effect of an extragenic suppressor, prlA4 on the rate of processing pLamB containing signal sequence mutations was also examined and compared to the rates in wild-type strains. It was found that prlA4 increases the rate of processing in some, but not all, mutants having a kinetic defect while having no effect on the decreased synthesis seen in mutants of types 4 and 5.