Characterisation of the promoters for the ompA gene which encodes a major outer membrane protein of Escherichia coli

Fluorescence based primer extension technique to determine transcriptional starting points and cleavage sites of RNases in vivo

Fluorescence based primer extension (FPE) is a molecular method to determine transcriptional starting points or processing sites of RNA molecules. This is achieved by reverse transcription of the RNA of interest using specific fluorescently labeled primers and subsequent analysis of the resulting cDNA fragments by denaturing polyacrylamide gel electrophoresis. Simultaneously, a traditional Sanger sequencing reaction is run on the gel to map the ends of the cDNA fragments to their exact corresponding bases. In contrast to 5'-RACE (Rapid Amplification of cDNA Ends), where the product must be cloned and multiple candidates sequenced, the bulk of cDNA fragments generated by primer extension can be simultaneously detected in one gel run. In addition, the whole procedure (from reverse transcription to final analysis of the results) can be completed in one working day. By using fluorescently labeled primers, the use of hazardous radioactive isotope labeled reagents can be avoided and processing times are reduced as products can be detected during the electrophoresis procedure. In the following protocol, we describe an in vivo fluorescent primer extension method to reliably and rapidly detect the 5' ends of RNAs to deduce transcriptional starting points and RNA processing sites (e.g., by toxin-antitoxin system components) in S. aureus, E. coli and other bacteria.

Autodisplay of functional CYP106A2 in Escherichia coli

Cytochrome P450 enzymes catalyse a wide variety of reactions, including the hydroxylation and epoxidation of CC bonds, and dealkylation reactions. There is high interest in these reactions for biotechnology and pharmaceutical processes. Many P450s require membrane surroundings and have substrates that do not cross biological membranes. To circumvent these obstacles, CYP106A2 from Bacillus megaterium was expressed on the outer membrane of Escherichia coli cells by Autodisplay. Exposure on the surface was confirmed by a protease accessibility test and flow cytometry after immunolabelling. HPLC assays showed that 0.5 ml of cells displaying the enzyme (OD₅₇₈ = 6) converted 9.13 μmol of deoxycorticosterone to 15β-OH-deoxycorticosterone within 1h. Imipramine and abietic acid were also accepted as substrates. The number of active enzyme molecules per cell was calculated to be 20,000. Surprisingly, surface-exposed CYP106A2 was active in E. coli BL21 without the external addition of the heme group. However, when CYP106A2 was expressed on the surface of an E. coli strain lacking the TolC channel protein (JW5503), enzymatic activity was almost completely abolished. The activity of CYP106A2 on the surface of E. coli JW5503 could be restored by the external addition of the heme group. This suggests, as has been reported before, that E. coli uses a TolC-dependent mechanism to export heme into the growth media, where it can be scavenged by a surface-displayed apoenzyme. Our results indicate that Autodisplay enables the functional surface display of P450 enzymes and provides a new platform to access their synthetic potential.

Genome-wide identification of transcription start sites, promoters and transcription factor binding sites in E. coli

Despite almost 40 years of molecular genetics research in Escherichia coli a major fraction of its Transcription Start Sites (TSSs) are still unknown, limiting therefore our understanding of the regulatory circuits that control gene expression in this model organism. RegulonDB (http://regulondb.ccg.unam.mx/) is aimed at integrating the genetic regulatory network of E. coli K12 as an entirely bioinformatic project up till now. In this work, we extended its aims by generating experimental data at a genome scale on TSSs, promoters and regulatory regions. We implemented a modified 5' RACE protocol and an unbiased High Throughput Pyrosequencing Strategy (HTPS) that allowed us to map more than 1700 TSSs with high precision. From this collection, about 230 corresponded to previously reported TSSs, which helped us to benchmark both our methodologies and the accuracy of the previous mapping experiments. The other ca 1500 TSSs mapped belong to about 1000 different genes, many of them with no assigned function. We identified promoter sequences and type of sigma factors that control the expression of about 80% of these genes. As expected, the housekeeping sigma(70) was the most common type of promoter, followed by sigma(38). The majority of the putative TSSs were located between 20 to 40 nucleotides from the translational start site. Putative regulatory binding sites for transcription factors were detected upstream of many TSSs. For a few transcripts, riboswitches and small RNAs were found. Several genes also had additional TSSs within the coding region. Unexpectedly, the HTPS experiments revealed extensive antisense transcription, probably for regulatory functions. The new information in RegulonDB, now with more than 2400 experimentally determined TSSs, strengthens the accuracy of promoter prediction, operon structure, and regulatory networks and provides valuable new information that will facilitate the understanding from a global perspective the complex and intricate regulatory network that operates in E. coli.

Fis stabilizes the interaction between RNA polymerase and the ribosomal promoter rrnB P1, leading to transcriptional activation

It has been shown that Fis activates transcription of the ribosomal promoter rrnB P1; however, the mechanism by which Fis activates rrnB P1 transcription is not fully understood. Paradoxically, although Fis activates transcription of rrnB P1 in vitro, transcription from the promoter containing Fis sites (as measured from rrnB P1-lacZ fusions) is not reduced in a fis null mutant strain. In this study, we further investigated the mechanism by which Fis activates transcription of the rrnB P1 promoter and the role of Fis in rRNA synthesis and cell growth in Escherichia coli. Like all other stringent promoters investigated so far, open complex of rrnB P1 has been shown to be intrinsically unstable, making open complex stability a potential regulatory step in transcription of this class of promoters. Our results show that Fis acts at this regulatory step by stabilizing the interaction between RNA polymerase and rrnB P1 in the absence of NTPs. Mutational analysis of the Fis protein demonstrates that there is a complete correlation between Fis-mediated transcriptional activation of rrnB P1 and Fis-mediated stabilization of preinitiation complexes of the promoter. Thus, our study indicates that Fis-mediated stabilization of RNA polymerase-rrnB P1 preinitiation complexes, presumably at the open complex step, contributes prominently to transcriptional activation. Furthermore, our in vivo results show that rRNA synthesis from the P1 promoters of several rRNA operons are reduced 2-fold in a fis null mutant compared with the wild type strain, indicating that Fis plays an important role in the establishment of robust rRNA synthesis when E. coli cells are emerging from a growth-arrested phase to a rapid growth phase. Thus, our results resolve an apparent paradox of the role of Fis in vitro and in vivo in the field.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Aeromonas salmonicida possesses two genes encoding homologs of the major outer membrane protein, OmpA

Two homologs of the outer membrane protein OmpA were identified in Aeromonas salmonicida by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, and amino-terminal sequence analyses. An A. salmonicida genomic DNA library was constructed by using lambda GEM-11 and recombinant phage carrying both genes ompAI and ompAII) selected by immunoscreening. A 5.0-kb BamHI fragment containing the two genes in tandem was subcloned in pBluescript and used for further subcloning and sequencing of the genes. The encoded proteins (Mr = 33,564 and 32,536 for mature OmpAI and OmpAII, respectively) had only 64% identity with each other and otherwise had the highest level of homology to OmpA proteins from the members of the family Enterobacteriaceae. Based on the Escherichia coli OmpA model, an eight-stranded amphipathic beta-barrel model for the membrane assembly of the N-terminal half of OmpAI and OmpAII was predicted. Most variation between the two proteins was localized to the predicted surface loops and periplasmic turns, while the transmembrane strands and C-terminals domains were highly conserved. Expression of ompAI and ompAII separately in E. coli indicated that both genes could be independently transcribed from their own promoters and that both gene products were assembled into the E. coli outer membrane. A survey of different Aeromonas spp. by PCR revealed that possession of two tandem ompA genes was widespread among this genus. This is the first report of any bacterial species possessing two genes for homologs of this major outer membrane protein.

Compilation of E. coli mRNA promoter sequences

An updated compilation of 300 E. coli mRNA promoter sequences is presented. For each sequence the most recent relevant paper was checked, to verify the location of the transcriptional start position as identified experimentally. We comment on the reliability of the sequence databanks and analyze the conservation of known promoter features in the current compilation. This database is available by E-mail.

Cloning and sequencing of a gene encoding a 21-kilodalton outer membrane protein from Bordetella avium and expression of the gene in Salmonella typhimurium

Three gene libraries of Bordetella avium 197 DNA were prepared in Escherichia coli LE392 by using the cosmid vectors pCP13 and pYA2329, a derivative of pCP13 specifying spectinomycin resistance. The cosmid libraries were screened with convalescent-phase anti-B. avium turkey sera and polyclonal rabbit antisera against B. avium 197 outer membrane proteins. One E. coli recombinant clone produced a 56-kDa protein which reacted with convalescent-phase serum from a turkey infected with B. avium 197. In addition, five E. coli recombinant clones were identified which produced B. avium outer membrane proteins with molecular masses of 21, 38, 40, 43, and 48 kDa. At least one of these E. coli clones, which encoded the 21-kDa protein, reacted with both convalescent-phase turkey sera and antibody against B. avium 197 outer membrane proteins. The gene for the 21-kDa outer membrane protein was localized by Tn5seq1 mutagenesis, and the nucleotide sequence was determined by dideoxy sequencing. DNA sequence analysis of the 21-kDa protein revealed an open reading frame of 582 bases that resulted in a predicted protein of 194 amino acids. Comparison of the predicted amino acid sequence of the gene encoding the 21-kDa outer membrane protein with protein sequences in the National Biomedical Research Foundation protein sequence data base indicated significant homology to the OmpA proteins of Shigella dysenteriae, Enterobacter aerogenes, E. coli, and Salmonella typhimurium and to Neisseria gonorrhoeae outer membrane protein III, Haemophilus influenzae protein P6, and Pseudomonas aeruginosa porin protein F. The gene (ompA) encoding the B. avium 21-kDa protein hybridized with 4.1-kb DNA fragments from EcoRI-digested, chromosomal DNA of Bordetella pertussis and Bordetella bronchiseptica and with 6.0- and 3.2-kb DNA fragments from EcoRI-digested, chromosomal DNA of B. avium and B. avium-like DNA, respectively. A 6.75-kb DNA fragment encoding the B. avium 21-kDa protein was subcloned into the Asd+ vector pYA292, and the construct was introduced into the avirulent delta cya delta crp delta asd S. typhimurium chi 3987 for oral immunization of birds. The gene encoding the 21-kDa protein was expressed equivalently in B. avium 197, delta asd E. coli chi 6097, and S. typhimurium chi 3987 and was localized primarily in the cytoplasmic membrane and outer membrane. In preliminary studies on oral inoculation of turkey poults with S. typhimurium chi 3987 expressing the gene encoding the B. avium 21-kDa protein, it was determined that a single dose of the recombinant Salmonella vaccine failed to elicit serum antibodies against the 21-kDa protein and challenge with wild-type B. avium 197 resulted in colonization of the trachea and thymus with B. avium 197.

Differentiation of lactococci by rRNA gene restriction analysis

Strains of the subspecies of Lactococcus lactis could be differentiated by rRNA gene restriction fragment length polymorphisms (RFLP). 16S rRNA-specific oligonucleotide as well as polynucleotide DNA probes were used for the detection of restriction fragments. In addition, a site-specific probe was designed for the intergenic spacer region of 23S and 5S rRNA genes. For all lactococcal strains the putative presence of six rRNA operons was confirmed. A non-radioactive hybridization assay was used based on hybrid detection by chemiluminescence. Specific patterns were found for any of the strains investigated. Subspecies-specific restriction fragments could be identified in addition to the strain-specific patterns.

The ompA 5' untranslated RNA segment functions in Escherichia coli as a growth-rate-regulated mRNA stabilizer whose activity is unrelated to translational efficiency

The 5' untranslated region (UTR) of the long-lived Escherichia coli ompA message can function in vivo as an mRNA stabilizer. Substitution of this ompA mRNA segment for the corresponding segment of the labile bla gene transcripts prolongs their lifetime by a factor of 6. We show here that the function of this ompA mRNA stabilizer requires the presence of a 115-nucleotide ompA RNA segment that lies upstream of the ribosome-binding site. Although deletion of this segment reduced the half-life of the ompA transcript by a factor of 5, its absence had almost no effect on the translational efficiency of ompA mRNA. Like the ompA transcript, but unlike bla mRNA, hybrid ompA-bla messages containing the complete ompA 5' UTR were significantly less stable under conditions of slow bacterial growth. We conclude that the stabilizing activity of the ompA 5' UTR is growth rate regulated and that the mechanism of mRNA stabilization by this RNA segment is not related to the spacing between translating ribosomes.

Linkage map of Escherichia coli K-12, edition 8

The linkage map of Escherichia coli K-12 depicts the arrangement of genes on the circular chromosome of this organism. The basic units of the map are minutes, determined by the time-of-entry of markers from Hfr into F- strains in interrupted-conjugation experiments. The time-of-entry distances have been refined over the years by determination of the frequency of cotransduction of loci in transduction experiments utilizing bacteriophage P1, which transduces segments of DNA approximately 2 min in length. In recent years, the relative positions of many genes have been determined even more precisely by physical techniques, including the mapping of restriction fragments and the sequencing of many small regions of the chromosome. On the whole, the agreement between results obtained by genetic and physical methods has been remarkably good considering the different levels of accuracy to be expected of the methods used. There are now few regions of the map whose length is still in some doubt. In some regions, genetic experiments utilizing different mutant strains give different map distances. In other regions, the genetic markers available have not been close enough to give accurate cotransduction data. The chromosome is now known to contain several inserted elements apparently derived from lambdoid phages and other sources. The nature of the region in which the termination of replication of the chromosome occurs is now known to be much more complex than the picture given in the previous map. The present map is based upon the published literature through June of 1988. There are now 1,403 loci placed on the linkage group, which may represent between one-third and one-half of the genes in this organism.

(S)-3-hydroxy-3-methylglutaryl coenzyme A reductase, a product of the mva operon of Pseudomonas mevalonii, is regulated at the transcriptional level

We have cloned and sequenced a 505-base-pair (bp) segment of DNA situated upstream of mvaA, the structural gene for (S)-3-hydroxy-3-methylglutaryl coenzyme A reductase (EC 1.1.1.88) of Pseudomonas mevalonii. The DNA segment that we characterized includes the promoter region for the mva operon. Nuclease S1 mapping and primer extension analysis showed that mvaA is the promoter-proximal gene of the mva operon. Transcription initiates at -56 bp relative to the first A (+1) of the translation start site. Transcription in vivo was induced by mevalonate. Structural features of the mva promoter region include an 80-bp A + T-rich region, and -12, -24 consensus sequences that resemble sequences of sigma 54 promoters in enteric organisms. The relative amplitudes of catalytic activity, enzyme protein, and mvaA mRNA are consistent with a model of regulation of this operon at the transcriptional level.

Transcription of the sulA-ompA region of Escherichia coli during the SOS response and the role of an antisense RNA molecule

The transcriptional pattern of the 22 min region of the Escherichia coli chromosome containing the linked sulA and ompA genes, which encode an SOS-inducible inhibitor of cell division and a constitutively expressed, major outer membrane protein, respectively, has been re-examined. During normal growth, the sulA gene was repressed whereas the ompA gene produced a stable 1250 nucleotide transcript. Counter-transcription of sulA occurred from a promoter situated in the sulA-ompA intergenic region and the product of this transcriptional circuit, named isf, is a 353 nucleotide untranslated RNA. Since the isf RNA is complementary to the 3'-end of the sulA transcript, it could modulate sulA function by serving as an anti-messenger. On induction of the SOS-response, massive transcription of sulA took place, resulting in the 'silencing' of the isf gene, production of an abundant approximately 615 nucleotide sulA mRNA and a novel hybrid transcript of approximately 2100 nucleotides encoding both the SulA and OmpA proteins. Production of the latter RNA species, caused by transcription reading through the sulA terminator, the intergenic region and the coding sequences, was accompanied by a decrease in the abundance of the ompA mRNA as a result of promoter occlusion. However, the amount of OmpA protein produced was only slightly reduced.

Developmental regulation of tandem promoters for the major outer membrane protein gene of Chlamydia trachomatis

Chlamydia trachomatis has a biphasic developmental cycle which is characterized by qualitative and quantitative changes in protein expression. The molecular mechanisms that mediate these changes are unknown. Evidence for transcriptional regulation of the chlamydial major outer membrane protein gene (omp1) was found by Northern hybridization of RNA isolated sequentially during the chlamydial developmental cycle. Early in the growth cycle a single transcript was detected, which was followed hours later in the cycle by an additional transcript. Mapping of the initiating nucleotide for each transcript suggested that this gene is regulated by differential transcription from tandem promoters.

Evolution of the enterobacterial sulA gene: a component of the SOS system encoding an inhibitor of cell division

The LexA-regulated sulA (sfiA) gene of Escherichia coli encodes an unstable protein which inhibits cell division. By determining the nucleotide sequences of the corresponding genes from the related bacteria Salmonella typhimurium, Enterobacter aerogenes and Serratia marcescens it was found that the regulatory region and the LexA binding site (SOS box) have been better conserved during evolution than the coding sequence. The N terminus of the SulA protein [amino acid (aa) residues 1-30] has diverged extensively during the evolution of Enterobacteriaceae, whereas the central region (aa residues 31-149) has been well conserved. At the C terminus a sequence showing some homology to the N protein of phage lambda was detected that may represent a recognition site for the Lon protease, which is known to degrade both polypeptides. When expressed in E. coli, the foreign sulA genes did not block cell division suggesting that their products are inactive. This may indicate that the N terminus of the SulA protein is involved in recognizing the cell division apparatus.

The stability of E. coli gene transcripts is dependent on determinants localized to specific mRNA segments

To map the structural features responsible for the 5-fold difference in stability of the E. coli ompA and bla gene transcripts, we have constructed gene fusions that encode chimeric ompA/bla transcripts and a deletion that eliminates a large internal segment of bla mRNA. Shortening of bla transcripts by internal deletion or replacement of the 3' end with the corresponding segment of the ompA transcript had little effect on bla mRNA stability. However, fusion of a 5'-terminal 147 nucleotide segment of the ompA message 5' to full-length or truncated bla transcripts increased the half-life of the bla segments 3- to 5-fold. These and other findings indicate that E. coli transcripts contain discrete structural determinants of stability and instability that can influence the decay rate of linked mRNA segments derived from other genes.

Bacteriophage receptor area of outer membrane protein OmpA of Escherichia coli K-12

A number of T-even-like bacteriophages use the outer membrane protein OmpA of Escherichia coli as a receptor. We had previously analyzed a series of ompA mutants which are resistant to such phages and which still produce the OmpA protein (R. Morona, M. Klose, and U. Henning, J. Bacteriol. 159:570-578, 1984). Mutational alterations were found near or at residues 70, 110 and 154. Based on these and other results a model was proposed showing the amino-terminal half of the 325-residue protein crossing the outer membrane repeatedly and being cell surface exposed near residues 25, 70, 110, and 154. We characterized, by DNA sequence analysis, an additional 14 independently isolated phage-resistant ompA mutants which still synthesize the protein. Six of the mutants had alterations identical to the ones described before. The other eight mutants possessed seven new alterations: Ile-24----Asn, Gly-28----Val, deletion of Glu-68, Gly-70----Cys, Ser-108----Phe, Ser-108----Pro, and Gly-154----Asp (two isolates). Only the latter alteration resulted in a conjugation-deficient phenotype. The substitutions at Ile-24 and Gly-28 confirmed the expectation that this area of the protein also participates in its phage receptor region. It is unlikely that still other such sites of the protein are involved in the binding of phage, and it appears that the phage receptor area of the protein has now been characterized completely.

The nature of ompA mutants of Escherichia coli K12 exhibiting temperature-sensitive bacteriophage resistance

A class of ompA mutants of Escherichia coli, exhibiting temperature-sensitive resistance towards phages using the OmpA protein as receptor, was analysed. The mutants produce detectable levels of the protein at 42 degrees C but not at 30 degrees C (Manning and Reeves 1976). They were found to have a deletion (one isolate) or insertions (three isolates) upstream of the coding part of the ompA gene. Several previously characterized mutants possessing insertions or a deletion in the non-translated 5' area of the gene also exhibited a similar temperature-sensitive phage resistance. This cold-sensitive phenotype is explained in terms of the recent discovery that the stability of ompA mRNA is regulated by the rate of cell growth (Nilsson et al. 1984).

Lethal mutations in the structural gene of an outer membrane protein (OmpA) of Escherichia coli K12

The gene ompA encodes a major outer membrane protein of Escherichia coli. Localized mutagenesis of the part of the gene corresponding to the 21-residue signal sequence and the first 45 residues of the protein resulted in alterations which caused cell lysis when expressed. DNA sequence analyses revealed that in one mutant type the last CO2H-terminal residue of the signal sequence, alanine, was replaced by valine. The proteolytic removal of the signal peptide was much delayed and most of the unprocessed precursor protein was fractioned with the outer membrane. However, this precursor was completely soluble in sodium lauryl sarcosinate which does not solubilize the OmpA protein or fragments thereof present in the outer membrane. Synthesis of the mutant protein did not inhibit processing of the OmpA or OmpF proteins. In the other mutant type, multiple mutational alterations had occurred leading to four amino acid substitutions in the signal sequence and two affecting the first two residues of the mature protein. A reduced rate of processing could not be clearly demonstrated. Membrane fractionation suggested that small amounts of this precursor were associated with the plasma membrane but synthesis of this mutant protein also did not inhibit processing of the wild-type OmpA or OmpF proteins. Several lines of evidence left no doubt that the mature mutant protein is stably incorporated into the outer membrane. It is suggested that the presence, in the outer membrane, of the mutant precursor protein in the former case, or of the mutant protein in the latter case perturbs the membrane architecture enough to cause cell death.

Host range mutants of bacteriophage Ox2 can use two different outer membrane proteins of Escherichia coli K-12 as receptors

The Escherichia coli K-12 outer membrane protein OmpA functions as the receptor for bacteriophage Ox2. We isolated a host range mutant of this phage which was able to grow on an Ox2-resistant ompA mutant producing an altered OmpA protein. From this mutant, Ox2h5, a second-step host range mutant was recovered which formed turbid plaques on a strain completely lacking the OmpA protein. From one of these mutants, Ox2h10, a third-step host range mutant, Ox2h12, was isolated which formed clear plaques on a strain missing the OmpA protein. Ox2h10 and Ox2h12 apparently were able to use both outer membrane proteins OmpA and OmpC as receptors. Whereas there two proteins are very different with respect to primary structures and functions, the OmpC protein is very closely related to another outer membrane protein, OmpF, which was not recognized by Ox2h10 or Ox2h12. An examination of the OmpC amino acid sequence, in the regions where it differs from that of OmpF, revealed that one region shares considerable homology with a region of the OmpA protein which most likely is required for phage Ox2 receptor activity.

Roles of the 5' leader region of the ompA mRNA

OmpA protein, a major outer membrane protein of Escherichia coli, is synthesized from a messenger RNA containing a 134-nucleotide 5' leader region. The role of this leader region in efficient ompA expression was investigated using a series of ompA-lacZ fusion plasmids. These plasmids differ in the amount of DNA encoding the ompA leader region which is fused to the lacZ structural gene. The fusion containing all but six nucleotides of the ompA leader produced the highest beta-galactosidase activity, while the fusion containing the shortest leader synthesized only 4% as much beta-galactosidase. Fusions with leaders intermediate in length produced between 6% and 24% of the activity found in the most efficient fusion. Quantitation of lacZ mRNA synthesis by DNA-RNA hybridization revealed differences in lacZ mRNA production reflecting the observed differences in beta-galactosidase activity. The primary effect of the ompA leader in maintaining high levels of mRNA is discussed in terms of the roles of mRNA secondary structure.

DNA sequence analysis of the Serratia marcescens ompA gene: implications for the organisation of an enterobacterial outer membrane protein

The cloned ompA gene from Serratia marcescens was fully expressed in Escherichia coli and its product correctly assembled into the outer membrane. The S. marcescens polypeptide was not functionally equivalent to the E. coli OmpA protein, which serves as a phage receptor and as a component of several colicin uptake systems. DNA sequence analysis of the gene showed that three regions of the protein likely to be exposed on the cell surface not only differed extensively from the corresponding regions of the E. coli polypeptide but also from all other sequenced OmpA proteins. It is suggested that this sequence polymorphism represents a safety mechanism by which the various enterobacterial species can avoid cross-infection by noxious agents such as phages or colicins.

Molecular characterization of the gene coding for major outer membrane protein OmpA from Enterobacter aerogenes

The ompA gene from Enterobacter aerogenes was subcloned into a low-copy-number plasmid vector and the resultant plasmid, pTU7En, used to study its expression in Escherichia coli K12. Although the gene was strongly expressed and large amounts of OmpA protein were present in the outer membrane its product was not functionally identical to the E. coli polypeptide. In particular, the E. aerogenes OmpA protein was unable to confer sensitivity to OmpA-specific phages of E. coli. When the primary structure of the protein was deduced from the nucleotide sequence of its gene it was found that three domains differed extensively from the corresponding regions of the E. coli protein. As two of these are known to be exposed on the cell surface we inferred that these alterations are responsible for differences in the biological activity of the two proteins.

Gene fusions using the ompA gene coding for a major outer-membrane protein of Escherichia coli K12

It has been shown previously that fragments of the Escherichia coli major outer membrane protein OmpA lacking CO2H-terminal parts can be incorporated into this membrane in vivo [Bremer et al. (1982) Eur. J. Biochem. 122, 223-231]. The possibility that these fragments can be used, via gene fusions, as vehicles to transport other proteins to the outer membrane has been investigated. To test whether fragments of a certain size were optimal for this purpose a set of plasmids was prepared encoding 160, 193, 228, 274, and 280 NH2-terminal amino acids of the 325-residue OmpA protein. The 160-residue fragment was not assembled into the outer membrane whereas the others were all incorporated with equal efficiencies. Thus, if any kind of OmpA-associated stop transfer is required during export the corresponding signal might be present between residues 160 and 193 but not CO2H-terminal to 193. The ompA gene was fused to the gene (tet) specifying tetracycline resistance and the gene for the major antigen (vp1) of foot-and-mouth disease virus. In the former case a 584-residue chimeric protein is encoded consisting NH2-terminally of 228 OmpA residues followed by 356 CO2H-terminal residues of the 396-residue 'tetracycline resistance protein'. In the other case the same part of OmpA is followed by 250 CO2H-terminal residues of the 213-residue Vp1 plus 107 residues partly derived from another viral protein and from the vector. Full expression of both hybrids proved to be lethal. Lipophilic sequences bordered by basic residues, present in the non-OmpA parts of both hybrids were considered as candidates for the lethal effect. A plasmid was constructed which codes for 280 OmpA residues followed by a 31-residue tail containing the sequence: -Phe-Val-Ile-Met-Val-Ile-Ala-Val-Ser-Cys-Lys-. Expression of this hybrid gene was lethal but by changing the reading frame for the tail to encode another, 30-residue sequence the deleterious effect was abolished. It is possible that the sequence incriminated acts as a stop signal for transfer through the plasma membrane thereby jamming export sites for other proteins and causing lethality. If so, OmpA appears to cross the plasma membrane completely during export.

Cloning and molecular characterization of the ompA gene from Salmonella typhimurium

The ompA gene from Salmonella typhimurium, encoding a major heat-modifiable protein of the outer membrane, has been cloned and extensively characterized. When expressed in Escherichia coli the gene directs the synthesis of an OmpA protein which is functionally and topologically indistinguishable from that made in S. typhimurium, thus indicating that export and membrane incorporation are very similar in the two organisms. The S. typhimurium protein effectively substitutes for the E. coli polypeptide in F-dependent conjugation and in the uptake of certain colicins, although it cannot serve as the receptor for the OmpA-specific phages K3 and TuII. On examination of the primary sequence of the protein, predicted from the nucleotide sequence of its gene, it was found that those domains likely to be exposed on the cell surface were significantly different to the corresponding regions of the E. coli polypeptide. These differences in the structure of the two proteins have been used to interpret differences in their biological activities.