Identification and characterization of a gene cluster mediating enteroaggregative Escherichia coli aggregative adherence fimbria I biogenesis.

The aggregative pattern of adherence (AA) exhibited by enteroaggregative Escherichia coli upon HEp-2 cells is a plasmid-associated property which correlates with aggregative adherence fimbria I (AAF/I) expression and human erythrocyte hemagglutination. By using cloning and mutagenesis strategies, two noncontiguous plasmid segments (designated regions 1 and 2) required for AA expression have previously been identified in enteroaggregative E. coli 17-2. TnphoA mutagenesis was performed on clones containing region 1, and 16 TnphoA mutants which were negative for the AA phenotype were analyzed. The TnphoA insertion site for each mutant was determined by junctional DNA sequencing. All 16 mutations occurred within a 4.6-kb span in region 1. Nucleotide sequence analysis of the region revealed four contiguous open reading frames, designated aggDCBA, in the same span. AA-negative TnphoA insertions into all open reading frames except aggB were obtained. On the basis of mutational analysis and protein homology data, it is inferred that aggA, aggC, and aggD are involved in biogenesis of AAF/I, encoding a major fimbrial subunit, outer membrane usher, and periplasmic fimbrial chaperone, respectively. By immunogold electron microscopy, polyclonal antiserum raised against the aggA gene product decorated AAF/I fimbriae, affirming that AggA encodes an AAF/I subunit.     

Antimonite is accumulated by the glycerol facilitator GlpF in Escherichia coli.

In a search for genes responsible for the accumulation of antimonite in Escherichia coli, TnphoA was used to create a pool of random insertional mutants, from which one antimonite-resistant mutant was isolated. Sequence analysis showed that the TnphoA insertion was located in the glpF gene, coding for the glycerol facilitator GlpF. The mutant was shown to be defective in polyol transport by GlpF. These results suggest that in solution Sb(III) is recognized as a polyol by the glycerol facilitator.     

An extraintestinal, pathogenic isolate of Escherichia coli (O4/K54/H5) can produce a group 1 capsule which is divergently regulated from its constitutively produced group 2, K54 capsular polysaccharide.

We are studying an O4/K54/H5 Escherichia coli bacteremic isolate (CP9) as a model pathogen for extraintestinal infection. Its group 2, K54 capsular polysaccharide is an important virulence determinant and confers serum resistance. In this study the effect of the group 1 capsule regulators, RcsA, RcsB, and Lon protease, on the regulation of CP9's capsular polysaccharides was assessed. It was established that in the presence of multicopy rcsA or with disruption of lon, CP9 can be induced to produce a group 1 capsule. RcsA, RcsB, and Lon are present in this K54 background and regulate group 1 capsule expression in a fashion similar to that described for K-12 strains. Two independent group 2 capsule gene protein fusions (cl1.29::TnphoA and cl1.137::TnphoA) were used to evaluate the effects of these regulators on group 2 K54 capsule production. Disruption of lon resulted in 1.9-fold (TR293 [cl1.29::TnphoA lon-146]) and 3.4-fold (TR1373 [cl1.137::TnphoA lon-146]) decreases in fusion activity at 28 degrees C, relative to the baseline level. However, decreases in fusion activity at 42 degrees C were only 1.2- and 1.4-fold, respectively. Inactivation of both lon and rcsA or lon and rcsB restored fusion activity to baseline levels at 28 degrees C, but only a partial restoration of activity was seen at higher temperatures. To assess whether these differences in fusion activity reflected a functional change in capsule production, the effects of 80% normal human serum (NHS) were tested against CP9 and TR93 (lon-146). Since the group 2 K54 capsule protects against the bactericidal activity of 80% NHS, a decrease in its production results in an increase in serum sensitivity. Viable counts of CP9 increased 10-fold in 80% NHS over 3 h at 28 degrees C, as expected. In contrast to CP9, TR93 (lon-146) incurred a 10-fold loss in viability under the same conditions. The levels of RcsA are increased in TR93 (lon 146) as consequence of lon disruption; therefore, these results in conjunction with the cl1::TnphoA protein fusion data establish RcsA as a negative regulator of the group 2 K54 capsular polysaccharide. Furthermore, these results also suggest existence of another Lon-sensitive negative regulator of group 2 K54 capsule production, which is active higher temperatures.     

Penicillin-binding proteins from Erwinia amylovora: mutants lacking PBP2 are avirulent.

Radiolabelled penicillin G was used to examine penicillin-binding proteins (PBPs) from Erwinia amylovora (OT1). This procedure identified seven PBPs with molecular masses ranging from 22 to 83 kDa. E. amylovora PBPs were compared with those from Escherichia coli (JM101) and from two spherical, avirulent TnphoA mutants derived from OT1. Radiolabelled penicillin G bound to only six proteins from the spherical mutants which lacked a 69-kDa PBP. The spherical mutants could be complemented by the cloned E. coli pbpA-rodA operon, which restored both cell shape and virulence to apple seedlings. This suggested that the E. amylovora 69-kDa PBP is probably the functional equivalent of the E. coli PBP2 protein. Southern blot analysis using the E. coli rodA and pbpA genes as radiolabelled probes showed that TnphoA had inserted into the E. amylovora equivalent of the E. coli rodA-pbpA operon. Southern blots to chromosomal DNAs of the two spherical mutants, using the cloned hrp and dsp genes from E. amylovora as radiolabelled probes, confirmed that the TnphoA insertions were not located in the region of the E. amylovora chromosome postulated to encode known virulence factors. Both of the spherical TnphoA mutants synthesized amounts of extracellular polysaccharide equivalent to those synthesized by the wild-type strain (OT1), were resistant to lysis in distilled water and to lysozyme, and elicited the hypersensitive response on nonhost plants. These results indicate a possible role for cell shape in the virulence of this plant pathogen.     

Precise excision and secondary transposition of TnphoA in non-motile mutants of a Salmonella enterica serovar Enteritidis clinical isolate

Mutagenesis with TnphoA has been widely used in many bacteria. Here, we report the excision and secondary transposition of this transposon in three non-motile (fliC, fliF and motB) mutants of Salmonella enterica serovar Enteritidis (S. Enteritidis). Isolation of motile revertants showed that they were kanamycin resistant and conserved a copy of TnphoA in their genome in an insertion site different from the initial one. They also expressed an intact flagella. Characterization of the motile revertant derived from the fliC mutant showed that TnphoA excised precisely from the fliC gene, resulting in an equivalent amount of FliC secreted protein in the revertant compared to that of the wild-type strain. These results show that TnphoA mutants should be used with care and underline the value of using transposon derivatives lacking the transposase gene.     

A homologue of the Escherichia coli DsbA protein involved in disulphide bond formation is required for enterotoxin biogenesis in Vibrio cholerae

A strain of Vibrio cholerae, which had been engineered to express high levels of the non-toxic B subunit (EtxB) of Escherichia coli heat-labile enterotoxin, was subjected to transposon (TnphoA) mutagenesis. Two chromosomal TnphoA insertion mutations of the strain were isolated that showed a severe defect in the amount of EtxB produced. The loci disrupted by TnphoA in the two mutant derivatives were cloned and sequenced, and this revealed that the transposon had inserted at different sites in the same gene. The open reading frame of the gene predicts a 200-amino-acid exported protein, with a Cys-X-X-Cys motif characteristic of thioredoxin, protein disulphide isomerase, and DsbA (a periplasmic protein required for disulphide bond formation in E. coli). The V. cholerae protein exhibited 40% identity with the DsbA protein of E. coli, including 90% identity in the region of the active-site motif. Introduction of a plasmid encoding E. coli DsbA into the V. cholerae TnphoA derivatives was found to restore enterotoxin formation, whilst expression of Etx or EtxB in a dsbA mutant of E. coli confirmed that DsbA is required for enterotoxin formation in E. coli. These results suggest that, since each EtxB subunit contains a single intramolecular disulphide bond, a transient intermolecular interaction with DsbA occurs during toxin subunit folding which catalyses formation of the disulphide in vivo.     

Symbiotic loci of Rhizobium meliloti identified by random TnphoA mutagenesis.

We have developed a system for using TnphoA (TnphoA is Tn5 IS50L::phoA), which generates fusions to alkaline phosphatase (C. Manoil and J. Beckwith, Proc. Natl. Acad. Sci. USA 82:8129-8133, 1985), in Rhizobium meliloti. Active fusions expressing alkaline phosphatase can arise only when this transposon inserts in genes encoding secreted or membrane-spanning proteins. By confining our screening to 1,250 TnphoA-generated mutants of R. meliloti that expressed alkaline phosphatase, we efficiently identified 25 symbiotically defective mutants, all of which formed ineffective (Fix-) nodules on alfalfa. Thirteen of the mutants were unable to synthesize an acidic exopolysaccharide (exo::TnphoA) that is required for nodule invasion. Twelve of the mutations created blocked at later stages of nodule development (fix::TnphoA) and were assigned to nine symbiotic loci. One of these appeared to be a previously undescribed locus located on the pRmeSU47a megaplasmid and to encode a membrane protein. Two others were located on the pRmeSU47b megaplasmid: one was a new locus which was induced by luteolin and encoded a membrane protein, and the other was dctA, the structural gene for dicarboxylic acid transport. The remaining six loci were located on the R. meliloti chromosome. One of these was inducible by luteolin and encoded a membrane protein which determined lipopolysaccharide structure. Three additional chromosomal loci also appeared to encode membrane proteins necessary for symbiosis. The remaining two chromosomal loci encoded periplasmic proteins required for symbiosis.     

A plasmid-encoded type IV fimbrial gene of enteropathogenic Escherichia coli associated with localized adherence

Enteropathogenic Escherichia coli (EPEC) form adherent microcolonies on the surface of tissue culture cells in a pattern termed localized adherence. Localized adherence requires the presence of a large EPEC adherence factor (EAF) plasmid. Recently a bundle-forming pilus has been described in EPEC possessing the EAF plasmid. An analysis of 22 non-invasive EPEC TnphoA mutants revealed that seven have insertions in the EAF plasmid and are incapable of localized adherence. We report here the mapping of the TnphoA insertions in these mutants. The nucleotide sequence of the gene interrupted in these TnphoA mutants (bfpA) was determined and found to correspond to the N-terminal amino acid sequence of the major structural protein of the bundle-forming pilus. The bfpA gene bears sequence similarities to members of the type IV fimbrial gene family and encodes a potential site for processing by a prepilin peptidase. A plasmid containing bfpA as the only open reading frame directs the synthesis of a protein recognized by antiserum raised against the bundle-forming pilus. TnphoA mutants at this locus are unable to synthesize BfpA, but synthesis is restored by introduction of a plasmid containing the cloned gene. The minimum fragment of DNA required to restore localized adherence is considerably greater than that required to restore BfpA synthesis. BfpA expression, as assessed by alkaline phosphatase activity in bfpA::TnphoA mutants, is affected by temperature and growth medium. These studies describe an EPEC plasmid-encoded fimbrial gene, a candidate for the elusive EPEC adherence factor responsible for localized adherence.     

The first gene in the Escherichia coli secA operon, gene X, encodes a nonessential secretory protein.

TnphoA insertions in the first gene of the Escherichia coli secA operon, gene X, were isolated and analyzed. Studies of the Gene X-PhoA fusion proteins showed that gene X encodes a secretory protein, since the fusion proteins possessed normal alkaline phosphatase activity and a substantial portion of this activity was found in the periplasm. In addition, the Gene X-PhoA fusion proteins were initially synthesized with a cleavable signal peptide. A gene X::TnphoA insertion was used to construct a strain containing a disrupted chromosomal copy of gene X. Analysis of this strain indicated that gene X is nonessential for cell growth and viability and does not appear to play an essential role in the process of protein export.     

Identification of a Serratia entomophila genetic locus encoding amber disease in New Zealand grass grub (Costelytra zealandica).

Serratia entomophila UC9 (A1MO2), which causes amber disease in the New Zealand grass grub Costelytra zealandica, was subjected to transposon (TnphoA)-induced mutagenesis. A mutant (UC21) was found to be nonpathogenic (Path-) to grass grub larvae in bioassays and was shown, by Southern hybridization, to contain a single TnphoA insertion. This mutant failed to adhere to the gut wall (Adn-) of the larvae and also failed to produce pili (Pil-). A comparative study of the total protein profiles of wild-type S. entomophila UC9 and mutant UC21 revealed that the mutant lacked an approximately 44-kDa protein and overexpressed an approximately 20-kDa protein. Transfer of cosmids containing homologous wild-type sequences into mutant strain UC21 restored wild-type phenotypes (Path+, Pil+, and Adn+). One of the complementing cosmids (pSER107) conferred piliation on Pil- Escherichia coli HB101. The TnphoA insertion in UC21 was mapped within an 8.6-kb BamHI fragment common to the complementing cosmids, and we designated this gene locus amb-1. Six gene products with molecular masses of 44, 36, 34, 33, 20, and 18 kDa were detected in E. coli minicells exclusive to the cloned 8.6-kb fragment (pSER201A). The 44-kDa gene product was not detected in E. coli minicells containing the cloned mutant fragment. Saturation mutagenesis of this fragment produced four unlinked insertional mutations with active fusions to TnphoA. These active fusions disrupted the expression of one or more gene products encoded by amb-1. The 8.6-kb fragment cloned in the opposite orientation (pSER201B) expressed only a 20-kDa protein. We propose that these are the products of structural and/or regulatory genes involved in adhesion and/or piliation which are prerequisites in the S. entomophila-grass grub interaction leading to amber disease.     

Construction of TnphoA gene fusions in Rhodobacter sphaeroides: isolation and characterization of a respiratory mutant unable to utilize dimethyl sulfoxide as a terminal electron acceptor during anaerobic growth in the dark on glucose.

We have constructed a suicide vector, pU1800, containing the transposable element TnphoA (Tn5 IS50L::phoA), for the purpose of producing protein fusions in vivo between the Escherichia coli alkaline phosphatase (APase) and proteins of the facultative photoheterotroph, Rhodobacter sphaeroides. We introduced TnphoA into the genome of R. sphaeroides at a coupled conjugation-transposition frequency of approximately 1 x 10(-6). Fusions giving rise to APase expression, as judged by blue-colony pigmentation when exconjugants were plated on growth medium containing the chromogenic indicator 5-bromo-4-chloro-3-indolyl phosphate, were observed in about 1% of the exconjugants. Numerous, distinguishable mutant phenotypes have been generated by this method, including those which lack the ability to use dimethyl sulfoxide as a terminal electron acceptor during anaerobic respiration, as well as those which are photosynthetically incompetent or altered in pigment synthesis, and others that express resistance to chlorate. The growth and spectral characteristics of several of these mutants, as well as the localization and quantitation of subcellular APase activity under different physiological conditions, have been examined. The presence of TnphoA in the host genome has been confirmed for each mutant analyzed, and specifically tagged DNA fragments containing TnphoA have been identified and localized; cosmids containing R. sphaeroides genomic DNA capable of complementing individual mutants have also been isolated. The usefulness of this approach in studying gene activity in R. sphaeroides is discussed.     

Regulation of Rhizobium meliloti exo genes in free-living cells and in planta examined by using TnphoA fusions.

The exo loci of Rhizobium meliloti are necessary for the production of an acidic exopolysaccharide, EPS I, that is needed for alfalfa nodule invasion by strain Rm1021. We have isolated and characterized alkaline phosphatase fusions made with TnphoA in several exo loci of R. meliloti and used these fusions to examine the subcellular localization of exo gene products and the regulation of exo genes in free-living cells and in planta. In the course of this work, we isolated a new exo locus, exoT. We have obtained evidence that several of the exo loci may encode membrane proteins. The activity of TnphoA fusions in several exo loci is increased two- to fivefold in the presence of the regulatory mutations exoR95 and exoS96. While examining the regulation of the exo gens by exoR95 and exoS96, we found that certain classes of exo mutations are lethal in an exoR95 or exoS96 background unless a plasmid complementing the exo mutation is present. This result has possible implications for the role of these exo loci in EPS I biosynthesis. We have developed a method for staining nodules specifically for the alkaline phosphatase activity present in the inducing bacteria and used this method to show that an exoF::TnphoA fusion is expressed mainly in the invasion zone of the nodule.     

FtsL, an Essential Cytoplasmic Membrane Protein Involved in Cell Division in Escherichia coli

We have identified a gene involved in bacterial cell division, located immediately upstream of the ftsI gene in the min 2 region of the Escherichia coli chromosome. This gene, which we named ftsL, was detected through characterization of TnphoA insertions in a plasmid containing this chromosomal region. TnphoA topological analysis and fractionation of alkaline phosphatase fusion proteins indicated that the ftsL gene product is a 13.6-kDa cytoplasmic membrane protein with a cytoplasmic amino terminus, a single membrane-spanning segment, and a periplasmic carboxy terminus. The ftsL gene is essential for cell growth and division. A null mutation in ftsL resulted in inhibition of cell division, formation of long, nonseptate filaments, ultimate cessation of growth, and lysis. Under certain growth conditions, depletion of FtsL or expression of the largest ftsL-phoA fusion produced a variety of cell morphologies, including Y-shaped bacteria, indicating a possible general weakening of the cell wall. The FtsL protein is estimated to be present at about 20 to 40 copies per cell. The periplasmic domain of the protein displays a sequence with features characteristic of leucine zippers, which are involved in protein dimerization.     

A modified TnphoA useful for single-stranded DNA sequencing.

The TnphoA transposon constructed by Manoil and Beckwith [Proc. Natl. Acad. Sci. USA 82 (1985) 8129-8133] has been modified to permit easy isolation of single-stranded (ss) DNA of target plasmids. The intergenic region (IG) of filamentous phage f1, which consists of the phage origin of replication and packaging signal, was inserted into a nonessential region of TnphoA. This modified transposon should be useful for the analysis of genes cloned in plasmids that lack a filamentous phage IG. Transposition of TnphoA-IG into a plasmid carries the IG with it; subsequently, after infection with a filamentous helper phage, ss plasmid DNA suitable for sequence analysis and useful for oligodeoxyribonucleotide-mediated mutagenesis of TnphoA-generated fusions can be isolated. The utility of TnphoA-IG was confirmed by analysis of 'blue hops' into the bla (encoding beta-lactamase) and pspE (encoding phage shock protein) genes whose products are secreted into the Escherichia coli periplasm.     

Transposon tnPhoA mutagenesis as a method of obtaining mutants of Azospirillum brasilense by motility and flagellation

Three A. brasilense strains (S27, SpBr14, and KR77) did not hydrolyze the chromogenic substrate of alkaline phosphatase (PhoA), X-phosphate, in situ, and were used as recipients in experiments on TnphoA mutagenesis. KMR transconjugates were obtained only for A. brasilense S27, 85% of them were also PhoA+. About 12% TnphoA mutants of A. brasilense S27 had reduces capacity to swarming and 3% of mutants neither swam nor swarmed. These totally immotile clones were examined under transmission electron microscope and were classified as Fla-Laf-, Fla-leakyLaf-, and Fla-Laf+ mutants. In Fla-Laf+ TnphoA mutants of S27, the expression of their lateral flagella (Laf) retained the wild-type inducibility. The presence of intact polar flagellum (Fla) did not seem to be obligatory for controllable expression of Laf in A. brasilense S27. The data suggest that A. brasilense S27 Fla and Laf systems have common structural and/or regulatory components. The PhoA+ phenotype of S27 Fla- mutants suggested a periplasmic and/or membrane localization of the hybrid proteins, the formation of which blocks the flagellar assembly or functioning. Immunochemical analysis with antibodies to alkaline phosphatase will identify these proteins.     

Molecular cloning and characterization of acrA and acrE genes of Escherichia coli.

The DNA fragment containing the acrA locus of the Escherichia coli chromosome has been cloned by using a complementation test. The nucleotide sequence indicates the presence of two open reading frames (ORFs). Sequence analysis suggests that the first ORF encodes a 397-residue lipoprotein with a 24-amino-acid signal peptide at its N terminus. One inactive allele of acrA from strain N43 was shown to contain an IS2 element inserted into this ORF. Therefore, this ORF was designated acrA. The second downstream ORF is predicted to encode a transmembrane protein of 1,049 amino acids and is named acrE. Genes acrA and acrE are probably located on the same operon, and both of their products are likely to affect drug susceptibilities observed in wild-type cells. The cellular localizations of these polypeptides have been analyzed by making acrA::TnphoA and acrE::TnphoA fusion proteins. Interestingly, AcrA and AcrE share 65 and 77% amino acid identity with two other E. coli polypeptides, EnvC and EnvD, respectively. Drug susceptibilities in one acrA mutant (N43) and one envCD mutant (PM61) have been determined and compared. Finally, the possible functions of these proteins are discussed.