DNA sequence analysis of point mutations in traA, the F pilin gene, reveal two domains involved in F-specific bacteriophage attachment

Summary Six missense point mutations in traA (WPFL43,44,45,46,47 and 51), the gene encoding F pilin in the transfer region of the F plasmid, have been characterized for their effect on the transfer ability, bacteriophage (R17, QB and fl) sensitivity and levels of piliation expressed by the plasmid. The sequence analysis of the first five of these mutations revealed two domains in the F pilin subunit exposed on the surface of the F pilus which mediate phage attachment. These two domains include residues 14–17 (approximately) and the last few residues at the carboxy-terminus of the pilin protein. One of these mutants had a pleiotropic affect on pilus function and was thought to have affected pilus assembly. The sixthe point mutant (WPFL51), previously thought to be in traA, was complemented by chimeric plasmids carrying the traG gene of the F transfer region, which may be involved in the acetylation of the pilin subunit. A traA nonsense mutant (JCFL1) carried an amber mutation near the amino-terminus which is well suppressed in SuI⁺ (supD) and SuIII⁺ (supF) strains. Neither the antigenicity of the pilin nor the efficiency of plating of F-specific bacteriophages were affected when this plasmid was harbored by either suppressor strain. A second amber mutant (JCFL25) which is not suppressible, carried its mutation in the codon for the single tryptophan in F pilin, suggesting that this residue is important in subunit interactions during pilus assembly. Two other point mutants (JCFL32 and 44) carried missense mutations in the leader sequence (positions 9 and 13) which affected the number of pili per cell presumably by altering the processing of propilin to pilin.     

Coordination of Sex Pili with their Specifying R Factors

A single bacterial cell can simultaneously carry both F-like (fi⁺) and I-like (fi^?) R factors and, when the R factors are de-repressed, most cells produce both F-like and I-like sex pili. These pili can be distinguished immunologically and by their capacity to adsorb different phages¹. The F pilus is the receptor for RNA phages such as MS2 and filamentous DNA phages such as M13. The I pilus is the receptor for other filamentous DNA phages such as If1 and If2. Electron microscopy suggests that these filamentous DNA phages, both F-specific and I-specific, adsorb to the tip of the pilus^2,3.     

Processed VirB2 Is the Major Subunit of the Promiscuous Pilus of Agrobacterium tumefaciens

Previous studies have implicated the obligatory requirement for the vir regulon (or “virulon”) of the Ti plasmid for the transfer of oncogenes from Agrobacterium tumefaciens to plant cells. The machinery used in this horizontal gene transfer has been long thought to be a transformation or conjugative delivery system. Based on recent protein sequence comparisons, the proteins encoded by the virB operon are strikingly similar to proteins involved in the synthesis and assembly of conjugative pili such as the conjugative pilus of F plasmid in Escherichia coli. The F pilus is composed of TraA pilin subunits derived from TraA propilin. In the present study, evidence is provided showing that the counterpart of TraA is VirB2, which like TraA propilin is processed into a 7.2-kDa product that comprises the pilus subunit as demonstrated by biochemical and electron microscopic analyses. The processed VirB2 protein is present exocellularly on medium on which induced A. tumefaciens had grown and appears as thin filaments of 10 nm that react specifically to VirB2 antibody. Exocellular VirB2 is produced abundantly at 19°C as compared with 28°C, an observation that parallels the effect of low temperature on the production of vir gene-specific pili observed previously (K. J. Fullner, L. C. Lara, and E. W. Nester, Science 273:1107–1109, 1996). Export of the processed VirB2 requires other virB genes since mutations in these genes cause the loss of VirB2 pilus formation and result in processed VirB2 accumulation in the cell. The presence of exocellular processed VirB2 is directly correlated with the formation of pili, and it appears as the major protein in the purified pilus preparation. The evidence provides a compelling argument for VirB2 as the propilin whose 7.2-kDa processed product is the pilin subunit of the promiscuous conjugative pilus, hereafter called the “T pilus” of A. tumefaciens.     

Location of a function on RP1 that fertility inhibits Inc W plasmids

Two fertility inhibition (Fi⁺) functions which reduce R388(Inc W) transfer were detected on RP1(Inc P). Neither function affected R388-mediated surface exclusion but they could be distinguished by their effect on pilus production. One of the functions was located in the 6.5-kb Pst1-C region of RP1, part or all of which also occurs on six Fi⁺ but not two Fi^? Inc P plasmids studied.     

Five control systems preventing transfer of Escherichia coli K-12 sex factor F.

The transfer inhibition systems of 28 Fin+ plasmids have been characterized, using Flac mutants insensitive to inhibition by R100 or R62. All F-like plasmids (except R455) and one N group plasmid determined systems analogous to that of R100; this is designated the FinOP system. None of these plasmids could supply a FinP component of the transfer inhibitor able to replace that of F itself. In addition to the FinOP and R62 transfer inhibition systems described previously, new systems were encoded by the F-like plasmid R455, the I-like plasmid JR66a, and the group X plasmid R485. Besides inhibiting F transfer, JR66a also inhibited F pilus formation and surface exclusion, whereas R485 inhibited only pilus formation and R455 inhibited neither. All three R factors inhibited transfer of J-independent Flac elements, indicating that they act directly on one or more genes (or products) of the transfer operon, rather than directly via traJ. The tral products and transfer origin sequences of two Fin+ F-like plasmids, ColB2 and R124, appear to have similar specificities to those of F itself.     

Type IV secretion in Gram‐negative and Gram‐positive bacteria

Type IV secretion systems (T4SSs) are versatile multiprotein nanomachines spanning the entire cell envelope in Gram‐negative and Gram‐positive bacteria. They play important roles through the contact‐dependent secretion of effector molecules into eukaryotic hosts and conjugative transfer of mobile DNA elements as well as contact‐independent exchange of DNA with the extracellular milieu. In the last few years, many details on the molecular mechanisms of T4SSs have been elucidated. Exciting structures of T4SS complexes from Escherichia coli plasmids R388 and pKM101, Helicobacter pylori and Legionella pneumophila have been solved. The structure of the F‐pilus was also reported and surprisingly revealed a filament composed of pilin subunits in 1:1 stoichiometry with phospholipid molecules. Many new T4SSs have been identified and characterized, underscoring the structural and functional diversity of this secretion superfamily. Complex regulatory circuits also have been shown to control T4SS machine production in response to host cell physiological status or a quorum of bacterial recipient cells in the vicinity. Here, we summarize recent advances in our knowledge of ‘paradigmatic’ and emerging systems, and further explore how new basic insights are aiding in the design of strategies aimed at suppressing T4SS functions in bacterial infections and spread of antimicrobial resistances.     

In vivo formation of a plasmid cointegrate expressing two incompatibility phenotypes

Plasmids of the N- and M-incompatibility groups were identified in a clinical isolate of Shigella sonnei. The IncN plasmid pDT200 encoded resistance to trimethoprim, streptomycin, and sulfamethoxazole, and specified N-type pili which were synthesized constitutively. The IncM plasmid mediated resistance to ampicillin, chloramphenicol, streptomycin, sulfamethoxazole, and tetracycline. It was fi⁺ and was repressed for pilus synthesis. Pili specified appeared to be of the FII-type. A recombinant plasmid was formed on transfer of these plasmids from Sh. sonnei to Escherichia coli. The cointegrate plasmid expressed two incompatibility phenotypes and encoded two types of pilus. The incompatibility behavior of the cointegrate plasmid formed in vivo resembled that of composite plasmids constructed by in vitro linkage experiments. The finding that plasmids from clinical isolates may express two incompatibility phenotypes and two types of pilus, and that the pilus type and incompatibility group may not necessarily correspond, has important implications for plasmid classification schemes.     

Genetic Analysis of the Role of the Transfer Gene, traN, of the F and R100-1 Plasmids in Mating Pair Stabilization during Conjugation

Mating pair stabilization occurs during conjugative DNA transfer whereby the donor and recipient cells form a tight junction which requires pili as well as TraN and TraG in the donor cell. The role of the outer membrane protein, TraN, during conjugative transfer was examined by introduction of a chloramphenicol resistance cassette into the traN gene on an F plasmid derivative, pOX38, to produce pOX38N1::CAT. pOX38N1::CAT was greatly reduced in its ability to transfer DNA, indicating that TraN plays a greater role in conjugation than previously thought. F and R100-1 traN were capable of complementing pOX38N1::CAT transfer equally well when wild-type recipients were used. F traN, but not R100-1 traN, supported a much lower level of transfer when there was an ompA mutation or lipopolysaccharide (LPS) deficiency in the recipient cell, suggesting receptor specificity. The R100-1 traN gene was sequenced, and the gene product was found to exhibit 82.3% overall similarity with F TraN. The differences were mainly located within a central region of the proteins (amino acids 162 to 333 of F and 162 to 348 of R100-1). Deletion analysis of F traN suggested that this central portion might be responsible for the receptor specificity displayed by TraN. TraN was not responsible for TraT-dependent surface exclusion. Thus, TraN, and not the F pilus, appears to interact with OmpA and LPS moieties during conjugation, resulting in mating pair stabilization, the first step in efficient mobilization of DNA.     

Characterization of the F plasmid bifunctional conjugation gene, traG.

Summary The Escherichia coli F plasmid gene, traG, is required for two stages of the conjugation process: pilus biosynthesis and mating aggregate stabilization. The nucleotide sequence of traG has been determined and the topology of its product in the cytoplasmic membrane analysed using protease accessibility experiments. Complementation analysis employing plasmid deletions revealed a correlation between an N-terminal periplasmic segment of the protein product (TraGp) and its pilus assembly activity. Production of an anti-TraGp antiserum has facilitated the detection of TraGp^*, a possible internal cleavage product of TraGp. Although its function is unknown, TraGp^* is located in the periplasm and has been shown to possess sequences required for aggregate stabilization. The detection of TraGp^*raises the possibility that the two functions of traG are carried out by separate products.     

Characterization of R-plasmids in environmental isolates ofsalmonella: Host range and stability

Four environmental isolates ofSalmonella, resistant to several drugs, were examined for plasmid carriage with four different plasmid DNA isolation procedures. The method of Birnboim and Doly gave the best results. Three of the strains possessed a single plasmid with molecular weights of 60 (kanamycin resistant), 44.5 (kanamcin resistant), and 23.4 Md (ampicillin and amoxicillin resistant); the other strain (resistant to tetracycline) harbored two plasmids of 69.8 and 2.2 Md. The 69.8 Md was the one responsible for resistance. All plasmids were fi^–, and the 44.5 Md Kc^r plasmid synthesized a sex pilus type F. Some properties related to the dissemination of R-plasmids, such as host range, transfer frequencies, and in vitro stability, were studied. Plasmids generally showed a wide host range and high stability in the transconjugants tested. It could be concluded that these plasmids may be widely disseminated in the environment studied.     

The differential affinity of the usher for chaperone–subunit complexes is required for assembly of complete pili

Attachment to host cells via adhesive surface structures is a prerequisite for the pathogenesis of many bacteria. Uropathogenic Escherichia coli assemble P and type 1 pili for attachment to the host urothelium. Assembly of these pili requires the conserved chaperone/usher pathway, in which a periplasmic chaperone controls the folding of pilus subunits and an outer membrane usher provides a platform for pilus assembly and secretion. The usher has differential affinity for pilus subunits, with highest affinity for the tip‐localized adhesin. Here, we identify residues F21 and R652 of the P pilus usher PapC as functioning in the differential affinity of the usher. R652 is important for high‐affinity binding to the adhesin whereas F21 is important for limiting affinity for the PapA major rod subunit. PapC mutants in these residues are specifically defective for pilus assembly in the presence of PapA, demonstrating that differential affinity of the usher is required for assembly of complete pili. Analysis of PapG deletion mutants demonstrated that the adhesin is not required to initiate P pilus biogenesis. Thus, the differential affinity of the usher may be critical to ensure assembly of functional pilus fibres.     

Genetic evidence of a coupling role for the TraG protein family in bacterial conjugation

The ability of conjugative plasmids from six different incompatibility groups to mobilize a set of mobilizable plasmids was examined. The mobilization frequencies of plasmids RSF1010, ColE1, ColE3, and CloDF13 varied over seven orders of magnitude, depending on the helper conjugative plasmid used. Mobilization of CloDF13 was unique in that it did not require TrwB, TraG or TraD (all members of the TraG family) for mobilization by R388, RP4 or F, respectively. CloDF13 itself codes for an essential mobilization protein (MobB) which is also a TraG homolog, only requiring a source of the genes for pilus formation. Besides, CloDF13 was mobilized efficiently by all conjugative plasmids, suggesting that TraG homologs are the primary determinants of the mobilization efficiency of a plasmid, interacting differentialy with the various relaxosomes. Previous results indicated that TraG and TrwB were interchangeable for mobilization of RSF1010 and ColE1 by PIL_W (the pilus system of IncW plasmids) but TraG could not complement conjugation of trwB mutants, suggesting that additional interactions were taking place between TrwB and oriT(R388) that were not essential for mobilization. To further test this hypothesis, we analyzed the mobilization frequencies of ColE1 and RSF1010 by the P, W, and F pili in the presence of alternative TraG homologs. The results obtained indicated that the frequency of mobilization was determined both by the particular TraG-like protein used and by the pilus system. Thus, TraG-like proteins are not generally interchangeable for mobilization. Therefore we suggest that the factors that determine the frequencies of transfer of different MOB regions are the differential interactions of TrwB with pilus and relaxosome. Received: 9 September 1996 / Accepted: 17 December 1996     

Proton Magnetic Resonance Studies of Conformational Changes in Cleaved Halves of Histone F2B

THE amino-acid sequences of the histones F2A1¹ and F2B² are of particular interest in that they have such a high degree of non-uniformity that different regions of the polypeptide chains have quite different characters. The amino-halves of the molecules have a high density of basic residues while the carboxyl-halves have far fewer basic residues and higher proportions of apolar residues and other residues which favour the formation of helical conformations. These properties have led to the suggestions that the regions of high basicity are the primary sites for interaction with DNA^1–4 in chromatin and that the non-basic regions contain any secondary structure that the molecule is capable of forming^1–4 and are the sites for histone–histone interactions^3,4. Evidence in support of this scheme has been obtained from nuclear magnetic resonance and optical spectroscopic studies of conformational changes and interactions in histones F1 and F2A1³ and F2B⁴. In these studies, however, the whole molecule has been examined and the possibility of the formation of some secondary structure in the basic region of the molecule cannot be excluded.     

Comparison of Proteins Involved in Pilus Synthesis and Mating Pair Stabilization from the Related Plasmids F and R100-1: Insights into the Mechanism of Conjugation

F and R100-1 are closely related, derepressed, conjugative plasmids from the IncFI and IncFII incompatibility groups, respectively. Heteroduplex mapping and genetic analyses have revealed that the transfer regions are extremely similar between the two plasmids. Plasmid specificity can occur at the level of relaxosome formation, regulation, and surface exclusion between the two transfer systems. There are also differences in pilus serology, pilus-specific phage sensitivity, and requirements for OmpA and lipopolysaccharide components in the recipient cell. These phenotypic differences were exploited in this study to yield new information about the mechanism of pilus synthesis, mating pair stabilization, and surface and/or entry exclusion, which are collectively involved in mating pair formation (Mpf). The sequence of the remainder of the transfer region of R100-1 (trbA to traS) has been completed, and the complete sequence is compared to that of F. The differences between the two transfer regions include insertions and deletions, gene duplications, and mosaicism within genes, although the genes essential for Mpf are conserved in both plasmids. F+ cells carrying defined mutations in each of the Mpf genes were complemented with the homologous genes from R100-1. Our results indicate that the specificity in recipient cell recognition and entry exclusion are mediated by TraN and TraG, respectively, and not by the pilus.     

The F pilus mediates a novel pathway of CDI toxin import

Contact‐dependent growth inhibition (CDI) is a widespread form of inter‐bacterial competition that requires direct cell‐to‐cell contact. CDI⁺ inhibitor cells express CdiA effector proteins on their surface. CdiA binds to specific receptors on susceptible target bacteria and delivers a toxin derived from its C‐terminal region (CdiA‐CT). Here, we show that purified CdiA‐CT⁵³⁶ toxin from uropathogenic Escherichia coli 536 translocates into bacteria, thereby by‐passing the requirement for cell‐to‐cell contact during toxin delivery. Genetic analyses demonstrate that the N‐terminal domain of CdiA‐CT⁵³⁶ is necessary and sufficient for toxin import. The CdiA receptor plays no role in this import pathway; nor do the Tol and Ton systems, which are exploited to internalize colicin toxins. Instead, CdiA‐CT⁵³⁶ import requires conjugative F pili. We provide evidence that the N‐terminal domain of CdiA‐CT⁵³⁶ interacts with F pilin, and that pilus retraction is critical for toxin import. This pathway is reminiscent of the strategy used by small RNA leviviruses to infect F⁺ cells. We propose that CdiA‐CT⁵³⁶ mimics the pilin‐binding maturation proteins of leviviruses, allowing the toxin to bind F pili and become internalized during pilus retraction.     

Development of a powder formulation based on <Emphasis Type="Italic">Bacillus</Emphasis><Emphasis Type="Italic">cereus</Emphasis> sensu lato strain B25 spores for biological control of <Emphasis Type="Italic">Fusarium verticillioides</Emphasis> in maize plants

Maize is an economically important crop in northern Mexico. Different fungi cause ear and root rot in maize, including Fusarium verticillioides (Sacc.) Nirenberg. Crop management of this pathogen with chemical fungicides has been difficult. By contrast, the recent use of novel biocontrol strategies, such as seed bacterization with Bacillus cereus sensu lato strain B25, has been effective in field trials. These approaches are not without their problems, since insufficient formulation technology, between other factors, can limit success of biocontrol agents. In response to these drawbacks, we have developed a powder formulation based on Bacillus B25 spores and evaluated some of its characteristics, including shelf life and efficacy against F. verticillioides, in vitro and in maize plants. A talc-based powder formulation containing 1 × 10⁹ c.f.u. g^?1 was obtained and evaluated for seed adherence ability, seed germination effect, shelf life and antagonism against F. verticillioides in in vitro and in planta assays. Seed adherence of viable bacterial spores ranged from 1.0 to 1.41 × 10⁷ c.f.u. g^?1. Bacteria did not display negative effects on seed germination. Spore viability for the powder formulation slowly decreased over time, and was 53 % after 360 days of storage at room temperature. This formulation was capable of controlling F. verticillioides in greenhouse assays, as well as eight other maize phytopathogenic fungi in vitro. The results suggest that a talc-based powder formulation of Bacillus B25 spores may be sufficient to produce inoculum for biocontrol of maize ear and root rots caused by F. verticillioides.     

PilP, a pilus biogenesis lipoprotein in Neisseria gonorrhoeae, affects expression of PilQ as a high-molecular-mass multimer

Studies of gonococcal pilus biogenesis are fundamental to understanding organelle structure/function relationships and identifying new approaches to controlling disease. This area of research is also relevant to elucidating the basic mechanisms of outer membrane translocation of macromolecules, which requires components highly related to those involved in type IV pilus expression. Previous studies have shown that products of several ancillary pil genes are required for organelle biogenesis but of these only PilQ, a member of the GspD protein family, is a component of the outer membrane. DNA sequencing of the region upstream of pilQ revealed the presence of two open reading frames (ORFs) whose deduced polypeptides shared significant identities with proteins required for pilus expression in Pseudomonas aeruginosa and Pseudomonas syringae, the genes for which are arrayed upstream of a gene encoding a PilQ homologue. Gonococcal mutants bearing transposon insertions in these ORFs were non-piliated and failed to express pilus-associated phenotypes, and the corresponding genes were designated pilO and pilP. The piliation defects in the mutants could not be ascribed to polarity on distal pilQ expression as shown by direct measurement of PilQ antigen in those backgrounds and the use of a novel technique to create tandem duplications in the gonococcus (Gc) genome. As predicted by the presence of a consensus lipoprotein signal sequence, PilP expressed in both Escherichia coli and Gc could be labelled with [³H]-palmitic acid. PilP^? as well as PilQ^? mutants shed PilC, a protein which facilitates pilus assembly and is implicated in epithelial cell adherence, in a soluble form. Combined with the finding that levels of multimerized PilQ were greatly reduced in PilP^? mutants, the results suggest that PilP is required for PilQ function and that PilQ and PilC may interact during the terminal stages of pilus biogenesis. The findings also support the hypothesis that the Gc PilQ multimer corresponds to a physiologically relevant form of the protein required for pilus biogenesis.     

Construction in Escherichia coli K12 of derivatives of sex factor F143 carrying lexB and recA mutations

Summary Various F sex factors have been derived from F143, an episome extending from lysA to pheA. F143 derivatives carrying recA and lexB alleles and also mutations in genes thyA, argA, cysC were constructed as follows. Recombination was used as a means to generate genetically labelled F-primes. Using trimethoprim as agent of counterselection of Thy⁺ cells in thyA ^–/F-thyA ⁺bacteria, it was possible to collect, after transfer, F-primes modified by deletion of the thyA region or recombination between chromosome and episome. F-primes which had spontaneously recombined with the chromosome and integrated chromosomal markers, were also selected by transfer to proper F^– recipients. P1 transduction of a dominant marker allele into a strain homodiploid for a recessive allele was used to construct F-primes carrying mutations introduced by cotransduction. These F-primes have been useful to establish the dominance and complementation pattern of recA and lexB mutations (Morand, Goze and Devoret, accompanying paper; Glickman, Guijt and Morand, accompanying paper).     

Characterization of the F-plasmid conjugative transfer gene traU.

We characterized the traU gene of the Escherichia coli K-12 conjugative plasmid F. Plasmids carrying segments of the F transfer operon were tested for their capacity to complement F lac traU526. The protein products of TraU+ clones were identified, and the nucleotide sequence of traU was determined. traU mapped between traW and trbC. It encodes a 330-amino-acid, Mr36,786 polypeptide that is processed. Ethanol caused accumulation of a precursor polypeptide; removal of ethanol permitted processing of the protein to occur. Because F lac traU526 strains appear to be resistant to F-pilus-specific phages, traU has been considered an F-pilus assembly gene. However, electron microscopic analysis indicated that the traU526 amber mutation caused only a 50% reduction in F-piliation. Since F lac traU526 strains also retain considerable transfer proficiency, new traU mutations were constructed by replacing a segment of traU with a kanamycin resistance gene. Introduction of these mutations into a transfer-proficient plasmid caused a drastic reduction in transfer proficiency, but pilus filaments remained visible at approximately 20% of the wild-type frequency. Like traU526 strains, such mutants were unable to plaque F-pilus-specific phages but exhibited a slight sensitivity on spot tests. Complementation with a TraU+ plasmid restored the wild-type transfer and phage sensitivity phenotypes. Thus, an intact traU product appears to be more essential to conjugal DNA transfer than to assembly of pilus filaments.