A NEW TYPE OF BACTERIAL PILUS GENETICALLY CONTROLLED BY THE FERTILITY FACTOR OF E. COLI K 12 AND ITS ROLE IN CHROMOSOME TRANSFER

The F pilus serves as a conduit for the DNA during conjugation between physically distant bacteria

Horizontal transfer of F-like plasmids by bacterial conjugation is responsible for disseminating antibiotic resistance and virulence determinants among pathogenic Enterobacteriaceae species, a growing health concern worldwide. Central to this process is the conjugative F pilus, a long extracellular filamentous polymer that extends from the surface of plasmid donor cells, allowing it to probe the environment and make contact with the recipient cell. It is well established that the F pilus can retract to bring mating pair cells in tight contact before DNA transfer. However, whether DNA transfer can occur through the extended pilus has been a subject of active debate. In this study, we use live-cell microscopy to show that while most transfer events occur between cells in direct contact, the F pilus can indeed serve as a conduit for the DNA during transfer between physically distant cells. Our findings enable us to propose a unique model for conjugation that revises our understanding of the DNA transfer mechanism and the dissemination of drug resistance and virulence genes within complex bacterial communities.

ssRNA phage penetration triggers detachment of the F-pilus

Although the F-specific ssRNA phage MS2 has long had paradigm status, little is known about penetration of the genomic RNA (gRNA) into the cell. The phage initially binds to the F-pilus using its maturation protein (Mat), and then the Mat-bound gRNA is released from the viral capsid and somehow crosses the bacterial envelope into the cytoplasm. To address the mechanics of this process, we fluorescently labeled the ssRNA phage MS2 to track F-pilus dynamics during infection. We discovered that ssRNA phage infection triggers the release of F-pili from host cells, and that higher multiplicity of infection (MOI) correlates with detachment of longer F-pili. We also report that entry of gRNA into the host cytoplasm requires the F-plasmid-encoded coupling protein, TraD, which is located at the cytoplasmic entrance of the F-encoded type IV secretion system (T4SS). However, TraD is not essential for pilus detachment, indicating that detachment is triggered by an early step of MS2 engagement with the F-pilus or T4SS. We propose a multistep model in which the ssRNA phage binds to the F-pilus and through pilus retraction engages with the distal end of the T4SS channel at the cell surface. Continued pilus retraction pulls the Mat-gRNA complex out of the virion into the T4SS channel, causing a torsional stress that breaks the mature F-pilus at the cell surface. We propose that phage-induced disruptions of F-pilus dynamics provides a selective advantage for infecting phages and thus may be prevalent among the phages specific for retractile pili.

Gold-Decorated M13 I-Forms and S-Forms for Targeted Photothermal Lysis of Bacteria

With the emergence of multidrug-resistant bacteria, photothermal therapy has been proposed as an alternative to antibiotics for targeting and killing pathogens. In this study, two M13 bacteriophage polymorphs were studied as nanoscaffolds for plasmonic bactericidal agents. Receptor-binding proteins found on the pIII minor coat protein targeted Escherichia coli bacteria with F-pili (F⁺ strain), while a gold-binding peptide motif displayed on the pVIII major coat protein templated Au nanoparticles. Temperature-dependent exposure to a chloroform-water interface transformed the native filamentous phage into either rod-like or spheroid structures. The morphology, geometry, and size of the polymorphs, as well as the receptor-binding protein and host cell receptor interaction were studied using electron microscopy. Au/template structures were formed through incubation with Au colloid, and optical absorbance was measured. Despite the closely packed Au nanoparticle layer on the surface the viral scaffolds, electron microscopy confirmed that host receptor affinity was retained. Photothermal bactericidal studies were performed using 532 nm laser irradiation with a variety of powers and exposure times. Bacterial viability was assessed using colony count. With the shape-modified M13 scaffolds, up to 64% of E. coli were killed within 20 min. These studies demonstrate the promise of i-form and s-form polymorphs for the directed plasmonic-based photothermal killing of bacteria.

Bacteriophage MS2 displays unreported capsid variability assembling T = 4 and mixed capsids

Bacteriophage MS2 is a positive-sense, single-stranded RNA virus encapsulated in an asymmetric T = 3 pseudo-icosahedral capsid. It infects Escherichia coli through the F-pilus, in which it binds through a maturation protein incorporated into its capsid. Cryogenic electron microscopy has previously shown that its genome is highly ordered within virions, and that it regulates the assembly process of the capsid. In this study, we have assembled recombinant MS2 capsids with non-genomic RNA containing the capsid incorporation sequence, and investigated the structures formed, revealing that T = 3, T = 4 and mixed capsids between these two triangulation numbers are generated, and resolving structures of T = 3 and T = 4 capsids to 4 Å and 6 Å respectively. We conclude that the basic MS2 capsid can form a mix of T = 3 and T = 4 structures, supporting a role for the ordered genome in favouring the formation of functional T = 3 virions.

Mutation in ESBL Plasmid from Escherichia coli O104:H4 Leads Autoagglutination and Enhanced Plasmid Dissemination

Conjugative plasmids are one of the main driving force of wide-spreading of multidrug resistance (MDR) bacteria. They are self-transmittable via conjugation as carrying the required set of genes and cis-acting DNA locus for direct cell-to-cell transfer. IncI incompatibility plasmids are nowadays often associated with extended-spectrum beta-lactamases producing Enterobacteria in clinic and environment. pESBL-EA11 was isolated from Escherichia coli O104:H4 outbreak strain in Germany in 2011. During the previous study identifying transfer genes of pESBL-EA11, it was shown that transposon insertion at certain DNA region of the plasmid, referred to as Hft, resulted in great enhancement of transfer ability. This suggested that genetic modifications can enhance dissemination of MDR plasmids. Such ‘superspreader’ mutations have attracted little attention so far despite their high potential to worsen MDR spreading. Present study aimed to gain our understanding on regulatory elements that involved pESBL transfer. While previous studies of IncI plasmids indicated that immediate downstream gene of Hft, traA, is not essential for conjugative transfer, here we showed that overexpression of TraA in host cell elevated transfer rate of pESBL-EA11. Transposon insertion or certain nucleotide substitutions in Hft led strong TraA overexpression which resulted in activation of essential regulator TraB and likely overexpression of conjugative pili. Atmospheric Scanning Electron Microscopy observation suggested that IncI pili are distinct from other types of conjugative pili (such as long filamentous F-type pili) and rather expressed throughout the cell surface. High transfer efficiency in the mutant pESBL-EA11 was involved with hyperpiliation which facilitates cell-to-cell adhesion, including autoagglutination. The capability of plasmids to evolve to highly transmissible mutant is alarming, particularly it might also have adverse effect on host pathogenicity.

Natural and Artificial Strategies To Control the Conjugative Transmission of Plasmids

Conjugative plasmids are the main carriers of transmissible antibiotic resistance (AbR) genes. For that reason, strategies to control plasmid transmission have been proposed as potential solutions to prevent AbR dissemination. Natural mechanisms that bacteria employ as defense barriers against invading genomes, such as restriction-modification or CRISPR-Cas systems, could be exploited to control conjugation. Besides, conjugative plasmids themselves display mechanisms to minimize their associated burden or to compete with related or unrelated plasmids. Thus, FinOP systems, composed of FinO repressor protein and FinP antisense RNA, aid plasmids to regulate their own transfer; exclusion systems avoid conjugative transfer of related plasmids to the same recipient bacteria; and fertility inhibition systems block transmission of unrelated plasmids from the same donor cell. Artificial strategies have also been designed to control bacterial conjugation. For instance, intrabodies against R388 relaxase expressed in recipient cells inhibit plasmid R388 conjugative transfer; pIII protein of bacteriophage M13 inhibits plasmid F transmission by obstructing conjugative pili; and unsaturated fatty acids prevent transfer of clinically relevant plasmids in different hosts, promoting plasmid extinction in bacterial populations. Overall, a number of exogenous and endogenous factors have an effect on the sophisticated process of bacterial conjugation. This review puts them together in an effort to offer a wide picture and inform research to control plasmid transmission, focusing on Gram-negative bacteria.

Comparative Genomics of the Conjugation Region of F-like Plasmids: Five Shades of F

The F plasmid is the foremost representative of a large group of conjugative plasmids, prevalent in Escherichia coli, and widely distributed among the Enterobacteriaceae. These plasmids are of clinical relevance, given their frequent association with virulence determinants, colicins, and antibiotic resistance genes. Originally defined by their sensitivity to certain male-specific phages, IncF plasmids share a conserved conjugative system and regulatory circuits. In order to determine whether the genetic architecture and regulation circuits are preserved among these plasmids, we analyzed the natural diversity of F-like plasmids. Using the relaxase as a phylogenetic marker, we identified 256 plasmids belonging to the IncF/ MOB_F12group, present as complete DNA sequences in the NCBI database. By comparative genomics, we identified five major groups of F-like plasmids. Each shows a particular operon structure and alternate regulatory systems. Results show that the IncF/MOB_F12 conjugation gene cluster conforms a diverse and ancient group, which evolved alternative regulatory schemes in its adaptation to different environments and bacterial hosts.

Fimbriae: Classification and Biochemistry

Proteinaceous, nonflagellar surface appendages constitute a variety of structures, including those known variably as fimbriae or pili. Constructed by distinct assembly pathways resulting in diverse morphologies, fimbriae have been described to mediate functions including adhesion, motility, and DNA transfer. As these structures can represent major diversifying elements among Escherichia and Salmonella isolates, multiple fimbrial classification schemes have been proposed and a number of mechanistic insights into fimbrial assembly and function have been made. Herein we describe the classifications and biochemistry of fimbriae assembled by the chaperone/usher, curli, and type IV pathways.

The asymmetric structure of an icosahedral virus bound to its receptor suggests a mechanism for genome release

Simple, spherical RNA viruses have well-understood, symmetric protein capsids, but little structural information is available for their asymmetric components, such as minor proteins and their genomes, which are vital for infection. Here, we report an asymmetric structure of bacteriophage MS2, attached to its receptor, the F-pilus. Cryo-electron tomography and subtomographic averaging of such complexes result in a structure containing clear density for the packaged genome, implying that the conformation of the genome is the same in each virus particle. The data also suggest that the single-copy viral maturation protein breaks the symmetry of the capsid, occupying a position that would be filled by a coat protein dimer in an icosahedral shell. This capsomere can thus fulfill its known biological roles in receptor and genome binding and suggests an exit route for the genome during infection.

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The asymmetric structure of a virus receptor complex is described

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The density for ordered genomic RNA was observed in the structure

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Viral maturation protein was visualized

Positively charged nanogold label allows the observation of fine cell filopodia and flagella in solution by atmospheric scanning electron microscopy

Optical microscopy is generally the first choice to observe microbes and cells. However, its resolution is not always sufficient to reveal specific target structures, such as flagella and pili, which are only nanometers wide. ASEM is an attractive higher resolution alternative, as the sample is observed in aqueous solution at atmospheric pressure. Sample pretreatment for ASEM only comprises simple tasks including fixation, gold labeling, and reagent exchange, taking less than 1 h in total. The lengthy sample pretreatments often required for more classical electron microscopies, such as embedding and dehydration, are unnecessary, and native morphology is preserved. In this study, positively charged nanogold particles were used to label the surfaces of bacteria and cultured animal cells, exploiting their net negative surface charge. After gold enhancement to increase the size of the nanogold particles, ASEM imaging of the bacteria in aqueous solution revealed pili and delicate spiral flagella. This natural shape contrasts starkly with images of dried flagella recorded by standard SEM. Positively charged nanogold labeled the plasma membrane of cultured COS7 cells, and after enhancement allowed filopodia as thin as 100 nm in diameter to be clearly visualized. Based on these studies, ASEM combined with positively charged nanogold labeling promises to become an important tool for the study of cell morphology and dynamics in the near future.

A new paradigm for the roles of the genome in ssRNA viruses

Recent work with RNA phages and an ssRNA plant satellite virus challenges the widely held view that the sequences and structures of genomic RNAs are unimportant for virion assembly. In the T=3 phages, RNA–coat protein interactions occur throughout the genome, defining the quasiconformers of their protein shells. In the plant virus, there are multiple packaging signals dispersed throughout the genome that overcome electrostatic barriers to protein self-assembly. Both viral coat proteins cause the solution structures of their cognate genomes to collapse into a form that is readily encapsidated in a two-stage assembly process. Such similar behavior in two structurally unrelated viral protein folds implies that this might be a conserved feature of many viral assembly reactions. These results suggest a highly defined structure for the RNA in the virions, consistent with recent structural studies. They also have implications both for subsequent genome release during infection and for the evolution of viral sequences.

Crystal structure of the read-through domain from bacteriophage Qβ A1 protein

Bacteriophage Qβ is a small RNA virus that infects Escherichia coli. The virus particle contains a few copies of the minor coat protein A1, a C-terminally prolonged version of the coat protein, which is formed when ribosomes occasionally read-through the leaky stop codon of the coat protein. The crystal structure of the read-through domain from bacteriophage Qβ A1 protein was determined at a resolution of 1.8 Å. The domain consists of a heavily deformed five-stranded β-barrel on one side of the protein and a β-hairpin and a three-stranded β-sheet on the other. Several short helices and well-ordered loops are also present throughout the protein. The N-terminal part of the read-through domain contains a prominent polyproline type II helix. The overall fold of the domain is not similar to any published structure in the Protein Data Bank.

Visualising a viral RNA genome poised for release from its receptor complex

We describe the cryo-electron microscopy structure of bacteriophage MS2 bound to its receptor, the bacterial F-pilus. The virus contacts the pilus at a capsid 5-fold vertex, thus locating the surface-accessible portion of the single copy of the pilin-binding maturation protein present in virions. This arrangement allows a 5-fold averaged map to be calculated, showing for the first time in any virus-receptor complex the nonuniform distribution of RNA within the capsid. Strikingly, at the vertex that contacts the pilus, a rod of density that may include contributions from both genome and maturation protein sits above a channel that goes through the capsid to the outside. This density is reminiscent of the DNA density observed in the exit channel of double-stranded DNA phages, suggesting that the RNA-maturation protein complex is poised to leave the capsid as the first step of the infection process.

Mutually-induced conformational switching of RNA and coat protein underpins efficient assembly of a viral capsid

Single-stranded RNA viruses package their genomes into capsids enclosing fixed volumes. We assayed the ability of bacteriophage MS2 coat protein to package large, defined fragments of its genomic, single-stranded RNA. We show that the efficiency of packaging into a T=3 capsid in vitro is inversely proportional to RNA length, implying that there is a free-energy barrier to be overcome during assembly. All the RNAs examined have greater solution persistence lengths than the internal diameter of the capsid into which they become packaged, suggesting that protein-mediated RNA compaction must occur during assembly. Binding ethidium bromide to one of these RNA fragments, which would be expected to reduce its flexibility, severely inhibited packaging, consistent with this idea. Cryo-EM structures of the capsids assembled in these experiments with the sub-genomic RNAs show a layer of RNA density beneath the coat protein shell but lack density for the inner RNA shell seen in the wild-type virion. The inner layer is restored when full-length virion RNA is used in the assembly reaction, implying that it becomes ordered only when the capsid is filled, presumably because of the effects of steric and/or electrostatic repulsions. The cryo-EM results explain the length dependence of packaging. In addition, they show that for the sub-genomic fragments the strongest ordered RNA density occurs below the coat protein dimers forming the icosahedral 5-fold axes of the capsid. There is little such density beneath the proteins at the 2-fold axes, consistent with our model in which coat protein dimers binding to RNA stem-loops located at sites throughout the genome leads to switching of their preferred conformations, thus regulating the placement of the quasi-conformers needed to build the T=3 capsid. The data are consistent with mutual chaperoning of both RNA and coat protein conformations, partially explaining the ability of such viruses to assemble so rapidly and accurately.

Episome-mediated Transfer of Drug Resistance in Enterobacteriaceae X. Restriction and Modification of Phages by fi R Factors

Watanabe, Tsutomu (Keio University, Tokyo, Japan), Toshiya Takano, Toshihiko Arai, Hiroshi Nishida, and Sachiko Sato. Episome-mediated transfer of drug resistance in Enterobacteriaceae. X. Restriction and modification of phages by fi(-) R factors. J. Bacteriol. 92:477-486. 1966.-An fi(-) R factor, which restricts phages lambda, T1, and T7 without modifying them, was found to restrict and not to modify an F(-)-specific phage, W-31, in Escherichia coli K-12, but not to restrict phage P-22 in Salmonella typhimurium LT-2, whereas other fi(-) R factors restricted and modified P-22 but not W-31; fi(+) R factors did not restrict these phages. Transduction and lysogenization with phages lambda and P-22 were reduced by these fi(-) R factors in K-12 and LT-2, respectively, and the transducing phages lambda and P-22 were modified by these fi(-) R factors. Spontaneous as well as ultraviolet-induced production of phage P-22 and zygotic induction of phage lambda were not significantly affected by any R factor. Injection of the nucleic acids of phages T1 and lambda was not affected by R factors, but the injected phage nucleic acids were rapidly broken down in the bacteria carrying fi(-) R factors. The nucleic acids of the modified phages were not broken down in these bacteria. It was assumed from these results that the mechanism of restriction of phages by fi(-) R factors is due to the breakdown of the injected phage nucleic acids by a deoxyribonuclease(s), presumably located near the cell surface in the cells carrying fi(-) R factors. The deoxyribonuclease(s), formed in the cells carrying the nonmodifying fi(-) R factor, is considered to be different from that synthesized in the cells carrying the modifying fi(-) R factors. It was further shown that the average burst sizes of the unmodified as well as modified phages are slightly reduced by the presence of the fi(-) R factors.

Surface rigidity change of Escherichia coli after filamentous bacteriophage infection

In this study, the feasibility using atomic force microscopy (AFM) to study the interaction between bacteriophages (phages) and bacteria in situ was demonstrated here. Filamentous phage M13 specifically infects the male Escherichia coli, which expresses F-pili. After infection, E. coli become fragile and grows at a slower rate. AFM provides a powerful tool for investigating these changes in a near-physiological environment. Using high-resolution AFM in phosphate-buffered saline, the damage to the lipopolysaccharide (LPS) layer on the outer membrane of the M13 phage-infected E. coli was observed. The membrane became smoother and more featureless compared to those that were not infected. Besides, the force-distance (f-d) curves were measured to reveal the surface rigidity change in E. coli after M13 phage infection. The effective spring constant and Young's modulus of E. coli decreased after M13 phage infection. Furthermore, the AFM tip was pressed against E. coli to study the response of E. coli under load before and after M13 phage infection. The results showed that after infection E. coli became less rigid and the membrane was also damaged. However, the stiffness changes, including the spring constant and Young's modulus of E. coli, are negligible after M13 phage infection compared with those in previous reports, which may be one of the reasons that E. coli still can maintain its viability after filamentous phage infection.

A study of pili onPseudomonas aeruginosa

Pseudomonas aeruginosacarries polar pili which act as receptors for RNA-containing bacteriophages. In order to confirm, that these pili were not involved in the transfer of the sex factor FP 2, eleven bacterial strains, both FP 2+and FP 2−, were examined in the electron microscope for the presence of pili and tested for sensitivity to the RNA phage PP7. Pili were found on all strains save one which was resistant to phage PP7. It was also found by electron microscopy that about 25 times more pili per cell were present after PP7 adsorption than before it. This result is discussed with reference to the pilus retraction theory, providing further evidence that some kinds of pili retract instead of acting as simple tubes for the transfer of genetic material. The strong supporting evidence provided by the infective processes of male-specific coliphages is discussed and compared to current knowledge ofP. aeruginosaRNA phages.

It was also found that pili were present on the host strain for theP. aeruginosafilamentous phage Pf. Although similar in appearance to RNA phage pili, these differed in that they did not adsorb phage PP7. However, it seemed likely that they were receptors for Pf. A structural comparison is made betweenP. aeruginosapili andEscherichia coliF-pili. It is possible thatP. aeruginosapili could be coded for by a plasmid other than FP 2.

Role of the Hrp pilus in type III protein secretion in Pseudomonas syringae

Bacterial surface appendages called pili and needle-like filaments are associated with protein and/or DNA transfer to recipient plant, human, or bacterial cells during pathogenesis or conjugation. Although it has long been suspected that pili function as a conduit for protein or DNA transfer, direct evidence has been lacking. The Hrp pilus of Pseudomonas syringae is assembled by the type III secretion system. We used an in situ immunogold labeling procedure to visualize the extrusion of an effector protein, AvrPto, from the tip of the Hrp pilus, providing direct evidence that a bacterial pilus can function as a conduit for protein delivery.

CHARACTERIZATION OF CONJUGATION FACTORS IN ESCHERICHIA COLI CELL WALLS. I. INHIBITION OF RECOMBINATION BY CELL WALLS AND CELL EXTRACTS

Lancaster, John H. (University of Texas, Austin), E. P. Goldschmidt, and Orville Wyss. Characterization of conjugation factors in Escherichia coli cell walls. I. Inhibition of recombination by cell walls and cell extracts. J. Bacteriol. 89:1478-1481. 1965.-An assay procedure was devised to determine quantitatively the interference with conjugation of cell-wall fragments from both male and female strains of Escherichia coli. The fertility of the donor is reflected in the assay. Phenol extracts from the cell walls were active, and chemical analysis suggested that the activity resided in the lipopolysaccharide fraction.

GROWTH OF MALE-SPECIFIC BACTERIOPHAGE IN PROTEUS MIRABILIS HARBORING F-GENOTES DERIVED FROM ESCHERICHIA COLI

Horiuchi, Kensuke (Yale University, New Haven, Conn.), and Edward A. Adelberg. Growth of male-specific bacteriophage in Proteus mirabilis harboring F-genotes derived from Escherichia coli. J. Bacteriol. 89:1231-1236. 1965.-Male-specific bacteriophage MS2 was shown to infect and grow in Proteus mirabilis strains which harbor F-genotes derived from Escherichia coli K-12. The burst size was 2,000 to 3,000, which is similar to that in E. coli K-12, whereas the latent period was 45 min, definitely longer than that in E. coli. In spite of the multiplication of MS2 in male P. mirabilis in broth, P. mirabilis strains failed to show plaque formation by MS2 on agar plates; this failure may be related to the low efficiency of phage adsorption. No host-controlled modification of MS2 by P. mirabilis was detected.

Purification of the Escherichia coli type 1 pilin and minor pilus proteins and partial characterization of the adhesin protein

Type 1 pili of Escherichia coli contain three integral minor proteins with apparent molecular weights (Mr) of 28,000 (28K protein), 16,500, and 14,500 attached to rods composed of Mr-17,000 pilin subunits (Hanson and Brinton, Nature [London] 322:265-268). We describe here an improvement on our earlier method of pilus purification, which gives higher yields and higher purity. Also reported are methods allowing fractionation of intact type 1 pili into rods of pure pilin and free minor proteins, as well as fractionation of the 28K tip adhesion protein from the 16.5K and 14.5K proteins. We have determined the amino acid composition and amino-terminal sequence of the adhesion protein. This sequence shows limited homology with the amino-terminal sequences of several E. coli pilins, including type 1.

DNA transfer occurs during a cell surface contact stage of F sex factor-mediated bacterial conjugation

Donor bacteria containing JCFL39, a temperature-sensitive traD mutant of the F sex factor, were used at the nonpermissive temperature to accumulate stable mating pairs with recipient cells. At this stage in conjugation, extracellular F pili were removed by treatment with 0.01% sodium dodecyl sulfate. Upon then shifting to the permissive temperature for JCFL39, transfer of the F plasmid was observed. The mating pairs that were accumulated with JCFL39 at the nonpermissive temperature were readily observed by electron microscopy in wall-to-wall contact with the recipient bacteria. These results demonstrate that the traD product, which is known to be required in transferring DNA to a recipient bacterium, acts after the stage at which extracellular F pili are required. In addition, we concluded that DNA transfer takes place while donor and recipient cells are in surface contact and not necessarily through an extended F pilus as envisioned in some models of bacterial conjugation.

Conjugation-deficient mutants of Escherichia coli distinguish classes of functions of the outer membrane OmpA protein

Sixty-two E. coli mutants, selected as being deficient as recipients in F factor conjugation, are altered either in the amount or function of the outer membrane OmpA protein or in lipopolysaccharide structure. These two components may function together in conjugation, since the residual conjugation activity of a mutant lacking OmpA protein was unaffected by the additional presence of a lipopolysaccharide defect. Sixty of the strains carried mutations mapping to ompA, and these could be divided into classes depending on the amount of OmpA protein in their membranes. Representatives of these classes of mutant alleles failed to complement in diploids, indicating that they all affect the ompA structural gene and nearby sequences needed for its expression. The properties of these classes distinguish three groups of OmpA protein functions: 1) the structural function in the outer membrane in providing resistance to chelating agents and the hydrophobic antibiotic novobiocin, 2) the receptor functions in phage TuII and K3 infection, and 3) the functions of binding cells together during conjugation, facilitating the uptake of receptor-bound colicin K or L, and allowing phage Ox2 to infect. Different cellular amounts or sites in OmpA protein are thus required for these three groups of functions.

Escherichia coli traD(Ts) mutant temperature sensitive for assembly of RNA bacteriophage MS2

We report here a study on the temperature-sensitive conjugational transfer-deficient mutant Escherichia coli JCFL39, carrying a traD(Ts) mutation, which is also temperature sensitive for group I RNA phages (MS2, f2, and R17). It is shown that, when the mutant was infected with MS2 at 42 degrees C, phage RNA replicated; a 27S MS2 RNA and phage proteins were synthesized. However, neither PFU nor physical MS2 particles were formed, showing that phage assembly was inhibited. In addition, the high temperature affected the membranes of the host mutant: the mutant was hypersensitive to chemicals, and the electrophoretic pattern of the membranal proteins was modified. We suggest that the pleiotropic effects of the traD mutation on MS2 assembly and DNA transfer during conjugation were a result of the changes in the membrane of the mutant.

Kinetic studies of the interaction between MS2 phage and F pilus of Escherichia coli

The kinetics of the binding reaction of MS2 phage to free F pili, which were highly purified from Escherichia coli, has been studied using a membrane filter assay. The rate of dissociation (kd) of the MS2-phage--F-pilus complex is very slow and follows first-order kinetics with a half-life of 4.2 h at 30 degrees C in the standard buffer. The dissociation rate is rather insensitive to temperature, but becomes more rapid at high ionic strength or at basic pH. In a 0.25 M ionic strength buffer, the half-life of the complex is about 1.0 min. The rate of association is very fast and follows second-order kinetics with the rate constant for association (ka) being 8 x 10(7) M-1 s-1 at 30 degrees C in the standard buffer. The rate of association is almost insensitive to ionic strength but slightly sensitive to pH or temperature. Monovalent cations can also promote the binding reaction as well as divalent cations but the complex formed with monovalent cation is unstable. A study of the kinetics of dissociation suggests that there are two types of interaction between MS2 phage and F pilus; one is a strong interaction formed with divalent cations and the other is a weak one formed with monovalent cations. The physical nature of the bonds involved in the former and the latter seems to be mainly electrostatic and non-electrostatic respectively. The mechanism of the binding reaction is discussed.

Cell-cell interactions in conjugating Escherichia coli: role of F pili and fate of mating aggregates

Bacterial conjugation between Escherichia coli cells was investigated by a combination of physical and genetic techniques, using Hfr, F', or R+ donors and F- recipients. DNA transfer occurred in mating aggregates of up to 50 cells. Multiple interactions between donor and recipient cells occurred, and both F- pilus connections and wall-to-wall contacts were detectable. The detectable F- pilus contacts could be destroyed without either disrupting the mating aggregates or preventing DNA transfer. Hfr X F- mating aggregates did not disaggregate even though recombinant frequencies were inversely proportional to the distance from the origin of DNA transfer. F' or R+ donors formed mating aggregates with F- cells which disaggregated soon after transfer of the autonomous sex factor DNA.

Immunization of suckling pigs against enteric enterotoxigenic Escherichia coli infection by vaccinating dams with purified pili

Pregnant swine (gilts) were vaccinated parenterally with a suspension of purified pili from the porcine enterotoxigenic Escherichia coli strain 987 (09:K103::NM). Gilts injected with placebo served as controls. Suckling pigs born to gilts in both groups were challenged intragastrically with virulent strain 987. The percentage of deaths, incidence and duration of diarrhea, numbers of E. coli in the ilea, and E. coli attachment to the villous epithelia were significantly less in suckling pigs of vaccinated gilts than in those of controls. These results are consistent with the hypothesis that pili of some enterotoxigenic E. coli facilitate adhesion to intestinal epithelia. Vaccination of dams with pili appears to be a means of immunizing against diarrheal disease caused by enterotoxigenic E. coli in suckling neonates. This work confirms the role of somatic pili as colonization and virulence factors and provides another example of safe and effective purified pilus vaccines.

Escherichia coli mutant temperature sensitive for group I RNA bacteriophages

The temperature-sensitive conjugational transfer-deficient mutant Escherichia coli JCFL39, carrying a traD(Ts) mutation, is herein described as also being temperature sensitive for group I RNA phages (MS2, f2, and R17) but not for Q beta. Temperature shift experiments showed that the growth of group I phage MS2 in the mutant could be inhibited by a post-penetration event at high temperature. A possible role for the traD cistron of sex factor F in the intracellular development of MS2 is suggested.

Isolation and characterization of Escherichia coli phase variants and mutants deficient in type 1 pilus production

Type 1 pili of Escherichia coli are the prototype of the somatic class of pili found on many strains of bacteria. As a first step in the genetic analysis of type 1 piliation, an extensive series of nonpiliated derivatives of E. coli K-12 strain AW405, was characterized to produce attached or free pili when examined in the antiserum or appeared to produce attached or free pili when examined in the electron microscope. The derivatives fell into two classes; phase variants and mutants. Phase variants that formed colonies of two distinctive types, one associated with a predominantly piliated (P+), and the other associated with a nonpiliated (P-) phase, were obtained. Each phase could give rise to the other at a relatively high rate, which was greater in the P- to P+ direction during culture in unshaken liquid medium. In addition, 77 Pil- mutants were selected on the basis of a subtle difference in colonial morphology. The mutants reverted, if at all, at a much lower rate than that of the P- to P+ change. The stability of Pil- derivatives grown in unshaken liquid medium was used as a criterion for distinguishing between phase variants and mutants, Phase variation also effected colonial morphology and chemotactic swarming. These properties did not directly depend upon piliation since Pil- mutants were only slightly altered in colonial form and unaltered in chemotactic swarming. Piliation of Pil+ bacteria was quantitatively affected by growth conditions.

Effect of entry exclusion on mating aggregates and transconjugants

Mating aggregates during conjugation directed by an F-like R factor in Escherichia coli were measured as the number of Lac+-Lac- sectored colonies present in a mating mixture. There is a high degree of correlation between the concentration of transconjugants produced in a mating mixture and the concentration of mating aggregates observed at several different concentrations of donor and recipient cells. The mating aggregates are sex pilus specific as demonstrated by the ability of donor-specific ribonucleic acid phage MS-2 to decrease both mating aggregates and transconjugants in a mating mixture. During entry exclusion by either a derepressed or a repressed F-like R factor, isogenic to the superinfecting R factor except for a resistance determinant, the number of transconjugants was markedly reduced, but the number of mating aggregates was not decreased. Entry exclusion by F-Gal toward the donor HfrH resembled that of the F-like R factor in that there was a reduction in the number of recombinants but no significant decrease in mating aggregates. These results suggest that entry exclusion inhibits conjugation at a stage after the formation of mating aggregates.

Effect of 1,10-phenanthroline on bacterial conjugation in Escherichia coli K-12: inhibition of maturation from preliminary mates into effective mates

The addition of 1 mM orthophenanthroline (OP) into a mating mixture drastically reduced the production of recombinants. Examination of the effect of OP on each step of conjugation showed that the effect on the following steps could not account for the up to 500-fold reduction of recombinant formation: (i) preliminary mate formation and (ii) deoxyribonucleic acid transfer and integration. Taking these results and additional experiments together, we conclude that OP inhibits the maturation of preliminary mates into effective mates. Kinetic experiments showed that there were two phases in the maturation of preliminary (OP-sensitive) mates into effective (OP-resistant) mates. The half-time (the time required to reach 50% OP-resistant mates) was 2.5 min for the first phase and 4 min for the second phase, with an overall half-time of 7.5 min. In contrast, only 3 min was required to reach 50% Zn2+-resistant mates. The difference in half-time suggests that there is an intermediate step involved to form an effective mate from a preliminary mate.

Effect of thymine-5-bromouracil substitution on F pili

The effect of thymine-5-bromouracil substitution on the regeneration and length of F pili produced by an F(+)Lac(+)/Lac(-)Thy(-) strain of Escherichia coli was studied by electron microscopy. When 5-bromouracil (5BU) incorporation into deoxyribonucleic acid (DNA) was maximal, the modal length of the pilus doubled and the number of pili per cell was approximately 50% that of thymine-grown cells. The ability of 5BU-grown cells to form mating pairs and to be infected by ribonucleic acid (R17) and DNA (M13) male-specific phages was also reduced by approximately 50%. Loss of function was not due to loss of sex factor as 5BU cells retained a sex factor that was susceptible to curing by acridine orange. Elongation of pili on 5BU-grown cells was more sensitive to irradiation at 253.7 nm than on thymine-grown cells, suggesting that DNA is the sensitive target.

Factors influencing the adsorption of bacteriophage 2 to cells of Pseudomonas aeruginosa

Phage 2 adsorbed to Pseudomonas aeruginosa strain BI in 5 mM Tris buffer, providing that cations like Na(+), Mg(2+), or Ca(2+) were present. Adsorption was observed over a broad pH range, reaching a maximum level around pH 7.5, which coincided with the pH required for maximal activity of the phage 2-associated slime polysaccharide depolymerase. Mutants of strain BI and other strains of P. aeruginosa possessing slime layers that were devoid of phage 2 depolymerase substrate were incapable of adsorbing phage 2. On the other hand, those strains containing substrate for the phage 2 depolymerase in the slime layer were capable of adsorbing phage 2. The same relationship of phage depolymerase-substrate interaction to phage adsorption was observed with Pseudomonas phage 8, which possesses a depolymerase that differs in its specificity from the phage 2 depolymerase. The receptor-like activity of purified slime containing the specific substrate for the phage-associated depolymerase was demonstrable by its ability to inactivate phage. However, receptor-like activity or phage inactivation was not observed with those slimes that were devoid of the depolymerase substrate.

Loss of an essential function of Escherichia coli by deletions in the thyA region

In an attempt to obtain deletions in the thyA gene, an abnormal lysogen of lambda having the prophage inserted between the thyA and lysA genes was induced, and the surviving cured cells were examined for Thy(-) and Lys(-) mutants. In nearly 10,000 cured cells, 184 Lys(-) but no Thy(-) mutants were found. At the same time, the induced lambda phage contained an approximately equivalent number of lambdathyA(+) and lambdalysA(+) transducing particles. By contrast, in a strain with the genotype F' thyA(-)lysA(+)/ thyA(+)lysA(+), induction of the abnormal lambda lysogen gave rise to many Thy(-) mutants in the cells cured of the prophage. In these Thy(-) mutants it was not possible to eliminate the episome with acridine orange, although the episome could be removed in control cultures with a thyA(+) allele in the resident gene. Therefore, it was suggested that deletion of a gene in the region of the chromosome from the position of the insertion of the lambda prophage through the thyA gene caused loss of an essential and diffusible function.

Effect of Zn2+ on bacterial conjugation: increase in ability of F- cells to form mating pairs

Incubation of F(-) cells at 37 C with 10(-3) M Zn(2+) before mating was found to increase the ability of F(-) cells to form mating pairs when mated. This increased pair-forming ability is persistent, at least for the duration of mating. The F(-) cells with increased pair-forming ability obtained by the 10(-3) M Zn(2+) treatment can form mating pairs efficiently with males from which F pili were removed or inactivated with 10(-3) M Zn(2+).

Inhibition of formation of Escherichia coli mating pairs by f1 and MS2 bacteriophages as determined with a Coulter counter

The effect of male-specific filamentous deoxyribonucleic acid (f1) and isometric ribonucleic acid (MS2) bacteriophages on the formation of mating pairs in Escherichia coli conjugation was examined directly in the Coulter counter. When a sufficient multiplicity of infection (MOI) was used, the f1 phage immediately and completely inhibited the formation of mating pairs. On the other hand, the MS2 phage at a relatively high MOI also inhibited the formation of mating pairs significantly although not completey. The inhibitory effect of MS2 phage was dependent on the time of addition and the MOI used. At relatively low MOI (<20), the MS2 phage showed some inhibitory effect when added to a male culture prior to mixing with females, whereas no effect was observed when phages were added after mating pair formation had already commenced. At a high MOI (>400) MS2 phage disrupted the mating pairs already formed. Some preformed mating pairs were resistant to the high MOI of MS2 phages, however, and the "sensitive" (to high MOI) mating pairs seem to mature into "resistant" mating pairs as a function of time. We conclude that the tip of an F pilus is the specific attachment site for mating. The following process of mating pair formation has been formulated by deduction. (i) The sides of F pili weakly contact female cells, (ii) then the tips of F pili attach to the specific receptor sites to form initial mating pairs, and (iii) those pairs mature into mating pairs that are resistant to the high MOI of MS2 phages. The high MOI of MS2 prevents the first step, whereas f1 phages affect the second step-the binding between the tips of F pili and the receptor sites.