Structure and Assembly of the Proteus mirabilis Flagellar Motor by Cryo-Electron Tomography

Proteus mirabilis is a Gram-negative Gammaproteobacterium and a major causative agent of urinary tract infections in humans. It is characterized by its ability to switch between swimming motility in liquid media and swarming on solid surfaces. Here, we used cryo-electron tomography and subtomogram averaging to reveal the structure of the flagellar motor of P. mirabilis at nanometer resolution in intact cells. We found that P. mirabilis has a motor that is structurally similar to those of Escherichia coli and Salmonella enterica, lacking the periplasmic elaborations that characterize other more specialized gammaproteobacterial motors. In addition, no density corresponding to stators was present in the subtomogram average suggesting that the stators are dynamic. Finally, several assembly intermediates of the motor were seen that support the inside-out assembly pathway.

Inhibition of development, swarming differentiation and virulence factors in Proteus mirabilis by an extract of Lithrea molleoides and its active principle (Z,Z)-5-(trideca-4',7'-dienyl)-resorcinol

Antibacterial activity of Lithrea molleoides extract against Proteus mirabilis has been previously reported by our group. In the present study, the compound (Z,Z)-5-(trideca-4',7'-dienyl)-resorcinol (1) was isolated as its responsible active principle. The effects of the compound obtained and of L. molleoides extract on P. mirabilis growth and virulence factors were evaluated. Compound 1 showed MIC and MBC values of 4000 μg/ml. It was found that the extract, at four times the MIC, produced complete killing of the uropathogen at 2h from the beginning of the experiment, while the alkylresorcinol, at four times the MIC, produced the same effect after 24 h. Hemolysis was adversely affected in treatments with both products at 8 μg/ml, while hemagglutination was not altered. The whole extract induced complete autoaggregation of P. mirabilis at 2000 μg/ml, while compound 1 at the same concentration did not show this property. Swarming motility was delayed in treatments with the extract and with 1 at 1000 and 8 μg/ml, respectively, at 8h from the beginning of the assay. Complete inhibition of the phenomenon was still observed after 24 h when compound 1 was added at 125 μg/ml. These findings offer the possibility of new classes of antimicrobial medicines to tackle infections caused by P. mirabilis.

An explanatory model to validate the way water activity rules periodic terrace generation in Proteus mirabilis swarm

This paper explains the biophysical principles which, according to us, govern the Proteus mirabilis swarm phenomenon. Then, this explanation is translated into a mathematical model, essentially based on partial differential equations. This model is then implemented using numerical methods of the finite volume type in order to make simulations. The simulations show most of the characteristics which are observed in situ and in particular the terrace generation.

[Antagonistic effect of bacteriocinogenic Lactobacillus acidophilus on Klebsiella pneumoniae, Citrobacter freundii and Proteus mirabilis cells]

Data of the ultrastructural cellular changes of conditionally pathogenic enterobacteria, including K. pneumoniae, C. freundii and P. mirabilis cells impacts to bacteriocin-producing L. acidophilus are presented. Enterobacteria in response to the bacteriocinogenic effect of lactobacilli are manifestated by expressive destructions of sensitive to pore formation bacteriocin cells. Various morphological types of enterobacteria cells with increase of involution, lysing and resting forms are revealed. The specific ultrastructural changes of enterobacteria cells which evidencing the significant destructive processes of the cells membranes are detected. The destabilization of cellular wall in expansion periplasmic spaces and appearance of the ultrastructural reorganization of bacterial cells nucleoid also are registrated. Revealing the mechanism of lactobacilli secreted bacteriocin action to conditionally pathogenic enterobacteria might provide new ways to select the effective highly antagonistic probiotic strains.

Ultrastructure of Proteus mirabilis swarmer cell rafts and role of swarming in catheter-associated urinary tract infection

Proteus mirabilis is a common cause of catheter-associated urinary tract infection (C-UTI). It blocks indwelling urethral catheters through the formation of extensive crystalline biofilms. The obstruction of urine flow can induce episodes of pyelonephritis, septicemia, and shock. P. mirabilis exhibits a type of motility referred to as swarming, in which multicellular rafts of elongated, hyperflagellated swarmer cells form and move rapidly in concert over solid surfaces. It has been suggested that swarming is important in the pathogenesis of C-UTI. In this study we generated a set of stable transposon mutants deficient in swarming and used them to assess the role of swarming in the migration of P. mirabilis over urinary catheters. Swarming was found to be essential for migration over all-silicone catheters. Swarming-deficient mutants were attenuated in migration over hydrogel-coated latex catheters, but those capable of swimming motility were able to move over and infect these surfaces. A novel vapor fixation technique for the preparation of specimens and scanning electron microscopy were used to resolve the ultrastructure of P. mirabilis multicellular rafts. The flagellar filaments of P. mirabilis were found to be highly organized during raft migration and were interwoven in phase to form helical connections between adjacent swarmer cells. Mutants lacking these novel organized structures failed to swarm successfully. We suggest that these structures are important for migration and formation of multicellular rafts. In addition, the highly organized structure of multicellular rafts enables P. mirabilis to initiate C-UTI by migration over catheter surfaces from the urethral meatus into the bladder.

Microwave irradiation for shortening the processing time of samples of flagellated bacteria for scanning electron microscopy

Microwave irradiation (MWI) has been applied to the development of rapid methods to process biological samples for scanning electron microscopy (SEM). In this paper we propose two simple and quick techniques for processing bacteria (Proteus mirabilis and Vibrio mimicus) for SEM using MWI. In the simplest methodology, the bacteria were placed on a cover-glass, air-dried, and submitted to conductivity stain. The reagent used for the conductivity stain was the mordant of a light microscopy staining method (10 ml of 5% carbolic acid solution, 2 g of tannic acid, and 10 ml of saturated aluminum sulfate 12-H2O). In the second method the samples were double fixed (glutaraldehyde and then osmium), submitted to conductivity stain, dehydrated through a series of ethanol solutions of increasing concentration, treated with hexamethyldisilazine (HMDS), and dried at 35 degrees C for 5 minutes. In both methods the steps from fixation to treatment with HMDS were done under MWI for 2 minutes in an ice-water bath, in order to dissipate the heat generated by the MWI. Although both techniques preserve bacterial morphology adequately, the latter, technique showed the best preservation, including the appearance of flagella, and that process was completed in less than 2 hours at temperatures of MWI between 4 to 5 degrees C.

Proteus mirabilis fimbriae (PMF) are important for both bladder and kidney colonization in mice

Proteus mirabilis expresses different types of fimbriae simultaneously. Several fimbrial types have been described and their role in the colonization of the urinary tract is under study. Previously, P. mirabilis fimbriae (PMF) have been shown to be associated with bacterial colonization of the lower urinary tract but not of the kidneys. In this study, a pmfA mutant was generated and used in several in vivo and in vitro studies. Two different urinary tract infection models in the mouse and two in vitro assays of bacterial adhesion to uroepithelial cells were performed. Expression of PmfA in a collection of P. mirabilis strains of different sources was also assessed. The results shown here indicate that PMF are involved in both bladder and kidney colonization by P. mirabilis and that these fimbriae are widely distributed among P. mirabilis isolates from different origins since all strains tested expressed PmfA.

High-resolution backscatter electron imaging of colloidal gold in LVSEM

High-resolution backscatter electron (BSE) imaging of colloidal gold can be accomplished at low voltage using in-lens or below-the-lens FESEMs equipped with either Autrata-modified yttrium aluminium garnet (YAG) scintillators doped with cerium, or with BSE to secondary electron (SE) conversion plates. The threshold for BSE detection of colloidal gold was 1.8 keV for the YAG detector, and the BSE/SE conversion was sensitive down to 1 keV. Gold particles (6, 12 and 18 nm) have an atomic number of 79 and were clearly distinguished at 500,000x by materials contrast and easily discriminated from cell surfaces coated with platinum with an atomic number of 78. BSE imaging was relatively insensitive to charging, and build up of carbon contamination on the specimen was transparent to the higher energy BSE.

Swarming ofProteus mirabilisover Ureteral Stents: A Comparative Assessment

BACKGROUND AND PURPOSE

Encrustation on indwelling ureteral stents is commonly related to the presence of urease-producing bacteria that elevate the pH of the urine through the hydrolysis of urea, resulting in the precipitation of calcium and magnesium salts. Using a model previously shown to measure accurately the ability of Proteus mirabilis to swarm over catheter surfaces (Eur J Clin Microbiol Infect Dis 1999;18:206), we investigated the ability of this organism to swarm over three ureteral stents with potential encrustation-resistance properties.

MATERIALS AND METHODS

Three commercially available ureteral stents were selected for evaluation: a low surface-energy stent, a hydrogel-coated stent, and a silicone stent. Ten-microliter aliquots of a 4-hour culture of P. mirabilis 296 in Trypticase soya (TSA) broth was inoculated 5 mm from a 1-cm channel cut out from TSA plates. Ten-millimeter stent sections were placed as bridges across the central channel adjacent to the inocula. Time to pathogen crossing was measured.

RESULTS

The mean time (+/- SD) to pathogen migration across the three test materials was 15.9 +/- 6.1, 19.8 +/- 9.5, and 29.7 +/- 14.3 hours for the low surface-energy, hydrogel-coated, and silicone stents, respectively. Statistical analysis revealed significant differences between the crossing times of the low surface-energy (P = 0.001) and hydrogel-coated (P = 0.034) stents compared with silicone but not between the low surface-energy and hydrogel-coated stents (P = 0.387).

CONCLUSION

Migration of P. mirabilis 296 across silicone stents was significantly reduced compared with low surface-energy and hydrogel-coated stents. These findings suggest that P. mirabilis may have a lower affinity for silicone stents, which may translate into a reduced risk of infection with P. mirabilis and associated stent encrustation.

High resolution CryoFESEM of microbial surfaces

The outer surfaces of three microorganisms, Giardia lamblia, Enterococcus faecalis, and Proteus mirabilis, were investigated by cryo-immobilization followed by sublimation of extracellular ice and cryocoating with either Pt alone or Pt plus carbon. Cryocoated samples were examined at -125 degrees C in either an in-lens field emission SEM or a below-the-lens field emission SEM. Cryocoating with Pt alone was sufficient for low magnification observation, but attempts to do high-resolution imaging resulted in radiolysis and cracking of the specimen surface. Double coating with Pt and carbon, in combination with high resolution backscatter electron detectors, enabled high-resolution imaging of the glycocalyx of bacteria, revealing a sponge-like network over the surface. High resolution examination of bacterial flagella also revealed a periodic substructure. Common artifacts included radiolysis leading to "cracking" of the surface, and insufficient deposition of Pt resulting in the absence of detectable surface topography.

Effects of mupirocin at subinhibitory concentrations on flagella formation in Pseudomonas aeruginosa and Proteus mirabilis

Colonization of Pseudomonas aeruginosa at trachea, nares and oropharynx can cause ventilator-acquired pneumonia. To identify beneficial effects of antibiotics on expression of virulence factors related to colonization by such pathogens, we evaluated the effect of mupirocin on flagella formation in P. aeruginosa and on motility and flagella formation in Proteus mirabilis. In P. aeruginosa, subinhibitory concentrations of mupirocin inhibited flagella formation, which was associated with reduced flagellin expression. In P. mirabilis, subinhibitory concentrations of mupirocin dose-dependently suppressed bacterial motility and flagella formation, again with reduced flagellin expression. Our results indicate that subinhibitory concentrations of mupirocin can suppress expression of virulence factors in P. aeruginosa and P. mirabilis.

Novel bacterial membrane surface display system using cell wall-less L-forms of Proteus mirabilis and Escherichia coli

We describe a novel membrane surface display system that allows the anchoring of foreign proteins in the cytoplasmic membrane (CM) of stable, cell wall-less L-form cells of Escherichia coli and Proteus mirabilis. The reporter protein, staphylokinase (Sak), was fused to transmembrane domains of integral membrane proteins from E. coli (lactose permease LacY, preprotein translocase SecY) and P. mirabilis (curved cell morphology protein CcmA). Both L-form strains overexpressed fusion proteins in amounts of 1 to 100 microg ml(-1), with higher expression for those with homologous anchor motifs. Various experimental approaches, e.g., cell fractionation, Percoll gradient purification, and solubilization of the CM, demonstrated that the fusion proteins are tightly bound to the CM and do not form aggregates. Trypsin digestion, as well as electron microscopy of immunogold-labeled replicas, confirmed that the protein was localized on the outside surface. The displayed Sak showed functional activity, indicating correct folding. This membrane surface display system features endotoxin-poor organisms and can provide a novel platform for numerous applications.

Molecular mechanisms of interaction of rabbit CAP18 with outer membranes of gram-negative bacteria

The mechanism of interaction of the cationic antimicrobial protein (18 kDa), CAP18, with the outer membrane of Gram-negative bacteria was investigated applying transmission electron microscopy and voltage-clamp techniques on artificial planar bilayer membranes. Electron micrographs of bacterial cells exposed to CAP18 showed damage to the outer membrane of the sensitive Escherichia coli strains F515 and ATCC 11775, whereas the membrane of the resistant Proteus mirabilis strain R45 remained intact. Electrical measurements on various planar asymmetric bilayer membranes, one side consisting of a phospholipid mixture and the other of different phospholipids or of lipopolysaccharide (reconstitution model of the outer membrane), yielded information about the influence of CAP18 on membrane integrity. Addition of CAP18 to the side with the varying lipid composition led to lipid-specific adsorption of CAP18 and subsequent induction of current fluctuations due to the formation of transient membrane lesions at a lipid-specific clamp voltage. We propose that the applied clamp voltage leads to reorientation of CAP18 molecules adsorbed to the bilayer into an active transmembrane configuration, allowing the formation of lesions by multimeric clustering.

Differential expression of nonagglutinating fimbriae and MR/P pili in swarming colonies of Proteus mirabilis

The expression of nonagglutinating fimbriae (NAF) and mannose-resistant/Proteus-like (MR/P) pili in swarming colonies of Proteus mirabilis was investigated. Elongated swarmer cells do not express pili, and the relative number of bacteria expressing NAF during swarming and early consolidation phases was very low (<5%). Relative expression of NAF in a terrace increased to approximately 30% at 48 h. We also determined the expression of NAF and MR/P pili in two phenotypically distinguishable regions of each terrace. The expression of both NAF and MR/P pili was always higher in the region closer (proximal) to the middle of the colony than in the distal region of the terrace. The relative numbers of bacteria expressing NAF or MR/P pili in the proximal region were between 39.1 and 63% and between 5.9 and 7.7%, respectively. In the distal region, expression levels were between 20.8 and 27.3% and between 3.7 and 5. 6%, respectively. A time course experiment testing NAF expression in both the proximal and distal regions of a terrace indicated that NAF expression in the proximal regions was always higher than in the distal regions and increased to a plateau 40 to 50 h after the start of the swarming phase for any given terrace. These results indicate that expression of NAF or MR/P pili in swarming colonies of P. mirabilis is highly organized, spatially and temporally. The significance of this controlled differentiation remains to be uncovered.

A novel membrane protein influencing cell shape and multicellular swarming of Proteus mirabilis

Swarming in Proteus mirabilis is characterized by the coordinated surface migration of multicellular rafts of highly elongated, hyperflagellated swarm cells. We describe a transposon mutant, MNS185, that was unable to swarm even though vegetative cells retained normal motility and the ability to differentiate into swarm cells. However, these elongated cells were irregularly curved and had variable diameters, suggesting that the migration defect results from the inability of these deformed swarm cells to align into multicellular rafts. The transposon was inserted at codon 196 of a 228-codon gene that lacks recognizable homologs. Multiple copies of the wild-type gene, called ccmA, for curved cell morphology, restored swarming to the mutant. The 25-kDa CcmA protein is predicted to span the inner membrane twice, with its C-terminal major domain being present in the cytoplasm. Membrane localization was confirmed both by immunoblotting and by electron microscopy of immunogold-labelled sections. Two forms of CcmA were identified for wild-type P. mirabilis; they were full-length integral membrane CcmA1 and N-terminally truncated peripheral membrane CcmA2, both present at approximately 20-fold higher concentrations in swarm cells. Differentiated MNS185 mutant cells contained wild-type levels of the C-terminally truncated versions of both proteins. Elongated cells of a ccmA null mutant were less misshapen than those of MNS185 and were able to swarm, albeit more slowly than wild-type cells. The truncated CcmA proteins may therefore interfere with normal morphogenesis, while the wild-type proteins, which are not essential for swarming, may enhance migration by maintaining the linearity of highly elongated cells. Consistent with this view, overexpression of the ccmA gene caused cells of both Escherichia coli and P. mirabilis to become enlarged and ellipsoidal.

[The development of a Proteus mirabilis macrocolony on a solid nutrient medium]

As revealed in this study, the macrocolony of Proteus mirabilis, formed on solid culture medium, may consist both of the main part and of sporadically appearing dissociating subcolonies, considerably differing one from another. The outer edge of the main part of the macrocolony of swarming cells is represented by bacteria located in three perpendicular directions. The next intermediate area consisting of two layers is represented by bacteria oriented, as a rule, in one direction. The center of the colony is made up of short microbial cells. Between the upper layer and the surface of agar an original subpopulation of microbial cells, forming a separate layer, has been detected; together they determine the planar sandwich-like architectonics of the macrocolony.

Study of a melanic pigment of Proteus mirabilis

The present study sought to determine whether the pigment produced by Proteus mirabilis from the L-forms of various aromatic amino acids under aerobic conditions is melanic in nature. It is a black-brown pigment which behaves like a melanin in many respects, namely solubility features, bleaching by oxidizing agents and positive response to the Fontana-Masson assay. In the present study, for the first time, it was shown by electron spin resonance analysis that a bacterial melanin is able to act as a free radical trap, as was previously demonstrated for other melanins. Scanning electron microscopy studies showed a specific organized structure of the pigment as rounded aggregates of spherical bodies. DNA hybridization data did not reveal, in the P. mirabilis genome, any nucleotide sequence related to Shewanella colwelliana mel A, one of the two melanogenesis systems already defined at the molecular level in bacteria. Results obtained from experiments on pigment production inhibition suggest a possible role of tyrosinase in P. mirabilis melanogenesis. In conclusion, from the bulk of our results, it appears that the pigment produced by P. mirabilis is melanic in nature.

Inhibitory effect of bile on bacterial invasion of enterocytes: possible mechanism for increased translocation associated with obstructive jaundice

OBJECTIVE

To clarify the effect of bile salts on internalization of enteric bacteria by intestinal epithelial cells.

DESIGN

Randomized study.

SETTING

Research laboratory.

SUBJECTS

Cultured human intestinal epithelial cells, namely HT-29 cells.

INTERVENTIONS

The effect of bile was studied by adding bile during the time period in which bacterial cells were permitted to interact with enterocytes. In subsequent experiments, bile was added to the culture medium used to grow bacteria, and bacterial cells were washed before adding bacteria to enterocytes. Three different concentrations of three different bile preparations were tested.

MEASUREMENTS AND MAIN RESULTS

Salmonella typhimurium and Proteus mirabilis were each incubated with HT-29 cells for 1 hr; the numbers of internalized bacteria were subsequently quantified following enterocyte lysis. The presence of bile during bacteria-enterocyte incubation had no effect on the numbers of internalized bacteria. However, if S. typhimurium or P. mirabilis were grown in the presence of bile, these washed bacterial cells were generally internalized by HT-29 cells in significantly fewer numbers, compared with bacterial cells grown in medium without bile supplementation. Enterocyte viability and morphologic ultrastructure did not appear to be affected by the presence of bile itself, or by the interaction with bacterial cells that had been cultivated in unsupplemented medium or in bile-supplemented medium.

CONCLUSIONS

Exposure to bile during bacterial growth resulted in bacterial cells with decreased invasiveness for cultured intestinal epithelial cells. This observation is consistent with previous in vivo studies of obstructive jaundice, where the absence of bile in the intestinal lumen, not bile duct ligation, appeared to facilitate bacterial translocation in obstructed animals. Thus, the presence of bile in the intestinal lumen may decrease bacterial translocation by a mechanism that involves decreased epithelial internalization of enteric bacteria.

Immunogold localization of glutathione transferase B1-1 in Proteus mirabilis

By using the immunolabelling technique, the cellular localization of glutathione transferase in Proteus mirabilis was investigated. Evidence was obtained indicating a significant higher content of glutathione transferase in the periplasmic than cytoplasmic space. This result further support the idea that bacterial glutathione transferase is involved in xenobiotic detoxication.

Enhanced staining of bacterial flagella using aged mordant in the silver stain

Intensity of bacterial flagella staining using a modified silver stain was increased by aging the mordant for one week at room temperature. The use of aged mordant increased the apparent diameters of stained flagella and resulted in a darker stain. The mordant remained stable for at least four months at room temperature. The staining protocol presented allows application to liquid or solid cultures.

Flagellate and non-flagellate Proteus mirabilis in the development of experimental urinary tract infection

Three isolates of Proteus mirabilis from symptomatic human urinary tract infections (UTI) were tested for their ability to cause renal infection in mice. All three strains were fimbriated as tested by hemagglutination. One of the strains, Pr 988, did not possess flagella, whereas the other two did and were capable of swarming on solid rich media. We compared the capacity of these strains to infect mice in both the ascending and hematogenous mouse UTI models. Infection was assessed by counting viable bacteria in kidney and bladder homogenates in ascending UTI or by the presence of abscesses in the hematogenously inoculated mice. All three strains were able to infect mice in both UTI models. These results suggest that flagella are not absolutely necessary for virulence in these experimental models.

Proteus mirabilis fimbriae: identification, isolation, and characterization of a new ambient-temperature fimbria

Urinary tract infections involving Proteus mirabilis may lead to complications including bladder and kidney stones, acute pyelonephritis, and bacteremia. This bacterium produces a number of fimbriae, two of which, MR/P fimbria and P. mirabilis fimbria, have been shown to contribute to the ability of this pathogen to colonize the bladder and kidney. We have now purified and characterized a previously undescribed fimbria of P. mirabilis, named ambient-temperature fimbria (ATF). Electron microscopy of a pure preparation and immunogold labeling of cells demonstrated that ATF was fimbrial in nature. The major fimbrial subunit of ATF has an apparent molecular weight of 24,000. The N-terminal amino acid sequence, E-X-T-G-T-P-A-P-T-E-V-T-V-D-G-G-T-I-D-F, did not show significant similarity to that of any previously described fimbrial protein. ATF was expressed by all eight P. mirabilis strains examined. Culture conditions affected expression of ATF, with optimal expression observed in static broth cultures at 23 degrees C. This fimbria was not produced by cells grown at 42 degrees C or on solid medium. Expression of ATF did not correlate with mannose-resistant/Proteus-like (MR/P) or mannose-resistant/Klebsiella-like (MR/K) hemagglutination and represents a novel fimbria of P. mirabilis.

Capsule structure of Proteus mirabilis (ATCC 49565)

Proteus mirabilis 2573 (ATCC 49565) produces an acidic capsular polysaccharide which was shown from glycose analysis, carboxyl reduction, methylation, periodate oxidation, and the application of one dimensional and two-dimensional high-resolution nuclear magnetic resonance techniques to be a high-molecular-weight polymer of branched trisaccharide units composed of 2-acetamido-2-deoxy-D-glucose (N-acetyl-D-glucosamine), 2-acetamido-2,6-dideoxy-L-galactose (N-acetyl-L-fucosamine), and D-glucuronic acid, having the structure: [formula: see text] P. mirabilis 2573 also produces an O:6 serotype lipopolysaccharide in which the O-chain component has the same structure as the homologous capsular polysaccharide. This is the first report of a defined capsular polysaccharide in this bacterial genus.

[The mechanisms of Proteus mirabilis resistance to the bactericidal action of blood serum]

When studying sensitivity of Proteus mirabilis to bactericide effect of blood serum the resistance to alternative way of the complement activation was found in a number of strains. The population of cells with morphologically determinable changes of the surface structures resistant to bactericide effect of the serum is formed as affected by the blood serum of the culture P. mirabilis. Proteus proteases capable to inactivate the complement components are one of the factors of P. mirabilis resistance to bactericide effect of the complement.

[The characteristics of the initial link in the intestinal lesion by opportunistic Proteus mirabilis bacteria]

Interaction of Proteus mirabilis with the intestine epithelium in white mongrel mice has been studied by means of bacteriological, toxicological and electron microscopic methods. Introduction of the agar culture of bacteria to the intestine lumen has permitted finding its general toxic action on enterocytes and other cell elements of epithelium which was accompanied by a potentiation of the striated margin membrane degradation but caused no destruction of cells. A damaging factor of protei was connected with the thermostable large-molecular fraction of cultural fluid of bacteria and its action was traced at the first hours of the bacterial contact with the mucous surface of thin intestine. Preliminary weakening of protective barriers of the intestine mucosa permitted protei to penetrate deep into the tissue through the intercellular slots. Colonization of the intestine lumen wall zone by the proteus is a necessary condition of the above-mentioned changes.

Proteus mirabilis flagella and MR/P fimbriae: isolation, purification, N-terminal analysis, and serum antibody response following experimental urinary tract infection

Urinary tract infection with Proteus mirabilis may lead to serious complications, including cystitis, acute pyelonephritis, fever, bacteremia, and death. In addition to the production of hemolysin and the enzyme urease, fimbriae and flagellum-mediated motility have been postulated as virulence factors for this species. We purified mannose-resistant/proteuslike (MR/P) fimbriae and flagella from strains CFT322 and HU2450, respectively. Electron microscopy revealed highly concentrated preparations of fimbriae and flagella. Fimbrial and flagellar structural subunits were estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be 18.5 and 41 kDa, respectively. N-terminal sequencing revealed that 10 of the first 20 amino acids of the major MR/P subunit matched the sequence of the P. mirabilis uroepithelial cell adhesin N terminus and 11 of 20 amino acids matched the predicted amino acid sequence of the Escherichia coli P fimbriae structural subunit, PapA. In addition, 90 and 80% homologies were found between the first 20 amino acids of P. mirabilis flagellin and those of Salmonella typhimurium phase-1 flagellin and the E. coli hag gene product, respectively. An enzyme-linked immunosorbent assay using purified antigens showed a strong reaction between the MR/P fimbriae or flagella and sera of CBA mice challenged transurethrally with P. mirabilis. A possible role for MR/P fimbriae in the pathogenesis of urinary tract infection is supported by (i) a strong immune response to the antigen in experimentally infected animals, (ii) amino acid sequence similarity to other enteric surface structure, and (iii) our previously reported observation that MR/P fimbriae are expressed preferentially as the sole fimbrial type in human pyelonephritis isolates.

Closely linked genetic loci required for swarm cell differentiation and multicellular migration by Proteus mirabilis

The pathogenic bacterium Proteus mirabilis exhibits a form of multicellular behaviour called swarming migration. This involves the differentiation of vegetative cells at the colony margin into swarm cells which are long, aseptate, multinucleate, hyper-flagellated filaments able to undergo repeated cycles of co-ordinated population migration and consolidation (reversion to vegetative cells). Transposon mutagenesis of uropathogenic P. mirabilis strain U6450 with Tn5 generated 4860 chromosomal insertions and, of these, 75 (1.6%) caused visibly abnormal swarming behaviour, indicating that at least 45 genes are involved in directing motility, cell differentiation and multicellular behaviour. While about one fifth of the swarm-defective mutants lacked flagella and were non-motile non-swarming (NMNS) the majority were normally flagellated and motile but were unable to form swarm cells (motile non-swarming, MNS), or were motile and able to form swarm cells but displayed aberrant patterns of multicellular migration (dendritic swarming, DS) or consolidation (frequent and infrequent consolidation, FC and IC). Restriction enzyme mapping of representative mutant DNAs by Southern hybridization with transposon DNA probes identified eight different mutated genetic loci within the five phenotypic classes. Subsequent Southern analysis of large restriction fragments separated by pulsed-field electrophoresis showed that these eight mutated loci required for motility, cell differentiation and multicellular migration were clustered on a region of DNA spanning approximately 8% of the 4.2 mbp P. mirabilis chromosome. Further linkage analysis showed that the DS locus involved in the ordered migration of the swarm cell population mapped separately from two main clusters of swarm loci, one cluster containing, within 112 kbp, genetic determinants of motility (NMNS) and also differentiation into swarm cells (MNS1, MNS2), and a second within a neighbouring 95 kbp DNA sequence containing three loci involved in the control of consolidation (FC, IC1, IC2).

Differentiation of Enterobacteriaceae, Pseudomonas aeruginosa, and Bacteroides and Haemophilus species in gram-stained direct smears

The accuracy of examination of the Gram-stained direct smear to classify presumptively Gram-negative rods into three morphotype groups, that is, (a) Enteric bacteria, (b) Pseudomonas, and (c) Bacteroides or Haemophilus, was evaluated. Randomly selected clinical strains (4-9) each of Escherichia coli, Klebsiella pneumoniae, Proteus mirabilis, Ps. aeruginosa, B. fragilis, and H. influenzae were used to produce peritonitis or subcutaneous abscesses in mice. A Gram-stained direct smear was prepared from exudate collected from each animal. The direct smears were examined to classify bacteria observed into one of the three morphotype groups. The percent accuracy was 82, 56, and 95, respectively, and 76 overall. The assumption was made that classification was based primarily on differences in length and width of the organisms. To test this hypothesis, we prepared scanning electron photomicrographs from each specimen of exudate and measured the lengths and widths of bacteria. Examination of the Gram-stained direct smear was more accurate for classification of enteric bacteria, H. influenzae, or B. fragilis. Electron microscopy was more accurate for classification of Ps. aeruginosa. The higher length-width radio should be helpful in recognizing Ps. aeruginosa in direct smears.

Antigenic and immunogenic activity of flagella and fimbriae preparations from uropathogenic Proteus mirabilis

The antigenic and immunogenic activities of fimbriae and flagella from three uropathogenic strains of Proteus mirabilis were compared. Flagella were obtained by mechanical treatment and fimbriae were isolated from cells by heat shock, ammonium sulfate precipitation, sodium deoxycholate and urea treatment, and gel filtration. Both preparations inoculated to mice demonstrated high antigenicity. Titers up to 1:80,000 were determined by an enzyme-linked immunosorbent assay either against the homologous or heterologous strains. When immunized mice were challenged with homologous or heterologous hematogenous infecting doses, a good cross protection was achieved only when fimbriae were used as antigens. Cross-reactivity found between the three fimbriae antisera, and the presence of common proteins in sodium dodecyl sulfate polyacrylamide gel electrophoresis patterns of fimbriae, should validate the study of these proteins to determine the existence of a shared adhesin.

Staining bacterial flagella easily

A wet-mount technique for staining bacterial flagella is highly successful when a stable stain and regular slides and cover slips are used. Although not producing a permanent mount, the technique is simple for routine use when the number and arrangement of flagella are critical in identifying species of motile bacteria.

The action of sodium deoxycholate on Escherichia coli

Sodium deoxycholate is used in a number of bacteriological media for the isolation and classification of gram-negative bacteria from food and the environment. Initial experiments to study the effect of deoxycholate on the growth parameters of Escherichia coli showed an increase in the lag time constant and generation time and a decrease in the growth rate constant and total cell yield of this microorganism. Cell fractionation studies indicated that sodium deoxycholate at levels used in bacteriological media interferes with the incorporation of [U-14C]glucose into the cold-trichloroacetic acid-soluble, ethanol-soluble, and trypsin-soluble cellular fractions of E. coli. Finally, sodium deoxycholate interfered with the flagellation and motility of Proteus mirabilis and E. coli. It would appear then that further improvement of the deoxycholate medium may be in order.

[Ultrastructural characteristics of Proteus vulgaris and Proteus mirabilis cells differing in the capacity for swarming]

Specific differences in the structure of colonies and the location of microbial cells in colonies, characteristic for aggregating and nonaggregating genetically related pairs of P. vulgaris and P. mirabilis strains, have been demonstrated by means of transmission and scanning electron microscopy. In calculating the number of flagellae per 100 outlines of microbial bodies revealed in negatively stained preparations, the fact that both aggregating and nonaggregating bacteria possess practically the same number of flagellae, on the average 4-8 flagellae per microbial cell outline, has been established. This fact indicates that the presence of flagellae in microbial cells is unrelated to their capacity for swarming.

Histochemical and biochemical urease localization in the periplasm and outer membrane of two Proteus mirabilis strains

Proteus mirabilis, a gram-negative bacillus, is often implicated in the formation of infectious kidney stones. As ureolytic activity of this organism is thought to play a major role in its pathogenesis, we adapted our recently described urease localization technique to visualize urease activity in vivo. Urease activity was ultrastructurally localized in two clinically isolated P. mirabilis strains by precipitating the enzymatic reaction product (ammonia) with sodium tetraphenylboron. Subsequent silver staining of the cells revealed urease activity to be predominantly associated with the periplasm and outer membranes of each strain. Biochemical measurements of urease activity in P. mirabilis cell fractions correlated well with histochemical observations in that the majority of urease activity was associated with the periplasm. Membrane-bound urease activity of these strains was associated mainly with the peptidoglycan in the detergent-insoluble (outer membrane) fraction.

Swarmer cell differentiation of Proteus mirabilis in fluid media

After 3-4 h in a rich fluid medium such as brain--heart infusion broth, motile nonseptate filaments developed from normal short rods and formed about 80% of the cell mass of Proteus mirabilis PM23. This developmental pattern was not observed in any of the other nine representatives of the species. These filaments were considered to be equivalent to swarmer cells formed on agar media because these cells ceased tumbling (i.e., chemotaxis was repressed), they developed large numbers of flagella (i.e., flagella synthesis and insertion was derepressed), and the distribution of nuclei in the filaments indicated that there was normal segregation. The population of cells grown in a minimal medium supplemented with amino acids and nicotinic acid consisted only of short cells with tumbling motility, despite the production of long cells and swarming on the same medium solidified with ordinary agar (refined agar was not effective). These short cells differentiated in 1-1.5 h in brain--heart infusion broth at 37 degrees C after an initial division. The requirements for initiation of differentiation were good basal nutrition, suitable cations (probably Ca2+ and Na+, or K+), and unknown heat-stable organic factors (molecular weight less than 10 000) present in crude agar and yeast extract. Other components of media promoted swarmer differentiation if it was initiated and these included organic acids (lactate), amino acids (proline or serine), phosphate, and an appropriate ionic environment. Comparison of the observed sequence of length classes in brain--heart infusion broth culture with computer generated growth models suggested that, at the outset of growth, 50% of the products of each short cell division ceased septation but grew in length for about five doubling periods and then divided cells from each end at a faster rate (3-5 times per hour) for return to the short cell pool.

[Characteristics of various morphological and biological properties of bacteria of the genus Proteus]

The stable O-form of Proteus has been found to differ from the initial H-form in the absence of flagellae or in a few weakly developed flagellae, in decreased capacity for agglutination with polyvalent and typing sera and in virulence for laboratory animals. As revealed in this study, the conversion of the H-form of Proteus into the stable O-form leads to the loss of resistance to streptomycin, chloramphenicol, tetracycline, monomycin, ampicillin and neomycin.

Unstable L-form of Proteus mirabilis induced by fosfomycin

An unstable L-form of Proteus mirabilis was induced on solid medium by sensitivity test discs (200 micrograms of fosfomycin + 20 micrograms of glucose-6-phosphate). The L-colonies were subcultured on agar containing the antibiotic at a concentration of 60 micrograms/ml. On antibiotic-free medium, all the cells reverted to the bacterial phase. On antibiotic-containing agar, the reversion took place as well although at a much lower frequency. Parents and revertants differed in glucose metabolism while they reacted identically in H2S, indole, and urea tests.

gamma-Glutamyltranspeptidase from Proteus mirabilis: localization and activation by phospholipids

Antiserum was prepared against the purified gamma-glutamyltranspeptidase (EC 2.3.2.2) of Proteus mirabilis. The antiserum inactivated the gamma-glutamyltranspeptidase activities of both purified enzyme and intact cells. Native cells were agglutinated with the antibody. Immunocytochemical studies with indirect immunofluorescence and electron microscopy analysis suggested that gamma-glutamyltranspeptidase is localized on the surface of the cell. Its distribution in the cell wall or periplasmic space or both was also confirmed by the treatment of cells with lysozyme-EDTA. The purified enzyme was activated by the addition of membrane phospholipids isolated from the same bacterium. The hydrolysis activity was stimulated more than the transpeptidation activity by several phospholipids.

The effect of capsular polysaccharide and lipopolysaccharide of Bacteroides fragilis on polymorph function and serum killing

The determinant responsible for the ability of Bacteroides spp. to inhibit polymorph phagocytic killing of aerobic organisms has not yet been identified. Therefore, the roles of lipopolysaccharide and capsular polysaccharide of B. fragilis were investigated. Serum-resistant and serum-sensitive strains of Proteus mirabilis were used to indicate inhibition of phagocytic killing and serum killing of aerobes. Whole organisms of B. fragilis, purified lipopolysaccharide and capsular polysaccharide were added to an in-vitro phagocytosis system. Results showed that greater than 10(7) bacteroides/ml inhibited both serum and phagocytic killing. Concentrations below 10(7)/ml had little effect on either process. Purified capsular polysaccharide (10 or 100 micrograms/ml), either alone in the system or in combination with sub-inhibitory concentrations of B. fragilis also markedly inhibited serum and phagocytic killing. Lipopolysaccharide (9 micrograms/ml) appeared relatively inert. B. ovatus, reputedly non-capsulated, produced identical results to those obtained with B. fragilis, but an encapsulated strain of Streptococcus pneumoniae did not inhibit serum or phagocytic killing.

Proteus mirabilis chromosome mobilization by plasmid D: a physical characterization

Plasmid D, a hybrid of plasmids P-lac and R1 drd19, mediates polarized chromosome mobilization from one origin in Proteus mirabilis strain PM5006, while the parental plasmids neither individually nor combined mobilize this chromosome. To elucidate its acquired mobilizing ability plasmid D was characterized physically in relation to P-lac and R1 drd19. Restriction patterns of these plasmids were compared and it was shown that D consists of P-lac and only the r-determinant (r-det) of R1 drd19. A mechanism for the formation of plasmid D, via transduction of the r-det and subsequent transposon-like integration into P-lac, involving insertion sequence IS1, was suggested. Evidence for aberration in plasmid D DNA as a result of r-det integration into P-lac was attributed to IS1 elements which flank the r-det. Recombination regions of parental plasmid DNA were located on HindIII fragments alpha and beta of plasmid D and were subsequently inserted in vitro into IncP-1 plasmid RP4 that fails to mobilize the P. mirabilis chromosome. RP4::HindIII alpha plasmids did not mobilize the latter chromosome, but rendered the Proteus host lac+. RP4::HindIII beta plasmids pMC1 and pMC17, containing the fragment in opposite orientations, mobilized the P. mirabilis chromsome. For pMC17, mobilization was indistinguishable from that of plasmid D, i.e. having the same orientation and the same single origin. However, mobilization promoted by pMC1 was from two distinctly different origins, different from that of pMC17. This apparently deviates from known examples where inversion of homologous DNA inserted into plasmids leads to mobilization from the same origin but in reverse direction.

Interaction of bacterial pili and leukocytes

Since Duguid and Guilles first described the ability of piliated bacteria to bind to leukocytes, much has been learned about the nature of this interaction. Mannose-sensitive (MS) pili bind to specific mannose-containing receptors on the leukocyte surface. While MS pili are responsible for attachment, the relative hydrophobicity of the bacterial surface determines whether the organism is internalized. Both binding and ingestion trigger the leukocyte to respond with degranulation and enhanced oxidative activity. The response to piliated bacteria, however, is delayed as compared to bacteria opsonized with serum, which may account for the reduced bactericidal activity associated with pili-mediated phagocytosis. A number of factors appear to influence the significance of pili-mediated phagocytosis in vivo. These include natural selective pressures in the host tissue, the ability of the organism to undergo pili phase transition and the presence of serum or other host opsonic factors. Antipili antibody does not enhance leukocyte killing of MS + Escherichia coli, but does stimulate leukocyte metabolic activity. Antipili antibody may, therefore, have an adverse effect on the infectious process by promoting the extracellular release of inflammatory material from the granulocyte.

Extracellular slime associated with Proteus mirabilis during swarming

Light microscopy, transmission electron microscopy, and scanning electron microscopy were used to visualize the extracellular slime of Proteus mirabilis swarm cells. Slime was observed with phase-contrast microscopy after fixation in hot sulfuric acid-sodium borate. Ruthenium red was used to stain slime for transmission electron microscopy. Copious quantities of extracellular slime were observed surrounding swarm cells; the slime appeared to provide a matrix through which the cells could migrate. Swarm cells were always found embedded in slime. These observations support the argument that swarming of P. mirabilis is associated with the production of large quantities of extracellular slime. Examination of nonswarming mutants of P. mirabilis revealed that a number of morphological changes, including cell elongation and increased flagellum synthesis, were required for swarm cell migration. It is still unclear whether extracellular slime production also is required for migration.

Changes in the organization of the outer membrane of Proteus mirabilis during swarming: freeze-fracture structure and membrane fluidity analysis

Freeze-fracture studies of short, nonswarming Proteus mirabilis revealed the characteristic gram-negative profile of fractured inner membrane with densely packed particles and sectioned outer membrane with little or no fracture plane. Long swarming cells, however, fractured easily along both the inner membrane and a second membrane, probably the outer membrane. The inner membrane had a typical profile, whereas the outer membrane had fewer but more prominent particles. Isolation and purification of the inner and outer membranes of the short and long bacteria and examination of them with electron paramagnetic resonance measurements after spinlabeling supported the above observations. The outer membrane of swarmer cells allowed higher mobility of the spin label than did the outer membrane of the nonswarming short cells, which showed a typical rigid profile. These results suggest that regions of lipid bilayer appear in the outer membrane during swarmer formation. Previous observation of the behavior and biochemistry of P. mirabilis during swarming are discussed in light of these results.

Binding of a bacteriophage to wall-membrane adhesion in proteus mirabilis

A bacteriophage was shown to adsorb to plasmolyzed non-swarming cells of Proteus mirabilis preferentially at the sites of adhesion between the inner membrane and outer cell wall membrane; 75% of phage particles were adsorbed at these sites, while 25% were not. Differences in outer membrane composition between swarming and non-swarming cells were reflected in altered phage-binding properties, with only 33% of phage absorbed at these adhesion sites in swarming cells. On the basis of their phage distribution, cross-sections of swarm cells could be distinguished from sections of short non-swarming cells.

Rapid flagella stain

Leifson stain was modified to produce rapid staining of bacterial flagella on untreated microscope slides. The procedure was reliable when tested against a variety of motile and nonmotile bacteria.

Membranes of the protoplast L-form of Proteus mirabilis

Isolated membranes of the cell wall-less stable protoplast L-form of Proteus mirabilis were characterized by density gradient centrifugation and by assay for their major chemical constituents, proteins, phospholipids and lipopolysacchartide, and for some specific marker enzymes of the cytoplasmic membrane. In most of the analyzed properties the L-form protoplast membrane resembled the bacterial cytoplasmic membrane, with some notable modifications. Considerable amounts of lipopolysaccharide, normally an exclusive constituent of the outer membrane, were found. Furthermore, the L-form membranes contained the functions of the reduced nicotinamide adenine dinucleotide oxidase system, of D-lactate dehydrogenase (EC 1.1.1.28) and of succinate dehydrogenase (EC 1.3.99.1) at specific activities comparable to, or in some cases considerably higher than, those present in cytoplasmic membranes of the bacterial form. Of two peptidoglycan DD-carboxypeptidase/transpeptidases (EC 3.4.17.8 and EC 2.3.2.10). which are normally present in the cytoplasmic membrane of the bacterial form of P. mirabilis, the membrane of the protoplast L-form contained only one. Electron microscopy of thin sectioned L-form protoplasts showed extensive heterogeneity of membraneous structures. In addition to the single membraneous integument, internal membrane-bounded vesicles and multiple stacks of membranes were present, as the result of unbalanced growth and membrane synthesis in the L-form state.

Covalent linkage of lipoprotein to peptidoglycan is not essential for outer membrane stability in Proteus mirabilis

Isolated rigis layers from Proteus mirabilis harvested at different growth phases were degraded by endo-N-acetylmuramidase from Chalaropsis B, and the degradation products were investigated. The results show the complete absence of covalently linked lipoprotein in exponential-phase cultures. Stationary cells, however, possess covalently linked lipoprotein in amounts similar to those found in Escherichia coli or Salmonella typhimurium during all growth phases. The overall peptidoglycan structure did not change during transition from logarithmic to stationary growth. Implications of these findings for the organization of the outer membrane are discussed.

Patterns of mobilization of the Proteus mirabilis chromosome by R plasmids

R plasmids R40a, Rip69, R447b, R769 belonging to incompatibility groups A-C, M, N, V, respectively, were investigated for chromosomal mobilizing ability in Proteus mirabilis. Plasmids R40a, Rip69 and R447b mediated polarized transfer of markers in a clockwise direction from origins near tyr-1, metF and ser-2, respectively, on the linkage map. The recovery frequency per donor cell of proximal markers approached 1 x 10(-4) for these three plasmids and the efficiency of chromosomal transfer was higher than that of the previously studied plasmid D. The plasmid-guided chromosomal trajectories overlap and it was possible to complement results obtained with plasmid D to assemble a time-of-entry chromosomal map and directly establish the circularity of the linkage group. The map comprises a length of 93 min in terms of transfer time. Plasmid R769 had a different pattern of chromosome transfer. This plasmid produced recombinants for all markers at frequencies of about 4 x 10(-6) per donor. It effected multiple and more or less simultaneous entry of markers and produced recombination over lengths of chromosome rarely corresponding to more than 10 min on the linkage map.

Properties of R plasmid R772 and the corresponding pilus-specific phage PR772

R plasmid R772 was isolated from a strain of Proteus mirabilis and is a self-transmissible P-1 incompatibility group plasmid having a molecular weight of about 27 x 10(6). It renders bacterial hosts resistant to kanamycin. Phage PR772 was isolated as a phage dependent on the presence of R772 in bacterial hosts. It is hexagonal-shaped with a diameter of 53 nm, has a thick inner membrane and no tail. Vaguely defined appendages are sometimes apparent at some vertices and the phage possesses double-stranded DNA. The DNA has a guanine plus cytosine molar content of 48%. The phage is sensitive to chloroform and has a buoyant density of 1.26 g cm(-3). These observations suggested that the inner membrane of the phage could contain lipid. Phage PR772 differs in morphology from the double-stranded DNA plasmid-specific phages PR4 and PRR1 which adsorb to tips and sides, respectively, of sex pili coded for by P-1 incompatibility group plasmids. Phage PR772 formed clear plaques which varied in diameter. Serologically, phages PR772 and PR4 are possibly related though very distantly, but the two phages have identical host ranges. Phage PR772 adsorbed by one of its apices to tips of sex pili coded for by plasmid R772 in Escherichia coli. It also formed plaques on Salmonella typhimurium Proteus morganii and Providence strains harbouring this plasmid as well as strains of E. coli carrying plasmids of incompatibility groups N or W. The phage produced areas of partial clearing on lawns of P. mirabilis PM5006 harbouring plasmid R772, the P-1 incompatibility group plasmid RP4, the W group plasmid RSa or the N group plasmid N3, and on lawns of Providence strain P29 carrying plasmid RP4.

Genetic circularity of the Proteus mirabilis linkage map

The T incompatibility group plasmid R394 can mobilize the chromosome of Proteus mirabilis strain PM5006. It transferred relatively large segments, corresponding to at least 20 min on the D plasmid chromosomal map of the organism. The frequency of recombination for a large number of selected markers was nearly constant at 5 X 10(-6) per donor cell and it is concluded that mobilization takes place from a number of chromosomal sites. All recombinants were R+ and displayed all properties of the plasmid. By analysing crosses for co-inheritance frequencies of unselected markers, a number of chromosomal loci were assembled in linear array. Linkage between markers at the ends of this linkage group was established to markers at the respective termini of the existing D plasmid linkage group. This established a composite circular linkage map of genes of the P. mirabilis strain PM5006 chromosome.