Swarming Characteristics of Proteus mirabilis Under Anaerobic and Aerobic Conditions

Nutrients have a pronounced effect on the growth and swarming behaviour of Proteus mirabilis 7002. Iron, zinc, amino acids, and dioxygen are important for rapid growth and normal swarming. Anaerobically grown cultures of P. mirabilis 7002 were unable to swarm on anaerobically maintained rich nutrient agar. Upon exposure to aerobic conditions, P. mirabilis 7002 resumed swarming behaviour. Scanning electron microscopy was used to demonstrate the presence of community organization and mature rafts during normal swarming. These results support the importance of dioxygen and redox status in cell differentiation.     

Inhibitory Effects of Secondary Metabolites from the Red Alga Delisea pulchra on Swarming Motility of Proteus mirabilis

Abnormal, uncoordinated swarming motility of the opportunistic human pathogen Proteus mirabilis was seen when a crude extract of the Australian red alga Delisea pulchra was added to the medium. This occurred at concentrations at which growth rate, swimming motility, cell elongation, polynucleation, and hyperflagellation were not affected. One halogenated furanone from D. pulchra inhibited swarming motility at concentrations that did not affect growth rate and swimming motility. Other structurally similar D. pulchra furanones had no effect on swarming, suggesting considerable specificity in the effects of furanones on swarming motility by P. mirabilis.     

一株奇异变形杆菌对铜绿假单胞菌多细胞行为的抑制作用

目的：抗生素耐药性成为了全球性的健康问题。研究发现病原菌的多细胞行为在抗生素的耐药性中起着至关重要的作用（尤其是生物膜）,因而通过抑制多细胞行为而控制耐药性成为当务之急。本文以奇异变形杆菌（Proteus mirabilis）为研究对象,考察它的发酵滤液对一种机会致病菌——铜绿假单胞菌（Pseudomonas aeruginosa）多细胞行为的作用,以期得到一株多细胞行为抑制菌：在不影响Paerugiliosa生长的前提下,抑制生物膜形成、EPS产生以及定向丛集运动,解除保护,减缓扩散,为降低Paemgi—nosa耐药性,增强抗生素作用效果提供可能。方法：采用结晶紫生物膜测定法、蒽酮一硫酸法、平板检测法,探究Pmirabilis发酵滤液对Paemginosa生物膜、胞外多聚物、定向丛集运动和生长的影响。结果：Pmirabilis发酵滤液能显著抑制Paeruginosa生物膜量,在体积百分比浓度为1％时,抑制率可达60．9％。该菌的发酵滤液还能阻碍Paeruginosa的定向丛集运动,减弱它的吸附和扩散运动;同时,也减少了Pacrugillosa胞外多聚物的产量,在滤液体积百分比浓度为1％时,抑制率达到45．9％。更重要的是,固体平板实验证明该发酵滤液对P．aemginosa的生长没有影响。结论：Pmirabilis在不影响病原菌生长的前提下,对病原菌的多细胞行为有一定的控制作用。其发酵滤液中存在着抑制微生物膜、定向丛集运动等的成分,在治疗细菌感染性疾病和降低抗生素耐药性方面有潜在应用价值。     

Evidence against the involvement of chemotaxis in swarming of Proteus mirabilis.

Nonswarming and nonchemotactic mutants of Proteus mirabilis were isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine or ultraviolet light. These mutants were used in experiments to determine if chemotaxis is involved in the swarming of P. mirabilis. Nonchemotactic mutants failed to form chemotactic bands in a semisolid casein hydrolysate medium, yet they swarmed on the same medium containing 1.5% agar. Nonswarming mutants were attracted towards individual amino acids and components of tryptose. In cross-feeding experiments, no evidence was obtained to indicate the production of a diffusable chemical repellent. In studies with the wild-type P. mirabilis, no clear-cut negative chemotaxis was seen even though three different assays were used and numerous chemicals were tested. Additional evidence against the involvement of chemotaxis in swarming comes from finding that dialysis does not interfere with swarming; swarm cells will swarm immediately when transferred to fresh media, and swarm cells will swarm on an agar-water medium supplemented with a surfactant. These data indicate that chemotaxis is not involved in the swarming of P. mirabilis.     

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).     

The ITS region as a target for characterization of fungal communities using emerging sequencing technologies

In a previous work, it was observed that the swarming of polyamine-deficient Proteus mirabilis ( speB :: sm ) was severely inhibited on Luria–Bertani (LB) swarming plates (LBSw) (LB, 0.5% glucose, 0.5% agar), and it was clarified that extracellular putrescine was important as a signaling molecule for the induction of swarming in P. mirabilis . However, a polyamine-deficient strain (delta- speAB delta- speC ) of Escherichia coli swarmed as well as the parental strain on LBSw plates. We report that the swarming phenotype of a polyamine-deficient E. coli strain is dependent on spermidine and PotABCD, a spermidine importer.     

Proteus mirabilis mutants defective in swarmer cell differentiation and multicellular behavior

Proteus mirabilis is a dimorphic bacterium which exists in liquid cultures as a 1.5- to 2.0-microns motile swimmer cell possessing 6 to 10 peritrichous flagella. When swimmer cells are placed on a surface, they differentiate by a combination of events that ultimately produce a swarmer cell. Unlike the swimmer cell, the polyploid swarmer cell is 60 to 80 microns long and possesses hundreds to thousands of surface-induced flagella. These features, combined with multicellular behavior, allow the swarmer cells to move over a surface in a process called swarming. Transposon Tn5 was used to produce P. mirabilis mutants defective in wild-type swarming motility. Two general classes of mutants were found to be defective in swarming. The first class was composed of null mutants that were completely devoid of swarming motility. The majority of nonswarming mutations were the result of defects in the synthesis of flagella or in the ability to rotate the flagella. The remaining nonswarming mutants produced flagella but were defective in surface-induced elongation. Strains in the second general class of mutants, which made up more than 65% of all defects in swarming were motile but were defective in the control and coordination of multicellular swarming. Analysis of consolidation zones produced by such crippled mutants suggested that this pleiotropic phenotype was caused by a defect in the regulation of multicellular behavior. A possible mechanism controlling the cyclic process of differentiation and dediferentiation involved in the swarming behavior of P. mirabilis is discussed.     

Co-ordinate expression of virulence genes during swarm-cell differentiation and population migration of Proteus mirabilis

The uropathogenic Gram-negative bacterium Proteus mirabilis exhibits a form of multicellular behaviour termed swarming, which involves cyclical differentiation of typical vegetative cells into filamentous, multinucleate, hyperflagellate swarm cells capable of rapid and co-ordinated population migration across surfaces. We observed that differentiation into swarm cells was accompanied by substantial increases in the activities of intracellular urease and extracellular haemolysin and metalloprotease, which are believed to be central to the pathogenicity of P. mirabilis. In addition, the ability of P. mirabilis to invade human urothelial cells in vitro was primarily a characteristic of differentiated swarm cells, not vegetative cells. These virulence factor activities fell back as the cells underwent cyclical reversion to the vegetative form (consolidation), in parallel with the diagnostic modulation of flagellin levels on the cell surface. Control cellular alkaline phosphatase activities did not increase during differentiation or consolidation. Non-flagellated, nonmotile transposon insertion mutants were unable to invade urothelial cells and they generated only low-level activities of haemolysin, urease and protease (0-10% of wild type). Motile mutants unable to differentiate into swarm cells were comparably reduced in their haemolytic, ureolytic and invasive phenotypes and generated threefold less protease activity. Mutants that were able to form swarm cells but exhibited various aberrant patterns of swarming migration produced wild-type activities of haemolysin, urease and protease, but their ability to enter urothelial cells was three- to 10-fold lower.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of Indole-Positive Proteus mirabilis

Thirteen indole-producing, swarming strains of Proteus were identified by additional biochemical testing as being Proteus mirabilis. These strains were characterized by 40 biochemical tests and by susceptibility testing to 11 antibiotics. All produced ornithine decarboxylase and were susceptible to members of the penicillin-cephalosporin groups of antibiotics. These indole-positive strains are similar to indole-negative P. mirabilis and are distinctly different from P. vulgaris. For greatest accuracy and to insure greatest clinical relevancy, P. mirabilis and P. vulgaris should be distinguished from one another in the laboratory by performing both the indole and ornithine decarboxylase tests.     

A Zn(II)-translocating P-type ATPase from Proteus mirabilis.

A mutant of Proteus mirabilis had been previously isolated as defective in swarming. The mutation had been found to be in a gene related to the Escherichia coli zntA gene, which encodes the ZntA Zn(II)-translocating P-type ATPase. In this study the P. mirabilis gene was expressed in an E. coli strain in which the zntA gene had been disrupted. The P. mirabilis gene complemented the sensitivity to salts of zinc and cadmium. Everted membrane vesicles from the zntA-disrupted strain lost ATP-driven 65Zn(II) uptake. Membranes from the complemented strain had restored 65Zn(II) transport. These results demonstrate that the P. mirabilis homologue of ZntA is a Zn(II)-translocating P-type ATPase.     

Lecithinase activity of Proteus vulgaris

Lecithinase production is described as a new biochemical property of P. vulgaris strains grown in a selective agar medium containing brilliant green, crystal violet and lecithin (BCL agar), the authors' own modification of egg-yolk culture medium. By using this BCL agar as a medium inhibiting the swarming growth of P. vulgaris cultures the authors succeeded in identifying 12 lecithinase-positive strains among the P. vulgaris isolates obtained from patients with Crohn's disease. Of 50 P. mirabilis strains tested in parallel none gave the positive test for lecithinase production in this medium.     

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.     

Abolition of Swarming of Proteus by p-Nitrophenyl Glycerin: General Properties

Para-nitrophenyl glycerin (PNPG) was shown to be an effective agent to abolish the swarming of Proteus mirabilis and Proteus vulgaris on predried solid culture media. The level required to abolish swarming varied with the strain of Proteus, the components of the medium, and also with the conditions of incubation. Generally 0.1 to 0.2 mM PNPG effectively abolished swarming for at least 24 h with aerobic incubation. Levels of PNPG that abolished swarming showed no effect upon the growth of the cells, little or no effect upon the motility characteristics of the organisms, and no effect upon the cellular morphology. PNPG was found to be freely water soluble, stable to autoclaving, and to retain biological activity for at least one month in prepared culture media stored under refrigeration.     

一株奇异变形杆菌对铜绿假单胞菌多细胞行为的抑制作用*

摘要目的：抗生素耐药性成为了全球性的健康问题。研究发现病原菌的多细胞行为在抗生素的耐药性中起着至关重要的作用 （尤其是生物膜）,因而通过抑制多细胞行为而控制耐药性成为当务之急。本文以奇异变形杆菌（Proteus Mirabilis ）为研究对象,考 察它的发酵滤液对一种机会致病菌———铜绿假单胞菌（ Pseudomonas aeruginose）多细胞行为的作用,以期得到一株多细胞行为抑 制菌：在不影响 P.aeruginosa 生长的前提下,抑制生物膜形成、EPS 产生以及定向丛集运动,解除保护,减缓扩散,为降低P.aeruginosa 耐药性,增强抗生素作用效果提供可能。方法：采用结晶紫生物膜测定法、蒽酮-硫酸法、平板检测法,探究P.aeruginosa 发酵滤 液对P.aeruginosa 生物膜、胞外多聚物、定向丛集运动和生长的影响。结果： P.aeruginosa 发酵滤液能显著抑制生物膜 量,在体积百分比浓度为1 %时,抑制率可达60.9 %。该菌的发酵滤液还能阻碍的定向丛集运动,减弱它的吸附和扩 散运动;同时,也减少了P.aeruginosa 胞外多聚物的产量,在滤液体积百分比浓度为1 %时,抑制率达到45.9%。更重要的是,固体 平板实验证明该发酵滤液对P.aeruginosa 的生长没有影响。结论： 在不影响病原菌生长的前提下,对病原菌的多细胞 行为有一定的控制作用。其发酵滤液中存在着抑制微生物膜、定向丛集运动等的成分,在治疗细菌感染性疾病和降低抗生素耐药 性方面有潜在应用价值。     

Role of the Umo proteins and the Rcs phosphorelay in the swarming motility of the wild type and an O-antigen (waaL) mutant of Proteus mirabilis

Proteus mirabilis is a Gram-negative bacterium that exists as a short rod when grown in liquid medium, but during growth on surfaces it undergoes a distinct physical and biochemical change that culminates in the formation of a swarmer cell. How P. mirabilis senses a surface is not fully understood; however, the inhibition of flagellar rotation and accumulation of putrescine have been proposed to be sensory mechanisms. Our lab recently isolated a transposon insertion in waaL, encoding O-antigen ligase, that resulted in a loss of swarming but not swimming motility. The waaL mutant failed to activate flhDC, the class 1 activator of the flagellar gene cascade, when grown on solid surfaces. Swarming in the waaL mutant was restored by overexpression of flhDC in trans or by a mutation in the response regulator rcsB. To further investigate the role of the Rcs signal transduction pathway and its possible relationship with O-antigen surface sensing, mutations were made in the rcsC, rcsB, rcsF, umoB (igaA), and umoD genes in wild-type and waaL backgrounds. Comparison of the swarming phenotypes of the single and double mutants and of strains overexpressing combinations of the UmoB, UmoD, and RcsF proteins demonstrated the following: (i) there is a differential effect of RcsF and UmoB on swarming in wild-type and waaL backgrounds, (ii) RcsF inhibits UmoB activity but not UmoD activity in a wild-type background, and (iii) UmoD is able to modulate activity of the Rcs system.     

ZapA, the IgA-degrading metalloprotease of Proteus mirabilis, is a virulence factor expressed specifically in swarmer cells

The IgA-degrading metalloprotease, ZapA, of the urinary tract pathogen Proteus mirabilis is co-ordinately expressed along with other proteins and virulence factors during swarmer cell differentiation. In this communication, we have used zapA to monitor IgA protease expression during the differentiation of vegetative swimmer cells to fully differentiated swarmer cells. Northern blot analysis of wild-type cells and beta-galactosidase measurements using a zapA:lacZ fusion strain indicate that zapA is fully expressed only in differentiated swarmer cells. Moreover, the expression of zapA on nutrient agar medium is co-ordinately regulated in concert with the cycles of cellular differentiation, swarm migration and consolidation that produce the bull's-eye colonies typically associated with P. mirabilis. ZapA activity is not required for swarmer cell differentiation or swarming behaviour, as ZapA- strains produce wild-type colony patterns. ZapA- strains fail to degrade IgA and show decreased survival compared with the wild-type cells during infection in a mouse model of ascending urinary tract infection (UTI). These data underscore the importance of the P. mirabilis IgA-degrading metalloprotease in UTI. Analysis of the nucleotide sequences adjacent to zapA reveals four additional genes, zapE, zapB, zapC and zapD, which appear to possess functions required for ZapA activity and IgA proteolysis. Based on homology to other known proteins, these genes encode a second metalloprotease, ZapE, as well as a ZapA-specific ABC transporter system (ZapB, ZapC and ZapD). A model describing the function and interaction of each of these five proteins in the degradation of host IgA during UTI is presented.     

Dynamic aspects of the structured cell population in a swarming colony of Proteus mirabilis

Proteus mirabilis forms a concentric-ring colony by undergoing periodic swarming. A colony in the process of such synchronized expansion was examined for its internal population structure. In alternating phases, i.e., swarming (active migration) and consolidation (growth without colony perimeter expansion), phase-specific distribution of cells differing in length, in situ mobility, and migration ability on an agar medium were recognized. In the consolidation phase, the distribution of mobile cells was restricted to the inner part of a new ring and a previous terrace. Cells composing the outer part of the ring were immobile in spite of their ordinary swimming ability in a viscous solution. A sectorial cell population having such an internal structure was replica printed on fresh agar medium. After printing, a transplant which was in the swarming phase continued its ongoing swarming while a transplanted consolidation front continued its scheduled consolidation. This shows that cessation of migration during the consolidation phase was not due to substances present in the underlying agar medium. The ongoing swarming schedule was modifiable by separative cutting of the swarming front or disruption of the ring pattern by random mixing of the pattern-forming cell population. The structured cell population seemed to play a role in characteristic colony growth. However, separation of a narrow consolidation front from a backward area did not induce disturbance in the ongoing swarming schedule. Thus, cells at the frontal part of consolidation area were independent of the internal cell population and destined to exert consolidation and swarming with the ongoing ordinary schedule.     

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.     

Urease activity related to the growth and differentiation of swarmer cells of Proteus mirabilis

Urease activity was measured using whole cells of both long (swarming) and short (nonswarming) populations of Proteus mirabilis from casein hydrolysate agar (CHA) and broth (CHB) cultures, and from brain heart infusion broth (BHIB) cultures. Urease is a constitutive enzyme for both long and short cells, but its activity was tremendously increased when urea was incorporated into the media. Urease production was also affected by culture age and media used. Before exponential phase, urease activity was very low, and it increased to its highest point after about 4 h in BHIB and 8 h in both CHA and CHB cultures at 37 degrees C. Long cells had higher urease activity than did short cells when grown on CHA, and was also expressed by two different strains cultured in BHIB. Strain PM23, in BHIB, was able to form long cells (swarming cells) to a maximum proportion after about 4 h, but strain IM47 could not differentiate in any of the liquid media. The former had more urease when swarming differentiation was initiated. PM23 grew relatively faster than IM47 when the former began to differentiate, but this fast growth could not be observed when nutrient broth or minimal medium was used. These observations suggest that long or swarming cells are "faster growing" rather than "nongrowing bacteria".