Differentiation of Serratia marcescens 274 into swimmer and swarmer cells

We describe a new sensory response in the enteric bacterium Serratia marcescens. When grown in liquid media, the bacteria were short rods with one to two flagella and displayed classical swimming behavior. Upon transfer to a solid surface (0.7 to 0.8T% agar medium), the bacteria underwent a dramatic change of form. They ceased septation, elongated, and expressed numerous (10 to 100) flagella that covered the lateral sides of the cells. The bacteria now displayed a different form of locomotion--swarming--which allowed them to rapidly move over the top of the solid surface. The differentiation to either swimmer or swarmer cells could be reversed by growth on solid or liquid medium, respectively. To identify conditions that influence this differentiation, the growth environment of S. marcescens was manipulated extensively. The swarming response was monitored by visual and microscopic observation of cell movement on solid surfaces, by immunofluorescent labeling followed by microscopic observation for the presence of elongated, profusely flagellated cells, as well as by estimation of induction of flagellin protein, using Western immunoblot analysis. Conditions that imposed a physical constraint on bacterial movement, such as solid or viscous media, were the most efficient at inducing the swarming response. No chemical constituent of the medium that might contribute to the response could be identified, although the existence of such a component cannot be ruled out. Both swimmer and swarmer cells had flagellin proteins of identical molecular weight, which produced similar proteolysis patterns upon digestion with trypsin.     

Alterations in the cell envelope composition of Proteus mirabilis during the development of swarmer cells.

Long, swarming cells of Proteus mirabilis had different proportions of some lipopolysaccharide components when compared to short cells, either agar grown or broth grown. Fluorescence spectrophotometry of antibody binding, and sodium dodecyl sulphate-polyacrylamide gel electrophoresis indicated that the change was in the proportion of lipopolysaccharide with long O-antigenic sidechains, swarmer lipopolysaccharide relative to short sidechain lipopolysaccharide than the non-swarming cells. The proteins and phospholipids of the envelop remained the same during swarmer development. The results are discussed in relation to the increase in flagella synthesis and permeability to some antibacterial agents during swarmer development.     

Further studies of swarmer cell differentiation of Proteus mirabilis PM23: a requirement for iron and zinc

Proteus mirabilis PM23, unlike other motile strains of the species, differentiates in rich fluid media to form nonseptate filaments resembling the swarmer cells formed on solid media. The swarming activity of PM23 is greater than that of the other strains on solid media and it grows faster than another strain, IM47, in differentiation-supporting broth. This faster growth is not exhibited in broth that does not support differentiation. The differentiation of PM23 in brain-heart infusion broth occurs over a wide range of pH and temperature. Inhibitors of swarming on agar plates (p-nitrophenylglycerol and boric acid) and three chelating agents (EDTA, sodium cyanide, and sodium diethyldithiocarbamate) stop differentiation both on plates and in brain-heart infusion broth; however, EGTA is not effective even at 10 mM (10 times the minimum inhibitory concentration of EDTA). The inhibitory mechanisms of p-nitrophenylglycerol and boric acid are different from that of the chelating agents. The timing of EDTA inhibition suggests generation of a "signal" to differentiate after about 2 h growth. Prevention of differentiation by addition of Fe2+ and Zn2+ up to near the time that differentiation should appear suggests that these cations have a crucial involvement in the process of initiation. However, they are not effective as additives in allowing differentiation to occur in defined media or even nutrient broth; the further addition of nucleotides or cAMP was equally ineffective.     

Caulobacter crescentus pili: structure and stage-specific expression.

Pili are functionally expressed during the predivisional and swarmer stages of the Caulobacter crescentus differentiation cycle. They appear on the developing swarmer pole and at the same cellular location as flagella and the phiCbK receptor sites. Pili disappear when the swarmer cell differentiates into a stalked cell; this occurs with the loss of flagella and the disappearance of phage receptor sites. C. crescentus CB13B1a pili have been purified and characterized. Monomeric pilin is a protein with an apparent molecular weight of 8,500 that stains weakly with periodic acid-Schiff reagent. The amino acid composition of purified pilin reveals very low quantities of basic amino acids and a complete absence of methionine. Pilin is synthesized throughout the C. crescentus differentiation cycle. Neither free pili nor pilin monomers are detectable in the growth media, suggesting that loss of piliation in the swarmer- to stalked-cell transition occurs via pilus retraction.     

Acidic environments induce differentiation of Proteus mirabilis into swarmer morphotypes

Although swarmer morphotypes of Proteus mirabilis have long been considered to result from surfaced-induced differentiation, the present findings show that, in broth medium containing urea, acidic conditions transform some swimmer cells into elongated swarmer cells. This study has also demonstrates that P. mirabilis cells grown in acidic broth medium containing urea enhance virulence factors such as flagella production and cytotoxicity to human bladder carcinoma cell line T24, though no significant difference in urease activity under different pH conditions was found. Since there is little published data on the behavior of P. mirabilis at various hydrogen-ion concentrations, the present study may clarify aspects of cellular differentiation of P. mirabilis in patients at risk of struvite formation due to infection with urease-producing bacteria, as well as in some animals with acidic or alkaline urine.     

Synthesis and Structure of Caulobacter crescentus Flagella

During the normal cell cycle of Caulobacter crescentus, flagella are released into the culture fluid as swarmer cells differentiate into stalked cells. The released flagellum is composed of a filament, hook, and rod. The molecular weight of purified flagellin (subunit of flagella filament) is 25,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The formation of a flagellum opposite the stalk has been observed by microscope during the differentiation of a stalked cell in preparation for cell division. By pulsing synchronized cultures with (14)C-amino acids it has been demonstrated that the synthesis of flagellin occurs approximately 30 to 40 min before cell division. Flagellin, therefore, is synthesized at a discrete time in the cell cycle and is assembled into flagella at a specific site on the cell. A mutant of C. crescentus that fails to synthesize flagellin has been isolated.     

Genetics of swarming motility in Salmonella enterica serovar typhimurium: critical role for lipopolysaccharide

Salmonella enterica serovar Typhimurium can differentiate into hyperflagellated swarmer cells on agar of an appropriate consistency (0.5 to 0.8%), allowing efficient colonization of the growth surface. Flagella are essential for this form of motility. In order to identify genes involved in swarming, we carried out extensive transposon mutagenesis of serovar Typhimurium, screening for those that had functional flagella yet were unable to swarm. A majority of these mutants were defective in lipopolysaccharide (LPS) synthesis, a large number were defective in chemotaxis, and some had defects in putative two-component signaling components. While the latter two classes were defective in swarmer cell differentiation, representative LPS mutants were not and could be rescued for swarming by external addition of a biosurfactant. A mutation in waaG (LPS core modification) secreted copious amounts of slime and showed a precocious swarming phenotype. We suggest that the O antigen improves surface "wettability" required for swarm colony expansion, that the LPS core could play a role in slime generation, and that multiple two-component systems cooperate to promote swarmer cell differentiation. The failure to identify specific swarming signals such as amino acids, pH changes, oxygen, iron starvation, increased viscosity, flagellar rotation, or autoinducers leads us to consider a model in which the external slime is itself both the signal and the milieu for swarming motility. The model explains the cell density dependence of the swarming phenomenon.     

The ability of Proteus mirabilis to sense surfaces and regulate virulence gene expression involves FliL, a flagellar basal body protein

Proteus mirabilis is a urinary tract pathogen that differentiates from a short swimmer cell to an elongated, highly flagellated swarmer cell. Swarmer cell differentiation parallels an increased expression of several virulence factors, suggesting that both processes are controlled by the same signal. The molecular nature of this signal is not known but is hypothesized to involve the inhibition of flagellar rotation. In this study, data are presented supporting the idea that conditions inhibiting flagellar rotation induce swarmer cell differentiation and implicating a rotating flagellar filament as critical to the sensing mechanism. Mutations in three genes, fliL, fliF, and fliG, encoding components of the flagellar basal body, result in the inappropriate development of swarmer cells in noninducing liquid media or hyperelongated swarmer cells on agar media. The fliL mutation was studied in detail. FliL- mutants are nonmotile and fail to synthesize flagellin, while complementation of fliL restores wild-type cell elongation but not motility. Overexpression of fliL+ in wild-type cells prevents swarmer cell differentiation and motility, a result also observed when P. mirabilis fliL+ was expressed in Escherichia coli. These results suggest that FliL plays a role in swarmer cell differentiation and implicate FliL as critical to transduction of the signal inducing swarmer cell differentiation and virulence gene expression. In concert with this idea, defects in fliL up-regulate the expression of two virulence genes, zapA and hpmB. These results support the hypothesis that P. mirabilis ascertains its location in the environment or host by assessing the status of its flagellar motors, which in turn control swarmer cell gene expression.     

Surface-induced swarmer cell differentiation of Vibrio parahaemoiyticus

Vibrio parahaemolyticus distinguishes between life in a liquid environment and life on a surface. Growth on a surface induces differentiation from a swimmer cell to a swarmer cell type. Each cell type is adapted for locomotion under different circumstances. Swimmer cells synthesize a single polar flagellum (Fla) for movement in a liquid medium, and swarmer cells produce an additional distinct flagellar system, the lateral flagella (Laf), for movement across a solid substratum, called swarming. Recognition of surfaces is necessary for swarmer cell differentiation and involves detection of physical signals peculiar to that circumstance and subsequent transduction of information to affect expression of swarmer cell genes (laf). The polar flagellum functions as a tactile sensor controlling swarmer cell differentiation by sensing forces that restrict its movement. Surface recognition also involves a second signal, i.e. nutritional limitation for iron. Studying surface-induced differentiation could reveal a novel mechanism of gene control and lead to an understanding of the processes of surface colonization by pathogens and other bacteria.     

More than Motility: Salmonella Flagella Contribute to Overriding Friction and Facilitating Colony Hydration during Swarming

We show in this study that Salmonella cells, which do not upregulate flagellar gene expression during swarming, also do not increase flagellar numbers per μm of cell length as determined by systematic counting of both flagellar filaments and hooks. Instead, doubling of the average length of a swarmer cell by suppression of cell division effectively doubles the number of flagella per cell. The highest agar concentration at which Salmonella cells swarmed increased from the normal 0.5% to 1%, either when flagella were overproduced or when expression of the FliL protein was enhanced in conjunction with stator proteins MotAB. We surmise that bacteria use the resulting increase in motor power to overcome the higher friction associated with harder agar. Higher flagellar numbers also suppress the swarming defect of mutants with changes in the chemotaxis pathway that were previously shown to be defective in hydrating their colonies. Here we show that the swarming defect of these mutants can also be suppressed by application of osmolytes to the surface of swarm agar. The “dry” colony morphology displayed by che mutants was also observed with other mutants that do not actively rotate their flagella. The flagellum/motor thus participates in two functions critical for swarming, enabling hydration and overriding surface friction. We consider some ideas for how the flagellum might help attract water to the agar surface, where there is no free water.     

Requirement of a cell division step for stalk formation in Caulobacter crescentus.

Penicillin G at low concentrations blocked cell division in Caulobacter crescentus without inhibiting cell growth. The long filamentous cells formed after two to three generations under these conditions had a stalk at one pole and usually one or more flagella at the opposite pole. The failure of the filaments to form a second stalk at the flagellated pole indicates that stalk formation was dependent upon completion of a step that was also required for cell division. Two observations support this conclusion. (i) Penicillin did not stop the normal development of synchronous swarmer cells into stalked initiation and stalk elongation. (ii) When the action of penicillin was reversed by the addition of penicillinase to cultures of filaments, stalks were not formed at the nonstalked pole until after cell division had occurred; thus the normal order of development events was maintained: cell division leads to stalk formation. These results are consistent with a model in which the organization of the developmental program for stalk formation occurs before cell division as a consequence of steps that branch from the cell division pathway.     

Swarmer cell differentiation in Proteus mirabilis

Under the appropriate environmental conditions, the gram-negative bacterium Proteus mirabilis undergoes a remarkable differentiation to form a distinct cell type called a swarmer cell. The swarmer cell is characterized by a 20- to 40-fold increase in both cell length and the number of flagella per cell. Environmental conditions required for swarmer cell differentiation include: surface contact, inhibition of flagellar rotation, a sufficient cell density and cell-to-cell signalling. The differentiated swarmer cell is then able to carry out a highly ordered population migration termed swarming. Genetic analysis of the swarming process has revealed that a large variety of distinct loci are required for this differentiation including: genes involved in regulation, lipopolysaccharide and peptidoglycan synthesis, cell division, ATP production, putrescine biosynthesis, proteolysis and cell shape determination. The process of swarming is important medically because the expression of virulence genes and the ability to invade cells are coupled to the differentiated swarmer cell. In this review, the genetic and environmental requirements for swarmer cell differentiation will be outlined. In addition, the role of the differentiated swarmer cell in virulence and its possible role in biofilm formation will be discussed.     

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".     

Effects of some chemical factors on flagellation and swarming ofVibrio alginolyticus

Vibrio alginolyticus strains recently isolated from Dutch coastal seawater changed flagellar organization when cultivated in the presence of certain chemical agents. On agar media with more than 4.0% (w/v) NaCl the number of lateral flagella per cell decreased with increasing salt concentration. Both on agar media and in broth cultures with 6.0–9.0% (w/v) NaCl, cells with polar tufts of 2–4 sheathed or unsheathed flagella were frequently found. Cells grown on agar media with 7.3–9.8% (w/v) Na₂SO₄ had drastically reduced numbers of lateral flagella, but lacked polar tufts. EDTA suppressed growth, but did not affect flagellar arrangement. In the presence of 0.1–0.3% boric acid or 0.05–0.1% aluminium hydroxide, cells in liquid media tended to produce lateral, in addition to the polar flagella normally observed in broth cultures. Of a number of surface-active agents tested, Tween 80 and Na-taurocholate, even in high concentrations, did not affect flagellation. Bile salts (0.1%) and Na-deoxycholate (0.05%) strongly reduced the number of both polar and lateral flagella. In agar cultures, Na-lauryl sulphate (0.01–0.1%) inhibited the formation of lateral, but increased the incidence of polar flagella. Teepol (0.05–0.2%) had a similar effect and also it had a deteriorating effect on the sheaths of the polar flagella. Concomitant with the reduction in the number of lateral flagella, induced by these agents, swarming on agar media was inhibited.     

Localization of Surface Structures During Procaryotic Differentiation: Role of Cell Division in Caulobacter crescentus

Asymmetric cell division in Caulobacter crescentus produces two cell types, a stalked cell and a new swarmer cell, with characteristics surface structures. We have examined the role of the cell cycle in the differentiation of these two cells using the adsorption of bacteriophage øLC72, the assembly of the polar flagellum, and stalk formation as assays for changes in surface morphology. Previous studies of this aquatic bacterium [17, 25] have suggested that the replicating chromosome acts as a 'clock' in timing the formation of the flagellar filament at one pole of the new swarmer cell. The analysis of conditional cell cycle mutants presented here extends these results by showing that DNA synthesis is also required for adsorption of phage øLC72 and, more importantly, they also suggest that a late cell division step is involved in determining the spatial pattern in which the phage receptors and flagella are assembled. We propose that this cell division step is required for formation of 'organizational' centers which direct the assembly of surface structures at the new cell poles, and for the polarity reversal in assembly that accompanies swarmer cell to stalked cell development.     

Mutations that impair swarming motility in Serratia marcescens 274 include but are not limited to those affecting chemotaxis or flagellar function.

Serratia marcescens exists in two cell forms and displays two kinds of motility depending on the type of growth surface encountered (L. Alberti and R. M. Harshey, J. Bacteriol. 172:4322-4328, 1990). In liquid medium, the bacteria are short rods with few flagella and show classical swimming behavior. Upon growth on a solid surface (0.7 to 0.85% agar), they differentiate into elongated, multinucleate, copiously flagellated forms that swarm over the agar surface. The flagella of swimmer and swarmer cells are composed of the same flagellin protein. We show in this study that disruption of hag, the gene encoding flagellin, abolishes both swimming and swarming motility. We have used transposon mini-Mu lac kan to isolate mutants of S. marcescens defective in both kinds of motility. Of the 155 mutants obtained, all Fla- mutants (lacking flagella) and Mot- mutants (paralyzed flagella) were defective for both swimming and swarming, as expected. All Che- mutants (chemotaxis defective) were also defective for swarming, suggesting that an intact chemotaxis system is essential for swarming. About one-third of the mutants were specifically affected only in swarming. Of this class, a large majority showed active "swarming motility" when viewed through the microscope (analogous to the active "swimming motility" of Che- mutants) but failed to show significant movement away from the site of initial inoculation on a macroscopic scale. These results suggest that bacteria swarming on a solid surface require many genes in addition to those required for chemotaxis and flagellar function, which extend the swarming movement outward. We also show in this study that nonflagellate S. marcescens is capable of spreading rapidly on low-agar media.     

Hypermotility in Clostridium perfringens Strain SM101 Is Due to Spontaneous Mutations in Genes Linked to Cell Division

Clostridium perfringens is a Gram-positive anaerobic pathogen of humans and animals. Although they lack flagella, C. perfringens bacteria can still migrate across surfaces using a type of gliding motility that involves the formation of filaments of bacteria lined up in an end-to-end conformation. In strain SM101, hypermotile variants are often found arising from the edges of colonies on agar plates. Hypermotile cells are longer than wild-type cells, and video microscopy of their gliding motility suggests that they form long, thin filaments that move rapidly away from a colony, analogously to swarmer cells in bacteria with flagella. To identify the cause(s) of the hypermotility phenotype, the genome sequences of normal strains and their direct hypermotile derivatives were determined and compared. Strains SM124 and SM127, hypermotile derivatives of strains SM101 and SM102, respectively, contained 10 and 6 single nucleotide polymorphisms (SNPs) relative to their parent strains. While SNPs were located in different genes in the two sets of strains, one feature in common was mutations in cell division genes, an ftsI homolog in strain SM124 (CPR_1831) and a minE homolog in strain SM127 (CPR_2104). Complementation of these mutations with wild-type copies of each gene restored the normal motility phenotype. A model explaining the principles underlying the hypermotility phenotype is presented.     

Growth and phage production of lysogenic B. megatherium

Cell multiplication and phage formation of lysogenic B. megatherium cultures have been determined under various conditions and in various culture media. 1. In general, the more rapid the growth of the culture, the more phage is produced. No conditions or culture media could be found which resulted in phage production without cell growth. 2. Cultures which produce phage grow normally, provided they are shaken. If they are allowed to stand, those which are producing phage undergo lysis. Less phage is produced by these cultures than by the ones which continue to grow. 3. Cells plated from such phage-producing cultures in liquid yeast extract medium grow normally on veal infusion broth agar or tryptose phosphate broth agar, which does not support phage formation, but will not grow on yeast extract agar. 4. Any amino acid except glycine, tyrosine, valine, leucine, and lysine can serve as a nitrogen source. Aspartic acid gives the most rapid cell growth. 5. The ribose nucleic acid content is higher in those cells which produce phage. 6. The organism requires higher concentrations of Mg, Ca, Sr, or Mn to produce phage than for growth. 7. The lysogenic culture can be grown indefinitely in media containing high phosphate concentrations. No phage is produced under these conditions, but the cells produce phage again in a short time after the addition of Mg. The potential ability to produce phage, therefore, is transmitted through cell division. 8. Colonies developed from spores which have been heated to 100°C. for 5 minutes produce phage and hence, infected cells must divide. 9. No phage can be detected after lysis of the cells by lysozyme.     

The Caulobacter crescentus polar organelle development protein PodJ is differentially localized and is required for polar targeting of the PleC development regulator

Regulation of polar development and cell division in Caulobacter crescentus relies on the dynamic localization of several proteins to cell poles at specific stages of the cell cycle. The polar organelle development protein, PodJ, is required for the synthesis of the adhesive holdfast and pili. Here we show the cell cycle localization of PodJ and describe a novel role for this protein in controlling the dynamic localization of the developmental regulator PleC. In swarmer cells, a short form of PodJ is localized at the flagellated pole. Upon differentiation of the swarmer cell into a stalked cell, full length PodJ is synthesized and localizes to the pole opposite the stalk. In late predivisional cells, full length PodJ is processed into a short form which remains localized at the flagellar pole after cell division and is degraded during swarmer to stalked cell differentiation. Polar localization of the developmental regulator PleC requires the presence of PodJ. In contrast, the polar localization of PodJ is not dependent on the presence of PleC. These results indicate that PodJ is an important determinant for the localization of a major regulator of cell differentiation. Thus, PodJ acts directly or indirectly to target PleC to the incipient swarmer pole, to establish the cellular asymmetry that leads to the synthesis of holdfasts and pili at their proper subcellular location.