Flagellar Morphology of Vibrio parahaemolyticus (Fujino et al) Sakazaki,Iwanami and Fukumi 19631

The flagellar morphology of 88 Vibrio parahaemolyticus strains, including a strain descended from Fujino's original strain EB101 (= ATCC17802 = KM1339) was studied. EB101 and 83 other strains (95%) showed mixed polar and peritrichous type of flagellation when grown on modified MOF (MMOF) agar after 16-hr incubation at 20 C. Cultures containing numerous peritrichous cells showed wiggly movements in moist preparations and rapidly spreading growth in semisolid agar plates. Peritrichous flagella were easily removed mechanically from the soma. The mean wavelengths of polar and peritrichous flagella were 2.53 μm (normal type) and 1.72 μm (atypical curly type) respectively. Peritrichous cells on solid media appeared after incubation for 2.5 hr at 37 C and 7 hr at 20 C. Overnight incubation at 37 C and acidity of the medium due to fermentation of carbohydrate markedly ruined peritrichous flagella. Electron micrograph of cells grown on MMOF agar revealed a sheathed polar flagellum and unsheathed peritrichous flagella. A hook structure was demonstrated at the proximal end of the latter. Polar monotrichous cultures in MMOF broth sometimes contained some cells having several or many peritrichous flagella of atypical curly type. Seven strains of Vibrio cholerae were exclusively polar monotrichous on solid and in liquid media. The flagellation of V. parahaemolyticus is concluded as being a mixed polar-peritrichous type. This fact would indicate that V. parahaemolyticus should be excluded from the genus Vibrio, since the genus Vibrio was defined as polar monotrichous.     

The rhizobia of lupinus densiflorus Benth., with some remarks on the classification of root nodule bacteria

Summary Four strains of rhizobia from Lupinus densiflorus Benth. were found to differ from the normal slow-growing strains of Rhizobium lupini by a rapid growth on agar medium, a somewhat different pattern of carbon metabolism, good growth in simple synthetic media, and also in their host plant relationships. Three strains had subpolar flagella like other lupine rhizobia, and the same was found to be predominant in a fourth strain previously described as having peritrichous flagellation.Two strains formed effectively nitrogen-fixing root nodules in Lotus corniculatus and Anthyllis vulneraria where the other two formed semieffective or ineffective nodules. All four strains formed ineffective nodules in Lotus uliginosus and Ornithopus sativus. The slow-growing strains of Rh. lupini mostly produce ineffective nodules in Lotus corniculatus but have now been seen to be effective in Lotus uliginosus.Instead of trying to define Rh. lupini as a cross-inoculation group it seems preferable to abandon it as a species and to transfer the fastgrowing strains to Rhizobium leguminosarum sensu Graham (1964) and De Ley and Rassel (1965), in spite of their predominantly subpolar flagellation. The familiar slow-growing strains would remain in the broad group of slow-growing root nodule bacteria with purely subpolar flagellation, called Phytomyxa japonica by Graham (1964) and Rhizobium japonicum by De Ley and Rassel (1965).     

Flagellation and taxonomy ofAcetobacter andAcetomonas

Summary Leifson's findings, that motile, acetate-oxidizing acetic acid bacteria (Acetobacter) have peritrichous flagella, and that motile, non-acetate oxidizing ones (Acetomonas) have polar flagella, of notably short wavelength, are fully confirmed and photographically illustrated. It is not confirmed, however, that the peritrichous flagella ofAcetobacter are always of “orthodox” type with a wavelength of about 2.9 μ, nor that they always tend to be few in number. In one strain ofA. aceti they were numerous, and the wavelength was as short (1.4 μ) as that considered byLeifson to be uniquely confined to the polar flagella ofAcetomonas. Furthermore the polar flagella of the latter genus seem not always to be multitrichous, strains having been found with only a single polar flagellum.     

Giant flagellar bundles ofVibrio alginolyticus (NCMB 1803)

Summary Following swarming ofVibrio alginolyticus on solid medium a large number of giant flagellar bundles appear behind the growth front. The suggested sequence of events leading to bundle formation is as follows. After inoculation from liquid to solid media the short rods with a single polar sheathed flagellum develop peritrichous nonsheathed flagella and elongate into long filamentous swarmers. After division into short rods, some of the cells become spherical in shape with many peritrichous flagella concentrated at one pole in close association with the sheathed polar flagellum. These tufted spherical bodies form the template upon which masses of loose peritrichous flagella spontaneously aggregate.Flagellar bundles formed when bacteria are grown at pH 8.5 are longer than those formed at pH 7.2 and shorter when grown at pH 6.5. In distilled water the flagellar bundles disintegrate into masses of flagellar fragments.     

The Asymmetric Flagellar Distribution and Motility of Escherichia coli

Rod-shaped bacteria such as Escherichia coli divide by binary fission. They inherit an old pole from the parent cell. The new pole is recently derived from the septum. Because the chemoreceptor accumulates linearly with time on the cell pole, the old pole carries more receptors than does the new pole. Here, further evidence is provided that the old pole appears more frequently at the rear when bacteria swim. This phenomenon had been observed, yet not extensively explored in the literature. The biased swimming orientation is the consequence of the asymmetric distribution of flagella over the cell surface. On about 75% of cells, there are more flagella on the old-pole half of the cell than on the new-pole half, regardless of growth conditions. Most flagella are lateral, and few were found on the cell pole per se. The asymmetric flagellar distribution makes cells more efficient in chemotaxis. Both swimming orientation and receptor localization are components of chemotaxis, by which bacteria follow environmental stimuli. If unipolarly flagellated cells, such as the swarmer cells of Caulobacter crescentus, are regarded as 100% polar with respect to chemotaxis, E. coli is about 75%. The difference is quantitative. The peritrichous flagellation might enhance the motility and chemotaxis in the viscous environment of enteric bacteria.     

Polar, peritrichous, and lateral flagella belong to three distinguishable flagellar families

The bacterial flagellum transforms its shape into several distinguishable helical shapes (polymorphs) under various environmental conditions. Polymorphs of each type of flagellum stay on a circle in the pitch-diameter (P versus πD) plot, indicating that they all belong to one family. Previously, we showed that the flagellar family of a marine bacterium Idiomarina loihiensis (Family II) differed from the conventional flagellar family of Salmonella typhimurium (Family I). The pitch and diameter of Family II flagella are half those of Family I flagella. We have suggested that Family I encompasses peritrichous flagella, while Family II forms a polar flagellum. In this study, we have surveyed the polymorphs of flagella from 18 other species and categorized their family types. Previous observations were confirmed; Family I form peritrichous flagella and Family II form polar flagella. Furthermore, we found that lateral flagella had helical parameters much smaller than those of the other two Families and thus belong to a new family (Family III).     

Spatial and numerical regulation of flagellar biosynthesis in polarly flagellated bacteria

Control of surface organelle number and placement is a crucial aspect of the cell biology of many Gram‐positive and Gram‐negative bacteria, yet mechanistic insights into how bacteria spatially and numerically organize organelles are lacking. Many surface structures and internal complexes are spatially restricted in the bacterial cell (e.g. type IV pili, holdfasts, chemoreceptors), but perhaps none show so many distinct patterns in terms of number and localization as the flagellum. In this review, we discuss two proteins, FlhF and FlhG (also annotated FleN/YlxH), which control aspects of flagellar assembly, placement and number in polar flagellates, and may influence flagellation in some bacteria that produce peritrichous flagella. Experimental data obtained in a number of bacterial species suggest that these proteins may have acquired distinct attributes influencing flagellar assembly that reflect the diversity of flagellation patterns seen in different polar flagellates. Recent findings also suggest FlhF and FlhG are involved in other processes, such as influencing the rotation of flagella and proper cell division. Continued examination of these proteins in polar flagellates is expected to reveal how different bacteria have adapted FlhF or FlhG with specific activities to tailor flagellar biosynthesis and motility to fit the needs of each species.     

Peritrichous flagellation in Plesiomonas shigelloides strains.

In total, 131 strains of Plesiomonas shigelloides isolated from various sources were tested for peritrichous flagella by a flagella staining method. When incubated on a solid medium for 18 hr at 25 C, peritrichous flagella were demonstrated in 89 (68%) of them. With an electron microscope, the peritrichous flagella were clearly distinguished from the lophotrichous ones by their wavelength.     

Starvation-Induced Changes in Motility, Chemotaxis, and Flagellation of Rhizobium meliloti

The changes in motility, chemotactic responsiveness, and flagellation of Rhizobium meliloti RMB7201, L5-30, and JJ1c10 were analyzed after transfer of the bacteria to buffer with no available C, N, or phosphate. Cells of these three strains remained viable for weeks after transfer to starvation buffer (SB) but lost all motility within just 8 to 72 h after transfer to SB. The rates of motility loss differed by severalfold among the strains. Each strain showed a transient, two- to sixfold increase in chemotactic responsiveness toward glutamine within a few hours after transfer to SB, even though motility dropped substantially during the same period. Strains L5-30 and JJ1c10 also showed increased responsiveness to the nonmetabolizable chemoattractant cycloleucine. Cycloleucine partially restored the motility of starving cells when added after transfer and prevented the loss of motility when included in the SB used for initial suspension of the cells. Thus, interactions between chemoattractants and their receptors appear to affect the regulation of motility in response to starvation independently of nutrient or energy source availability. Electron microscopic observations revealed that R. meliloti cells lost flagella and flagellar integrity during starvation, but not as fast, nor to such a great extent, as the cells lost motility. Even after prolonged starvation, when none of the cells were actively motile, about one-third to one-half of the initially flagellated cells retained some flagella. Inactivation of flagellar motors therefore appears to be a rapid and important response of R. meliloti to starvation conditions. Flagellar-motor inactivation was at least partially reversible by addition of either cycloleucine or glucose. During starvation, some cells appeared to retain normal flagellation, normal motor activity, or both for relatively long periods while other cells rapidly lost flagella, motor activity, or both, indicating that starvation-induced regulation of motility may proceed differently in various cell subpopulations.     

Swarming of Pseudomonas aeruginosa PAO1 without differentiation into elongated hyperflagellates on hard agar minimal medium

Polar flagellated Pseudomonas aeruginosa PAO1 demonstrated extensive spreading growth in 2 days on 1.5% agar medium. Such spreading growth of P. aeruginosa PAO1 strains was absent on Luria-Bertani 1.5% agar medium, but remarkable on Davis minimal synthetic agar medium (especially that containing 0.8% sodium citrate and 1.5% Eiken agar) under aerobic 37 degrees C conditions. Analyses using isogenic mutants and complementation transformants showed that bacterial flagella and rhamnolipid contributed to the surface-spreading behavior. On the other hand, a type IV pilus-deficient pilA mutant did not lose the spreading growth activity. Flagella staining of PAO1 T cells from the frontal edge of a spreading colony showed unipolar and normal-sized rods with one or two flagella. Thus, the polar flagellate P. aeruginosa PAO1 T appears to swarm on high-agar medium by producing biosurfactant rhamnolipid and without differentiation into an elongated peritrichous hyperflagellate.     

Characterization of two sets of subpolar flagella in Bradyrhizobium japonicum

Bradyrhizobium japonicum is one of the soil bacteria that form nodules on soybean roots. The cell has two sets of flagellar systems, one thick flagellum and a few thin flagella, uniquely growing at subpolar positions. The thick flagellum appears to be semicoiled in morphology, and the thin flagella were in a tight-curly form as observed by dark-field microscopy. Flagellin genes were identified from the amino acid sequence of each flagellin. Flagellar genes for the thick flagellum are scattered into several clusters on the genome, while those genes for the thin flagellum are compactly organized in one cluster. Both types of flagella are powered by proton-driven motors. The swimming propulsion is supplied mainly by the thick flagellum. B. japonicum flagellar systems resemble the polar-lateral flagellar systems of Vibrio species but differ in several aspects.     

The mechanism of swarming of Vibrio alginolyticus

Factors leading to swarming of Vibrio alginolyticus cells on solid media were studied. Polar flagellated rods from liquid medium develop into small colonies on solid medium. Byproducts, accumulating in the colony area, induce at certain critical concentrations, the formation of peritrichous flagella and development of long heavily flagellated filaments which swarm away form the high by-product concentrations. Several types of nonswarming mutants were isolated, among them, mutants which lack the capacity to form swarming-inducing pyproducts, but can be induced to swarm by byproducts of other mutants incapable of swarming. Different compounds could replace the natural metabolic byproducts; at very low concentration these compounds induce peritrichous flagella and swarming in some of the nonswarming mutants mentioned above. The natural metabolic byproducts accumulating in yeast-extract-peptone medium are suggested to be volatile acids belonging to the valine and isoleucine pathway. Wild-type V. alginolyticus cells cannot swarm on certain substrates but its mutants, able to swarm on many substrates in minimal media, are easily selected.     

Phenotypic diversity of Edwardsiella tarda isolated from different origins

Aims: To evaluate the diversity of phenotypic characteristics among isolates of Edwardsiella tarda from various origins. Methods and results: A total of 10 E. tarda strains were investigated on biological characteristics including flagella formation, bacterial motility, biofilm formation, extracellular protein and plasmid profiles. All the E. tarda strains (including two previous recognized as nonflagellation strains) were proven to have an average of 1–7 peritrichous flagella with the precise number positively correlated with motility and biofilm formation. All the E. tarda strains exhibited similar protein profiles except ET2034, LMG2793 and ET080814, which lacked the three major bands of approximately 18, 21 and 55 kDa. E. tarda with the same geographic location shared similar plasmid profiles. Conclusions:  Edwardsiella tarda strains exhibited diversities in phenotypic characteristics that may be linked to differences in geographic location or host origin. In addition, the number of flagella is essential for bacterial motility and biofilm formation. Significance and Impact of the Study: This is the first report demonstrating the difference in flagella formation between E. tarda strains, which may broaden the understanding of flagellation trait at intra‐species level. Furthermore, evaluation of virulence‐associated characteristics can provide useful information for unveiling the diverse pathogenic mechanisms of E. tarda.     

Conversion of mono-polar to peritrichous flagellation in Vibrio alginolyticus

Precise regulation of the number and positioning of flagella are critical in order for the mono-polar-flagellated bacterium Vibrio alginolyticus to swim efficiently. It has been shown that, in V. alginolyticus cells, the putative GTPase FlhF determines the polar location and production of flagella, while the putative ATPase FlhG interacts with FlhF, preventing it from localizing at the pole, and thus negatively regulating the flagellar number. In fact, no ΔflhF cells have flagella, while a very small fraction of ΔflhFG cells possess peritrichous flagella. In this study, the mutants that suppress inhibition of the swarming ability of ΔflhFG cells were isolated. The mutation induced an increase in the flagellar number and, furthermore, most Vibrio cells appeared to have peritrichous flagella. The sequence of the flagella related genes was successfully determined, however, the location of the suppressor mutation could not been found. When the flhF gene was introduced into the suppressor mutant, multiple polar flagella were generated in addition to peritrichous flagella. On the other hand, introduction of the flhG gene resulted in the loss of most flagella. These results suggest that the role of FlhF is bypassed through a suppressor mutation which is not related to the flagellar genes.     

Light Inhibits Flagellation in a Chlamydomonas Mutant

We have isolated a new flagellar mutant in Chlamydomonas reinhardtii.When the mutant was cultured under the white fluorescent lamp({small tilde}4,800 lux), most cells had no flagella. However,when the cultures were put in the dark, flagellation occurred.Greater than 70% of the cells had flagella within 12–16h after the transfer. The flagellar morphology varied from "rod-shape"(same as the wild-type flagella) to "disk-shape". The disk-shapedflagella had the axonemes which were curved into a loop withinthe swollen membrane. Hence, this mutant is called loop-1. Light-inhibitionof flagellation was restored in the presence of 10^–5 MDCMU. The spectral dependency of the photo-inhibition of flagellation,determined using the Okazaki Large Spectrograph, showed maximaleffectiveness at 400–420 nm and 600–680 nm. Theseresults suggest that photosynthesis inhibits flagellation ofloop-1 cells. (Received July 27, 1989; Accepted January 29, 1990)     

Electron microscopy of bundled flagella of the curly mutant of Salmonella abortivoequina

Mitani, Michiko (National Institute of Genetics, Mishima, Japan), and Tetsuo Iino. Electron microscopy of bundled flagella of the curly mutant of Salmonella abortivoequina. J. Bacteriol. 90:1096-1101. 1965.-The arrangement of flagella was observed by dark-field and electron microscopy in three strains of Salmonella abortivoequina, namely, normal flagellar, curly flagellar, and paralyzed curly flagellar strains. With dark-field microscopy, bundled flagella could be seen in 5 to 10% of actively moving normal or curly mutant cells. Under the electron microscope, a great many bundled flagella were observed in the curly mutant strain, but in the normal strain most of the flagella were dissociated or the bundles were rather loose and irregular. Normal flagella seem to separate easily during the process of preparation, but not the curly ones. Single flagella were found to run parallel with each other and to form a bundle consisting of five or more flagella; the bundle was spirally gyrating, with the characteristic flagellar wave. It is thought that the bundle observed with the electron microscope corresponds to that observed under the dark-field microscope. Further, the marked decrease of bundle formation in the paralyzed curly mutant cells suggests that bundle formation is not caused by curly flagellar structure per se, but corresponds to the mode of locomotion of peritrichously flagellated bacteria.     

How is the flagellar length of mature sperm determined? I. Comparison of flagellar growth in spermatids between newt and Xenopus in vitro

The kinetics of flagellar growth in round spermatids were compared between Xenopus laevis and Cynops pyrrhogaster in vitro, the latter of which has about 13 times longer flagella in mature sperm than the former. In both species, more than 90% of the spermatids derived from marked primary spermatocytes grew flagella. In Xenopus the average flagellar length increased to 28 microns by the 6th day and then stopped growth, while in the newt, flagellar growth did not stop until reaching 107 microns in average on the 10th day. Maximal length was 36-38 microns in Xenopus and 187 microns in the newt. Two major differences in kinetics of flagellar growth were found between the two species. First, the initial rate of growth in the newt was about double the rate in Xenopus. Second, the period of flagellar growth in the newt (10 days) was also about double the period in Xenopus (5-6 days). Actinomycin D (10 micrograms/ml) had no inhibitory effect on flagellar growth in either species, whereas cycloheximide (10 microM) inhibited flagellar growth by more than 80% in both species. These results indicate that translational control presumably of flagellar protein synthesis plays an important role in flagellar growth in both species and in the difference in flagellar length in spermatids between Xenopus and newt.     

Altered Flagellar Size-Control in shf-1 Short-Flagella Mutants of Chlamydomonas reinhardtii

Two allelic Mendelian mutations which confer a short flagella phenotype were used to explore flagellar size control in Chlamydomonas reinhardtii. When mutant/wild type quadriflagellate dikaryon cells were constructed, their two short flagella rapidly grew out to near wild type length. The kinetics of elongation suggest that the flagellar assembly process is not intrinsically self-limiting as a number of otherwise attractive models for size control require. Instead, we suggest that there exists a cellular machinery dedicated to flagellar size control and that the short-flagella mutations alter the machinery in some as yet unknown way. One of the mutants shows temperature-sensitive flagellar assembly, and both are flagellaless in acetate media. Genetic analysis indicates that the temperaturesensitive, acetate-sensitive, and short-flagella phenotypes have a common genetic basis. The responsible gene has been named shf-1, and it has been mapped to chromosome VI, approximately 5 map units from the centromere.     

Coordinated Flagellar and Ciliary Beating in the Protozoon Tritrichomonas foetus1

ABSTRACT. Tritrichomonas foetus is a flagellated protozoon found in urogenital tract of cattle. Its free movement in liquid medium is powered by the coordinated movement of three flagella projecting towards the anterior region of the cell, and one recurrent flagellum that forms a junction with the cell body and ends as a free projection in the posterior region of the cell. We have used video microscopy and digital image processing to analyze the relationships between the movements of these flagella. The anterior flagella beat in a ciliary type pattern displaying effective and recovery strokes, while the recurrent flagellum beats in a typical flagellar wave form. One of the three anterior flagella has a distinctive pattern of beating. It beats straight in its forward direction as opposed to the ample beats performed by the others. Frequency measurements obtained from cells swimming in a viscous medium shows that the beating frequency of the recurrent flagelium is approximate twice the frequency for the three anterior flagella. We also observed that the costa and the axostyle do not show any active motion. On the contrary, they form a cytoskeletal base for the anchoring and orientation of the flagella.