Capnocytophaga: New genus of gram-negative gliding bacteria I. General characteristics,taxonomic considerations and significance

The characteristics of gliding bacteria isolated from both healthy and diseased sites in the oral cavity are, summarized and the taxonomic position of the bacteria discussed. Uniform attributes of the fusiform isolates include gliding motility, strictly fermentative metabolism dependent on the presence of CO₂ (or HCO ₃ ^- ), under either anaerobic or aerobic conditions, presence of benzidine-reactive components, and the production of acetic and succinic acids as the major or sole, acidic, metabolic and products. Given the guanine and cytosine content of DNA, their gliding motility, and the ability of many strains to attack polysaccharide a relationship to the cytophagas is suggested. This relationship, along with the CO₂-dependent growth is recognized by the generic name Capnocytophaga given them. Many of the isolates are grouped into three species C. ochracea, C. Sputigena, and C. gingivalis, separated on the basis of morphological and physiological traits.     

Nutritional studies on Chloroflexus,a filamentous photosynthetic,gliding bacterium

Nutritional studies on four different strains of Chloroflexus, a new genus of filamentous, photosynthetic bacteria are described. This organism appears to be related to several different procaryotic groups, and in particular to the green sulfur bacteria and blue-green algae. Unlike these autotrophs, however, Chloroflexus is nutritionally diverse, being able to grow aerobically as a light-independent heterotroph, and anaerobically as a photoautotroph or photoheterotroph. Numerous organic carbon sources including hexoses, amino acids, short chain fatty acids, organic acids, and some alcohols are utilized under various growth conditions. These results suggest that this organism may be among the most nutritionally versatile organisms known.     

Properties of the Kinesin-1 motor DdKif3 from Dictyostelium discoideum

The amoeba Dictyostelium discoideum possesses genes for 13 different kinesins. Here we characterize DdKif3, a member of the Kinesin-1 family. Kinesin-1 motors form homodimers that can move micrometer-long distances on microtubules using the energy derived from ATP hydrolysis. We expressed recombinant motors in Escherichia coli and tested them in different in vitro assays. Full-length and truncated Kif3 motors were active in gliding and ATPase assays. They showed a strong dependence on ionic strength. Like the full-length motor, the truncated DdKif3-592 motor (aa 1-592; comprising motor domain, neck, and partial stalk) reached its maximum speed of around 2.0micrcom s(-1) at a potassium acetate concentration of 200mM. The shortened DdKif3-342 motor (aa 1-342; comprising motor domain, partial neck) showed a high ATP turnover, comparable to that of the fungal Kinesin-1, Nkin. Results from the duty cycle calculations and gliding assays indicate that DdKif3 is a processive motor. A GFP-fusion protein revealed a mainly cytoplasmic localization of DdKif3. Immunofluorescence staining makes an association with the endoplasmic reticulum or mitochondria unlikely. Despite a similar phylogenetic distance to both metazoa and fungi, in terms of its biochemical properties DdKif3 revealed a closer similarity to fungal than animal kinesins.     

Association of a new type of gliding,filamentous, purple phototrophic bacterium inside bundles of Microcoleus chthonoplastes in hypersaline cyanobacterial mats

An unidentified filamentous purple bacterium, probably belonging to a new genus or even a new family, is found in close association with the filamentous, mat-forming cyanobacterium Microcoleus chthonoplastes in a hypersaline pond at Guerrero Negro, Baja California Sur, Mexico, and in Solar Lake, Sinai, Egypt. This organism is a gliding, segmented trichome, 0.8–0.9 m wide. It contains intracytoplasmic stacked lamellae which are perpendicular and obliquely oriented to the cell wall, similar to those described for the purple sulfur bacteria Ectothiorhodospira. These bacteria are found inside the cyanobacterial bundle, enclosed by the cyanobacterial sheath. Detailed transmission electron microscopical analyses carried out in horizontal sections of the upper 1.5 mm of the cyanobacterial mat show this cyanobacterial-purple bacterial association at depths of 300–1200 m, corresponding to the zone below that of maximal oxygenic photosynthesis. Sharp gradients of oxygen and sulfide are established during the day at this microzone in the two cyanobacterial mats studied. The close association, the distribution pattern of this association and preliminary physiological experiments suggest a co-metabolism of sulfur by the two-membered community. This probable new genus of purple bacteria may also grow photoheterotrophically using organic carbon excreted by the cyanobacterium. Since the chemical gradients in the entire photic zone fluctuate widely in a diurnal cycle, both types of metabolism probably take place. During the morning and afternoon, sulfide migrates up to the photic zone allowing photoautotrophic metabolism with sulfide as the electron donor. During the day the photic zone is highly oxygenated and the purple bacteria may either use oxidized species of sulfur such as elemental sulfur and thiosulfate in the photoautotrophic mode or grow photoheterotrophically using organic carbon excreted by M. chthonoplastes. The new type of filamentous purple sulfur bacteria is not available yet in pure culture, and its taxonomical position cannot be fully established. This organism is suggested to be a new type of gliding, filamentous, purple phototroph.     

Speculations on the evolution of 9+2 organelles and the role of central pair microtubules

Motility generated by 9+2 organelles, variably called cilia or flagella, evolved before divergence from the last common ancestor of extant eukaryotes. In order to understand better how motility in these organelles is regulated, evolutionary steps that led to the present 9+2 morphology are considered. In addition, recent advances in our knowledge of flagellar assembly, together with heightened appreciation of the widespread role of cilia in sensory processes, suggest that these organelles may have served multiple roles in early eukaryotic cells. In addition to their function as undulating motility organelles, we speculate that protocilia were the primary determinants of cell polarity and directed motility in early eukaryotes, and that they provided the first defined membrane domain for localization of receptors that allowed cells to respond tactically to environmental cues. Initially, motility associated with these protocilia may have been gliding motility rather than the more complex bend propagation. Once these protocilia became functional motile organelles for beating, we believe that addition of an asymmetric central apparatus, capable of transducing signals to dynein motors and altering beat parameters, provided refined directional control in response to tactic signals. This paper presents hypothesized steps in this evolutionary process, and examples to support these hypotheses.     

Perlabentimonas gracilis gen. nov., sp. nov., a gliding aerotolerant anaerobe of the order Bacteroidales,isolated from a terrestrial mud volcano

A novel anaerobic bacterium (strain M08_MB^T) was isolated from a terrestrial mud volcano (Taman Peninsula, Russia). Gram-stain-negative cells were straight and slender rods with gliding motility, occasionally forming long filaments. The isolate was mesophilic, slightly halo- and alkaliphilic chemoorganoheterotroph, growing on carbohydrates (starch, dextrin, pectin, glucose, fructose, mannose, maltose, trehalose, lactose, sucrose) and proteinaceous compounds (peptone, tryptone, gelatin, casein and albumin). Strain M08_MB^T tolerated 3% oxygen in the gas phase while catalase negative. The dominant cellular fatty acids of strain M08_MB^T were C_15:0, C_15:1 and C_13:0 acids. 16S rRNA gene sequence analysis revealed that strain M08_MB^T belongs to the order Bacteroidales and only distantly related to other cultivated members of this order (85.12–90.01% 16S rRNA gene similarity). The genome of strain M08_MB^T had a size of 4.37 Mb with a DNA G + C content of 43.5 mol% (WGS). The genes involved in gliding motility, proteolysis, central carbon metabolism, and oxygen tolerance were listed in genome annotation. Based on the phenotypic and genotypic characteristics, strain M08_MB^T represents a novel species of a novel genus within family Tenuifilaceae, with proposed name Perlabentimonas gracilis gen. nov., sp. nov. The type strain is M08_ MB^T (=DSM 110720 ^T = VKM B-3471 ^T). This is the first representative of Bacteroidales isolated in pure culture from a mud volcano.     

Physicochemical and in situ observations on the adhesion of gliding bacteria to surfaces

The ability of Flexibacter BH3 to adhere to solid surfaces and to overcome the horizontal drag involved in gliding across the surfaces was considered in terms of the Stefan adhesion principle. The extracellular slime produced by Flexibacter BH3 was suitable as a Stefan adhesive because it exhibited viscous properties characteristic of a linear colloid, increasing the adhesiveness of the bacterium but allowing translational motion across the surface. The water-soluble slime was a glycoprotein, containing glucose, fucose, galactose and some uronic acid. Vesicles and tubules on the outer surface of Flexibacter BH3 possessed trilaminar membranes, contained 2-keto-3-deoxyoctonate (KDO), and showed identity with phenol-extracted lipopolysaccharide (LPS) in gel-diffusion tests.Sections of Flexibacter BH3 gliding on a gold film overlaying an agar medium reveraled a highly convuluted cell envelope outer membrane, portions of which closely conformed to the microcontours of the gold surface. Possible mechanisms of gliding are discussed in relation to this close association with solid surface features, to the finding that flexibility and spiral motion are not essential for gliding, and to evidence revealing the extrusion of slime in advance of pathfinder bacteria.Abbreviations used KDO 2-keto-3-deoxyoctonate - LPS lipopolysaccharide     

Genetics of gliding motility in Myxococcus xanthus: Molecular cloning of the mgl locus

Summary Wild-type Myxococcus xanthus cells move across solid surfaces by gliding. However no locomotory organelles for gliding have as yet been identified. Two sets of genes are required for gliding in M. xanthus: Gene System A is necessary for the gliding of isolated cells and Gene System S comes into play when cells are close together. The product of the mgl locus is required for both types of gliding and therefore may be a structural component of the gliding organelle. To begin to investigate the function of mgl in gliding a 12 kb segment of M. xanthus DNA containing the locus was cloned in Escherichia coli and returned to Myxococcus by specialized transduction with coliphage P1. In M. xanthus the chimeric plasmid integrates into the chromosome by recombination between the cloned segment and its homolog in the recipient chromosome forming a tandem duplication of the cloned segment with the vector sequences at the novel joint. The construction of partial diploids in this manner facilitated dominance tests and interallelic crosses with ten mgl alleles. We also describe a method for the analysis of tandem duplications that precisely maps alleles to a specific copy of the duplicated sequences. This method provides evidence for the dominance of mgl ⁺ over the mgl ^- alleles. It also reveals what appears to be gene conversion at this locus during recombination between a cloned mgl sequence and its homolog in the chromosome.     

Calcium Entry in Toxoplasma gondii and Its Enhancing Effect of Invasion-linked Traits

During invasion and egress from their host cells, Apicomplexan parasites face sharp changes in the surrounding calcium ion (Ca²⁺) concentration. Our work with Toxoplasma gondii provides evidence for Ca²⁺ influx from the extracellular milieu leading to cytosolic Ca²⁺ increase and enhancement of virulence traits, such as gliding motility, conoid extrusion, microneme secretion, and host cell invasion. Assays of Mn²⁺ and Ba²⁺ uptake do not support a canonical store-regulated Ca²⁺ entry mechanism. Ca²⁺ entry was blocked by the L-type Ca²⁺ channel inhibitor nifedipine and stimulated by the increase in cytosolic Ca²⁺ and by the specific L-type Ca²⁺ channel agonist Bay K-8644. Our results demonstrate that Ca²⁺ entry is critical for parasite virulence. We propose a regulated Ca²⁺ entry mechanism activated by cytosolic Ca²⁺ that has an enhancing effect on invasion-linked traits.