Two unusual budding bacteria isolated from a swimming pool

Two unusual strains of budding bacteria were isolated on a Millipore Pseudomonas Count Water Tester during routine monitoring of Pseudomonas aeruginosa counts in a swimming pool. The first isolate has been identified as Blastobacter sp. It was a yellow-pigmented, Gram negative rod-shaped organism with a polar holdfast by which it attached to solid surfaces or other cells to form rosettes. The cells reproduced by asymmetric division or budding at the free pole of the cell, producing motile daughter cells with a single polar flagellum. The second isolate, which has not yet been identified, was a red-pigmented, Gram negative rod-shaped organism which produced one or more buds at each pole of the cell. Cell division appears to occur by both binary fission and by budding. Both organisms were strict aerobes, catalase and oxidase positive and did not produce acid from glucose in Hugh and Leifson medium.     

Detoxication of the herbicide diuron byPseudomonas sp.

A strain of bacteria able to detoxicate the herbicide diuron in pure culture was isolated from sites contaminated with different urea herbicides. Diuron was used as a sole source of carbon and energy by this isolate which is a Gram-negative, aerobic, rod-shaped bacterium with a single polar flagellum, and grows at 40 degrees C. The strain has been identified as Pseudomonas sp.     

Taxonomy of bacteria isolated from a coastal, marine fish-rearing unit

Phenetic data on almost 600 aerobic, heterotrophic bacteria from a marine fishrearing unit were collected and analysed using numerical taxonomic techniques. Reference strains, representing 42 taxa were included in the analyses. At similarity levels of 85% or above, with analyses prepared from the simple matching coefficient (S_SM), 81% of the isolates were recovered in eight major and 43 minor phena. Five of the major phena were equated with Acinetobacter calcoaceticus, Photobacterium phosphoreum and Vibrio spp. (three groups); the three unidentified phena contained Gram negative rods with polar flagella which were considered to be intermediate between Cytophaga/Flexibacter and Flavobacterium (two phena), and Gram variable rods. The surface of healthy turbot ( Scophthalmus maximus L. ) was populated by a diverse array of bacteria, including Alcaligenes faecalis, Bacillus firmus, Photobacterium angustum,'Photobacterium logei' and Pseudomonas fluorescens. Taxa, isolated as pure culture growth from within the lesions of moribund animals, included Alteromonas haloplanktis and unidentified Gram negative, budding bacteria. Vibrio anguillarum was not recovered from any turbot suspected of suffering from 'vibriosis'.     

Localization of PBP3 in Caulobacter crescentus is highly dynamic and largely relies on its functional transpeptidase domain

In rod-shaped bacteria, septal peptidoglycan synthesis involves the late recruitment of the ftsI gene product (PBP3 in Escherichia coli) to the FtsZ ring. We show that in Caulobacter crescentus, PBP3 accumulates at the new pole at the beginning of the cell cycle. Fluorescence recovery after photobleaching experiments reveal that polar PBP3 molecules are, constantly and independently of FtsZ, replaced by those present in the cellular pool, implying that polar PBP3 is not a remnant of the previous division. By the time cell constriction is initiated, all PBP3 polar accumulation has disappeared in favour of an FtsZ-dependent localization near midcell, consistent with PBP3 function in cell division. Kymograph analysis of time-lapse experiments shows that the recruitment of PBP3 to the FtsZ ring is progressive and initiated very early on, shortly after FtsZ ring formation and well before cell constriction starts. Accumulation of PBP3 near midcell is also highly dynamic with a rapid exchange of PBP3 molecules between midcell and cellular pools. Localization of PBP3 at both midcell and pole appears multifactorial, primarily requiring the catalytic site of PBP3. Collectively, our results suggest a role for PBP3 in pole morphogenesis and provide new insights into the process of peptidoglycan assembly during division.     

A bacterial leaf spot of Protea cynaroides (king protea)

The etiology of a new leaf spot disease on king protea was investigated. The causal organism was a Gram negative rod-shaped bacterium with between two and seven flagella. On the basis of cultural, biochemical and physiological characters it was identified as a pathovar of Pseudomonas syringae.     

Recent advances on the development of bacterial poles

In rod-shaped bacteria, a surprisingly large number of proteins are localized to the cell poles. Polar positioning of proteins is crucial to many fundamental cellular processes. Formation of the pole occurs at the time of a prior cell division event and involves coordination of the cell division machinery with septal placement of newly-synthesized peptidoglycan. Development of polar peptidoglycan and outer membrane depends on the formation of the cytokinetic FtsZ ring at midcell. By contrast, positioning of at least two polar proteins depends on signals independent of both the assembly of the FtsZ ring and the synthesis of septal and polar peptidoglycan. We propose a model for distinct but interrelated developmental pathways for polar cell envelope synthesis and positional information recognized by polar proteins.     

Cell orientation of swimming bacteria: From theoretical simulation to experimental evaluation

The motion of small bacteria consists of two phases: relatively long runs alternate with intermittent stops, back-ups, or tumbles, depending on the species. In polar monotrichous bacteria, the flagellum is anchored at the cell pole inherited from the parent generation (old pole) and is surrounded by a chemoreceptor cluster. During forward swimming, the leading pole is always the pole recently formed in cell division (new pole). The flagella of the peritrichous bacterium Escherichia coli often form a bundle behind the old pole. Its cell orientation and receptor positioning during runs generally mimic that of monotrichous bacteria. When encountering a solid surface, peritrichous bacteria exhibit a circular motion with the leading pole dipping downward. Some polar monotrichous bacteria also perform circular motion near solid boundaries, but during back-ups. In this case, the leading pole points upward. Very little is known about behavior near milieu-air interfaces. Biophysical simulations have revealed some of the mechanisms underlying these phenomena, but leave many questions unanswered. Combining biophysics with molecular techniques will certainly advance our understanding of bacterial locomotion.     

Attachment of the chromosome to the cell poles: the strategy for the growth of bacteria in two and three dimensions.

Bacteria such as Staphylococcus, Lampropedia, and Sarcina develop in characteristic two-or three-dimensional groups of cells. We propose here a model of how bacteria may generate such groupings by an extension of an earlier model for rod-shaped bacteria. No other mechanism for forming two- or three-dimensional structures of groups of cells has been proposed. Our earlier model for division of rod-shaped bacteria into nearly equal-sized daughters assumed that the origin and terminus DNA were attached at a critical time to polar wall sites. While such binding was speculative 20 years ago, it has now been established that the DNA for the origin of replication, at least during some part of the cell cycle is located in the pole for several different bacteria. Evidence is also building showing that the terminus DNA region is sometimes located at a position in the cell that will develop into two new poles. Here, a new extension of the concept that polar sites bind specifically origin and terminus DNA of the chromosome is presented that can explain how division takes place in one and then in another dimension to form two-dimensional tablets of four cells or large planar arrays. A further possible extension to three dimensions to generate octets of cells is proposed.     

Carbohydrates Oxidation by Pseudomonas albosesamae nov. sp.

Taxonomic behaviors of a newly isolated bacterium which produces 2,5-diketogluconic acid in high yield were examined in this paper. The bacterium was isolated from sesame seed. It is aerobic, rod-shaped bacilli (0.6~0.8 × 1.0~3.0 microns) with rounded ends. It occurs singly or as a small mass and shows motility with a polar flagellum. Gram staining and acid-fast staining are both negative. Endospore and capsule are not observed. It does not possess photosynthetic and usual pigments the cell. Glucose and other sugars are attacked with acid production, but no gas formation. Polysaccharides and sucrose are not attacked. This bacterium does not produce acetic acid from ethanol. The above behaviors and other physiological properties which are described in the text lead to the conclusion that the bacterium is a new species situated in the genus Pseudomonas. So, it was named Pseudomonas albosesamae, nov. sp. (Wakisaka) in relation with its isolated origin.     

Characterization ofPseudomonas geomorphus: A novel groundwater bacterium

Strain ABS10, a Gram-negative, pleomorphic bacterium isolated from a pristine aquifer in Ada, Oklahoma, was studied as a candidate for the introduction and expression of plasmid DNA in a native ground water isolate. This organism was originally typed as anArthrobacter sp. due to its morphological phase change and Gram-variable reaction upon Gram staining. The fatty acid methyl ester profile of ABS10 revealed a high similarity withPseudomonas putida. DNA-DNA hybridization showed 81% homology between ABS10 andP. putida. 16S rRNA sequence analysis showed ABS 10 to be a member of the Gamma division of the purple photosynthetic bacteria. The organism has been designatedPseudomonas geomorphus due to its isolation from a subterranean sample and the morphological phase change from rods in young cultures to cocci in older cultures. The broad host range plasmid RP4 was introduced into ABS10 and stably maintained, indicating that RP4 may serve as a vehicle for the introduction of catabolic genes into this organism.     

Characterization of a planctomycete associated with the marine dinoflagellate Prorocentrum micans Her

During attempts to obtain axenic the cultures of the marine dinoflagellate Prorocentrum micans, a microorganism with peculiar features was isolated. This contaminant resisted the physical and antibiotic treatments performed. Subsequent characterization showed that in agar plates this microorganism develops round granular pink colonies. It is a salt-dependent mesophilic and chemoheterotrophic Gram negative bacterium with a rod to ovoid shape, presenting cell motility in young cultures. Cell division occurs by cell budding. The bacterium forms aggregates with a variable number of cells that are stacked by fibrillar glycoproteic material, the holdfast. A tuft of numerous short glycoproteic fimbriae emerges from one pole of the cell. Preeminent granular inclusions, also of glycoproteic nature, are present in the cytoplasm. Several structural and compositional aspects of the cell envelope and cytoplasm are provided. The production of fibrillar material and the existence of the polar appendages suggest that this microorganism should occur in aquatic environments bound to substrates and could be associated with P. micans in natural marine habitats. Based on the characteristics displayed, this microorganism is a member of the Planctomycetes, order Planctomycetales.     

Morphotype V of theBlastocaulis-Planctomyces group of budding and appendaged bacteria:Planctomyces guttaeformis Hortobágyi (sensu Hajdu)

The ultrastructure of a budding and appendaged bacterium resemblingPlanctomyces guttaeformis Hortobágyi (sensu Hajdu) was examined by transmission electron microscopy in negative-contrast and thin-section preparations from samples of pond and lake water in which natural blooms of this organism had occurred. Its prokaryotic nature was established, and observations were reported regarding its characteristic bulbiform or bulbose cell shape (cylindrical with one globose or swollen end), budding process, crateriform surface structures, rosettes (cell clusters) radiating from the narrow (nonglobose) ends of the adhering cells, cell envelope profile, and distinctive appendages (a single, relatively broad and long, gradually tapered, rigid, multifibrillar, polar or slightly subpolar, noncellular spike—without the adherence function of a stalk—located at the swollen pole of the bulbiform cell; numerous pili/fimbriae all over the globose portion). These traits establish the organism as a putative member of theBlastocaulis-Planctomyces group of budding and appendaged bacteria, but sufficiently distinctive (bulbiform cell shape; spike; adherent material at narrow end of cell rather than at the end of a noncellular appendage) to warrant its delineation as morphotype V of this group.     

Genome Analysis of the Anaerobic Thermohalophilic Bacterium Halothermothrix orenii

Halothermothirx orenii is a strictly anaerobic thermohalophilic bacterium isolated from sediment of a Tunisian salt lake. It belongs to the order Halanaerobiales in the phylum Firmicutes. The complete sequence revealed that the genome consists of one circular chromosome of 2578146 bps encoding 2451 predicted genes. This is the first genome sequence of an organism belonging to the Haloanaerobiales. Features of both Gram positive and Gram negative bacteria were identified with the presence of both a sporulating mechanism typical of Firmicutes and a characteristic Gram negative lipopolysaccharide being the most prominent. Protein sequence analyses and metabolic reconstruction reveal a unique combination of strategies for thermophilic and halophilic adaptation. H. orenii can serve as a model organism for the study of the evolution of the Gram negative phenotype as well as the adaptation under thermohalophilic conditions and the development of biotechnological applications under conditions that require high temperatures and high salt concentrations.     

Pectin-fermenting Bacteria Isolated from the Bovine Rumen

Thirty-two strains of pectin-fermenting rumen bacteria were isolated from bovine rumen contents in a rumen fluid medium which contained pectin as the only added energy source. Based on differences in morphology and the Gram stain, 10 of these strains were selected for characterization. Two strains were identified as Lachnospira multiparus, four strains were identified as Butyrivbrio fibrisolvens, and three strains were identified as Bacteroides ruminicola. Characteristics of the remaining strain did not correspond with any previously described species. It was a gram-positive anaerobic coccus, 1.0 to 1.2 mum in diameter, and occurred primarily as single cells or diplococci. The strain fermented pectin rapidly but showed little or no growth on any other energy sources tested. The only detectable end products were acetic acid and gas, a portion of which was identified as hydrogen. Although the physiological characteristics of this organism differ markedly from other described species, it has been placed in the genus Peptostreptococcus on the basis of morphology, Gram stain, relations to oxygen, and the occurrence of cell division in only one plane. End products of fermentation are somewhat similar to those of the cellulolytic ruminococci. Eight previously characterized strains of cellulolytic bacteria isolated in nonselective media were unable to ferment pectin, whereas ten strains of hemicellulolytic rumen bacteria, eight of which were isolated with a xylan medium, showed considerable variation in this characteristic.     

A mechanism for polar protein localization in bacteria

We investigate a mechanism for the polar localization of proteins in bacteria. We focus on the MinCD/DivIVA system regulating division site placement in the rod-shaped bacterium Bacillus subtilis. Our model relies on a combination of geometric effects and reaction-diffusion dynamics to direct proteins to both cell poles, where division is then blocked. We discuss similarities and differences with related division models in Escherichia coli and also develop extensions of the model to asymmetric polar protein localization. We propose that our mechanism for polar localization may be employed more widely in bacteria, especially in outgrowing spores, which do not possess any pre-existing polar division apparatus from prior division events.     

Polar localization of the autotransporter family of large bacterial virulence proteins

Autotransporters are an extensive family of large secreted virulence-associated proteins of gram-negative bacteria. Secretion of such large proteins poses unique challenges to bacteria. We demonstrate that autotransporters from a wide variety of rod-shaped pathogens, including IcsA and SepA of Shigella flexneri, AIDA-I of diffusely adherent Escherichia coli, and BrkA of Bordetella pertussis, are localized to the bacterial pole. The restriction of autotransporters to the pole is dependent on the presence of a complete lipopolysaccharide (LPS), consistent with known effects of LPS composition on membrane fluidity. Newly synthesized and secreted BrkA is polar even in the presence of truncated LPS, and all autotransporters examined are polar in the cytoplasm prior to secretion. Together, these findings are consistent with autotransporter secretion occurring at the poles of rod-shaped gram-negative organisms. Moreover, NalP, an autotransporter of spherically shaped Neisseria meningitidis contains the molecular information to localize to the pole of Escherichia coli. In N. meningitidis, NalP is secreted at distinct sites around the cell. These data are consistent with a model in which the secretion of large autotransporters occurs via specific conserved pathways located at the poles of rod-shaped bacteria, with profound implications for the underlying physiology of the bacterial cell and the nature of bacterial pathogen-host interactions.     

Unidirectional polar growth of cells of Seliberia stellata and aquatic seliberia-like bacteria revealed by immunoferritin labeling

When grown in a complex peptone-yeast extract culture medium, Seliberia stellata and related morphologically similar aquatic bacterial strains typically divided asymmetrically, giving rise to a motile swarmer and a longer sessile rod. Indirect immunoferritin labeling of these bacteria, followed by incubation during which cell growth occurred, has provided evidence that antigenic cell-surface components are synthesized de novo in a sharply demarcated zone at one pole of the growing parent cells. Cell elongation occurred unidirectionally from the pole showing the de novo surface synthesis; it was this end of the elongating, helically sculptured (i.e., screw-like) rod that became the daughter swarmer cell. The daughter swarmers, produced after polar growth and division of the immunoferritinlabeled parent cells, were not labeled. The immunoferritin label remaining on the parent cell did not appear to be diluted or disturbed by the cell growth and division process. Under the cultural conditions used in this study, the growth and division events which led to production of swarmer cells in the seliberia strains examined met two major criteria of accepted definitions of budding (de novo cell surface synthesis and transverse asymmetry of division). However, the developing daughter cell was not initially narrower than the parent and thus did not increase in cell diameter during growth.In memory: R. Y. Stanier     

A large dispersed chromosomal region required for chromosome segregation in sporulating cells of Bacillus subtilis

The cis-acting sequences required for chromosome segregation are poorly understood in most organisms, including bacteria. Sporulating cells of Bacillus subtilis undergo an unusual asymmetric cell division during which the origin of DNA replication (oriC) region of the chromosome migrates to an extreme polar position. We have now characterized the sequences required for this migration. We show that the previously characterized soj-spo0J chromosome segregation system is not essential for chromosome movement to the cell pole, so this must be driven by an additional segregation mechanism. Observations on a large set of precisely engineered chromosomal inversions and translocations have identified a polar localization region (PLR), which lies approximately 150-300 kbp to the left of oriC. Surprisingly, oriC itself has no involvement in this chromosome segregation system. Dissection of the PLR showed that it has internal functional redundancy, reminiscent of the large diffuse centromeres of most eukaryotic cells.     

Analysis of HubP-dependent cell pole protein targeting in Vibrio cholerae uncovers novel motility regulators

In rod-shaped bacteria, the emergence and maintenance of long-axis cell polarity is involved in key cellular processes such as cell cycle, division, environmental sensing and flagellar motility among others. Many bacteria achieve cell pole differentiation through the use of polar landmark proteins acting as scaffolds for the recruitment of functional macromolecular assemblies. In Vibrio cholerae a large membrane-tethered protein, HubP, specifically interacts with proteins involved in chromosome segregation, chemotaxis and flagellar biosynthesis. Here we used comparative proteomics, genetic and imaging approaches to identify additional HubP partners and demonstrate that at least six more proteins are subject to HubP-dependent polar localization. These include a cell-wall remodeling enzyme (DacB), a likely chemotaxis sensory protein (HlyB), two presumably cytosolic proteins of unknown function (VC1210 and VC1380) and two membrane-bound proteins, named here MotV and MotW, that exhibit distinct effects on chemotactic motility. We show that while both ΔmotW and ΔmotV mutants retain monotrichous flagellation, they present significant to severe motility defects when grown in soft agar. Video-tracking experiments further reveal that ΔmotV cells can swim in liquid environments but are unable to tumble or penetrate a semisolid matrix, whereas a motW deletion affects both tumbling frequency and swimming speed. Motility suppressors and gene co-occurrence analyses reveal co-evolutionary linkages between MotV, a subset of non-canonical CheV proteins and flagellar C-ring components FliG and FliM, whereas MotW regulatory inputs appear to intersect with specific c-di-GMP signaling pathways. Together, these results reveal an ever more versatile role for the landmark cell pole organizer HubP and identify novel mechanisms of motility regulation.