Mathematical modelling of intercellular regulation causing the formation of spatial structures in bacterial colonies

Bacterial colonies may grow forming stable spatial, particularly circular, structures. For instance, motile bacteria Proteus vulgaris or Escherichia coli grown on agar under certain conditions may form concentric rings with the centre in the inoculation point (Rüss-Münzer, 1935, Bact. Parasit Kde (Abt 1) 7, 214; Budriené, 1985, Dokl. Acad. Nauk SSR, 283, 470). A similar picture can be observed in a different situation, i.e. when a lawn of non-motile Salmonella typhimurium bacteria is cultivated on a solid agar with the locally introduced substrate (Hoppensteadt & J?ger, 1980, Lecture Notes in Biomath. 38, 68). This paper describes a mechanism of bacterial interactions through a hypothetical mediator released by the organisms. A mathematical model has been built. Its analysis has shown that the selected laws of secretion and reception of the mediator can adequately account for the formation of circular structures in the case of both motile and non-motile bacteria.     

Regulation der Glucose-6-phosphat-Dehydrogenase aus verschiedenen Bakterienarten durch ATP

Summary Actively motile bacteria became non-motile when plasmolyzed and they regained their motile function when deplasmolyzed. Many of the species observed spontaneously reverted to motile forms if allowed to remain sufficiently long in the plasmolyzing medium. The time required for resumption of motility could be decreased markedly by addition of tryptone, or dl-alanyl-dl-serine, or l-alanine to the medium. Motility resumption occurred when the bacteria stained in a manner similar to that of non-plasmolyzed forms, that is, evenly rather than bipolarly, thus suggesting that the displacement of the membrane influenced motile function.The resumption of motility by plasmolyzed bacteria may serve as a simple screening test for compounds having permeability change effects on the bacterial cytoplasmic membrane as their mode of action.     

Symbiotic and competitive properties of motility mutants of Rhizobium trifolii TA1

Non-motile mutants of Rhizobium trifolii defective in either flagellar synthesis or function were isolated by transposon Tn5 mutagenesis. they were indistinguishable from motile control strains in growth in both laboratory media and in the rhizosphere of clover roots. When each non-motile mutant was grown together with a motile strain in continuous culture, the numbers of motile and non-motile organisms remained in constant proportion, implying that their growth rates were essentially identical. When inoculated separately onto clover roots, the mutants and wildtype did not differ significantly in the number of nodules produced or in nitrogen fixing activity. However, when mixtures of equal numbers of mutant and wild-type cells were inoculated onto clover roots, the motile strain formed approximately five times more nodules than the flagellate or non-flagellate, non-motile mutants, suggesting that motility is a factor in competition for nodule formation.     

The role of motility in the in vitro attachment of Pseudomonas putida PaW8 to wheat roots

The attachment of motile and non-motile strains of Pseudomonas putida PaW8 to sterile wheat roots was assessed in both non-competitive and intra-specific competitive assays. The motile strain showed significantly greater attachment to wheat roots than non-motile strains in phosphate buffer. Overall, the motile strain attached better than the non-motile strain at 10(6), 10(7) and 10(8) cfu ml(-1) in competitive assays and at 10(6) and 10(7) cfu ml(-1) in non-competitive assays. When attachment was studied in Luria broth no significant difference between motile and non-motile strains was detected. P. putida PaW8 cells marked with the luxAB genes were used to compare direct detection of attached cells by luminometry with indirect detection by dilution plate counts following extraction from root material. Although direct detection permitted a rapid assessment (60 s) of attachment to surfaces, dilution plate counts provided a more sensitive method for quantification of bacteria. The detection limits were approximately 10 cfu root(-1) using dilution plate counts compared with 1000 cfu root(-1) using luminometry. All results highlighted the importance of motility for the attachment of P. putida to plant roots in simple model systems. To take this work further, studies to assess the role of motility using complex non-sterile systems are needed.     

Equine blastocyst development after intracytoplasmic injection of sperm subjected to two freeze-thaw cycles

This study was conducted to evaluate the effects of thawing, division into aliquots and refreezing on fertilizing capacity (ability to support embryo development after intracytoplasmic sperm injection; ICSI) of frozen stallion semen. Frozen semen from a fertile stallion was thawed, diluted 1:100 with freezing extender, and refrozen (2F treatment). Control semen was frozen only once. In vitro matured equine oocytes were injected with: (1) motile control spermatozoa; (2) motile 2F spermatozoa; (3) non-motile 2F spermatozoa; or (4) non-motile 2F spermatozoa, followed by injection of sperm extract. Blastocyst development after ICSI was equivalent between control spermatozoa and motile 2F spermatozoa (27 and 23%, respectively). Blastocyst development after injection of non-motile 2F spermatozoa (13%) tended (P=0.07) to be lower than that for control spermatozoa. Injection of sperm extract into oocytes that received non-motile 2F spermatozoa resulted in a significant decrease in blastocyst development (to 2%) compared with injection of non-motile 2F spermatozoa alone. Spermatozoa from a subfertile stallion was similarly processed and used for ICSI; blastocyst development for both motile control (once frozen) spermatozoa and motile 2F spermatozoa was 9%. In conclusion, frozen stallion semen may be thawed, diluted, and refrozen without effect on the ability of motile spermatozoa to initiate embryo development after ICSI. Non-motile spermatozoa from reprocessed semen may also achieve embryo development after ICSI. To our knowledge, this is the first report evaluating the ability of refrozen spermatozoa to produce embryos by ICSI in any species.     

Population dynamics of a motile and a non-motile Azospirillum lipoferum strain during rice root colonization and motility variation in the rhizosphere

Abstract: Azospirillum lipoferum 4B and non-motile A. lipoferum 4T have been simultaneously isolated from rice rhizosphere at the same frequency. A. lipoferum 4T showed stable morphological and metabolic traits which are atypical for A. lipoferum species such as lack of motility, carbohydrate metabolism and laccase activity. Inoculation experiments showed that A. lipoferum 4T, but not A. lipoferum 4B, needed rice roots to stabilize in sterile soil. Both strains were able to colonize efficiently rice roots (10⁸ cfu g⁻¹ fresh roots) but motile form 4B remained dominant. In spite of their phenotypical differences, A. lipoferum 4B and 4T co-existed without exclusion in sterile soil (planted or not) and rice rhizosphere. Inoculation of rice roots with A. lipoferum 4B showed that rice rhizosphere enhanced the frequency of appearance of stable non-motile forms (40%). This percentage was weaker in plantlet growth medium (4%). However, these non-motile bacteria kept the same biochemical traits than the motile parental strain 4B (carbohydrates metabolism, laccase activity).     

Selective elution and purification of living Trichomonas vaginalis using gravitational field-flow fractionation

Gravitational field-flow fractionation is one of the simplest separation methods for biological materials. Its potential in parasitology is demonstrated for Trichomonas vaginalis, a parasite responsible for one of the most widespread sexually transmitted diseases. It was observed that this unicellular parasite can be purified in a culture medium with a recovery of 85% for the living trophozoites. The parasite retention characteristics were different when motile living and non-motile dead cells were eluted, motile cells being less retained than the non-motile cells.     

The effects of agar concentration on the growth and morphology of submerged colonies of motile and non-motile bacteria

The growth and morphology of submerged bacterial colonies was investigated. Five separate colonial forms were recognized depending both on species and on agar concentration. These were (i) branched, dendritic structures seen only with Bacillus cereus ; (ii) lenticular colonies for all other species at high agar concentrations; (iii) small lobed to spherical colonies for non-motile organisms at low agar concentrations; (iv) and (v) large diffuse spherical colonies which can be further subdivided into 'snowball' or 'wispy' types for motile bacteria growing at agar concentrations below about 0·65% w/v. Viable count determinations suggested that agar concentration had little effect in the early stages of growth but that motile cells at low agar concentrations achieved higher cell numbers than did those in concentrations greater than 0·65% w/v. Transmission electron microscopy indicated that bacteria in lenticular colonies were tightly packed within lens-shaped splits in the agar whilst at low agar concentrations motile cells were well separated and appeared to move through the agar matrix.     

The role of bacterial motility in the survival and spread of Pseudomonas fluorescens in soil and in the attachment and colonisation of wheat roots

Motile and non-motile strains of Pseudomonas fluorescens SBW25 were constructed using different combinations of the lacZY, xylE and aph marker genes which allowed their detection and differentiation in soil, root and seed samples. The survival of motile and non-motile strains was investigated in both non-competitive and competitive assays in water and non-sterile soil. Although there was no difference between strains in water, the motile strain survived in significantly greater numbers than the non-motile strain after 21 days in soil. There was no significant difference between competitive assays, where motile and non-motile cells were co-inoculated into soil, and non-competitive assays where strains were inoculated separately. Bacterial survival decreased as matric potential increased from -224 to -17 kPa but matric potential had no significant effect on motile compared to non-motile strains. Vertical spread of both motile and non-motile strains was detected 6.4 mm from the inoculum zone after 14 days in the absence of percolating water. There was no significant difference, for either strain, in distance moved from the inoculum zone after 14, 26 or 40 days. The motile strain had a significant advantage in attachment to sterile wheat roots in both non-competitive and competitive studies. When the spatial colonisation of wheat root systems was assessed in non-sterile soil, there was no significant difference between the motile and non-motile strain from either seed or soil inoculum. However, when the whole root system was assessed as one sample unit, differences could be detected. Bacterial motility could contribute to survival in soil and the initial phase of colonisation, where attachment and movement onto the root surface are important.     

Formation of demarcation zones when bacterial population waves are drawn together

Many motile bacteria (for instance, Escherichia coli) inoculated at some point in a semisolid nutrient medium can form population waves: bands or rings. The formation of these motile structures is due to chemotaxis. The population waves when they are drawn together can form two types of non-motile structures. Firstly, the population waves can collide. Secondly, in certain conditions, the waves can slow down and stop without coming into contact directly with each other. In this way demarcation zones are formed. The mechanism of the occurrence of the demarcation zones has been unknown. In this paper we show that formation of these zones is due to lack of nutrients (which at the same time act as attractants) within the narrow gap between individual bacterial populations.     

Colony morphogenesis in a group of cellulose degrading Gram negative rods from brackish habitats

Cellulose degrading bacteria were isolated from brackish Phragmites reed beds near the Humber Estuary. Of 23 strains brought into pure culture, all developed characteristic differentiated colonies on certain media. On the basis of colour of the colonies (pseudosori) the organisms could be allocated to two groups, XMo and XMb. Related strains were isolated from a similar habitat on the Dee Estuary. Numerical taxonomy showed the group to be relatively diverse but, with a single exception, the XMo and XMb organisms appeared in separate clusters. The organisms were weakly motile or non-motile and certain cells had a polar flagellum. Pigments isolated from one strain had u.v. spectral characteristics similar to those of the xanthomonadins; the organisms may therefore be related to Xanthomonas .     

Use of CFSE staining of borreliae in studies on the interaction between borreliae and human neutrophils

Background  

Species of the tick-transmitted spirochete group Borrelia burgdorferi sensu lato (B. burgdorferi) cause Lyme borreliosis. Acute borrelial infection of the skin has unusual characteristics with only a mild local inflammatory response suggesting that the interaction between borreliae and the cells of the first-line defence might differ from that of other bacteria. It has been reported that human neutrophils phagocytose motile borreliae through an unconventional mechanism (tube phagocytosis) which is not observed with non-motile borreliae. Therefore, it would be of great interest to visualise the bacteria by a method not affecting motility and viability of borreliae to be able to study their interaction with the cells of the innate immunity. Carboxyfluorescein diacetate, succinimidyl ester (CFSE) labelling has been previously used for studying the adhesion of labelled bacteria to host cells and the uptake of labelled substrates by various cells using flow cytometry.     

Precise excision and secondary transposition of TnphoA in non-motile mutants of a Salmonella enterica serovar Enteritidis clinical isolate

Mutagenesis with TnphoA has been widely used in many bacteria. Here, we report the excision and secondary transposition of this transposon in three non-motile (fliC, fliF and motB) mutants of Salmonella enterica serovar Enteritidis (S. Enteritidis). Isolation of motile revertants showed that they were kanamycin resistant and conserved a copy of TnphoA in their genome in an insertion site different from the initial one. They also expressed an intact flagella. Characterization of the motile revertant derived from the fliC mutant showed that TnphoA excised precisely from the fliC gene, resulting in an equivalent amount of FliC secreted protein in the revertant compared to that of the wild-type strain. These results show that TnphoA mutants should be used with care and underline the value of using transposon derivatives lacking the transposase gene.     

Chemotaxis by Entamoeba histolytica

A micropore membrane procedure to assay taxis by Entamoeba histolytica is described and the results of studies of responses to a variety of soluble substances, bacteria, an rat colon washings using this procedure are reported. Trophozoites migrated in blind well chambers through 8-micron pore size polycarbonate membranes but not nitrocellulose membranes up to 12 micron pore size. Amoebae were attracted toward fresh axenic culture medium (TYI-S), an enzymatic hydrolysate of casein (Trypticase), and a partially purified preparation of N-acetylneuraminic acid from egg mucin, but not purified N-acetylneuraminate or a variety of other low molecular weight metabolites. The response was verified as chemotaxis by checkerboard analysis. Amoebae migrated most dramatically toward suspensions of all of seven bacterial species tested, including motile and non-motile, gram-negative and gram-positive rods and cocci. This response was diminished when the bacteria concentration gradient was eliminated. The response to bacteria culture filtrates was less than 10% of that to bacterial suspensions. A response to clarified washings from the rat colon was detected; this was diminished but not eliminated by filter sterilization of the washings. We concluded that some soluble molecules, possibly of intermediate molecular size, whole bacteria, and both soluble and particulate components of the rat colon provide tactic stimuli for E. histolytica. Scanning electron micrographs of trophozoites migrating towards attractants through membranes showed narrow, extended pseudopodia entering the membrane pores, and enlarging spheres exiting as the cells proceeded through.     

Deoxyribonucleic acid relationships among members of the genus Aeromonas.

Polynucleotide sequences among 24 motile and 11 non-motile aeromonads were studied by analysis of deoxyribonucleic acid - deoxyribonucleic acid (DNA-DNA) duplexes with endonuclease S1. In addition, DNA base composition (mole % guanine and cytosine (G + C)) and relative genome sizes were determined for selected strains. Large variations in genome size were found and % GC ranged from 57.1 to 62.9%. On the basis of the strains examined, the Genus Aeromonas consists of two genotypically legitimate groups: a diverse group of motile aeromonads, and the genetically more homogeneous non-motile aeromonads, comprising the species Aeromonas salmonicida. Internal homology groups could not be demonstrated within the motile aeromonads, and significant divergence in related sequences was indicated. This diverse motile group forms the single species Aeromonas hydrophila.     

A semi-continuous cultivation method for <Emphasis Type="Italic">Haematococcus pluvialis</Emphasis> from non-motile cells to motile cells

Non-motile cells of Haematococcus pluvialis grow slowly, whereas motile cells grow fast and divide frequently. Cultivation from non-motile cells to motile cells of H. pluvialis was implemented to promote semi-continuous production. When old cultures which consist of non-motile cells were inoculated in fresh medium with an inoculation amount less than 15%, zoospores were produced in the non-motile cells and developed into motile cells, as the concentration of astaxanthin inducer in the medium was below the threshold value. This process was accomplished within 3 days after inoculation. Furthermore, enhancing KNO₃ content to 1200 mg L^?1 or reducing light intensity to 20 μmol photons m^?2?s^?1 could increase growth during the late culturing period of H. pluvialis and postpone the next round of transformation from motile cells to non-motile cells. A semi-continuous cultivation method for H. pluvialis from non-motile cells to motile cells is proposed in order to regulate the life cycle and promote industrial production. This cultivation mode shortens the inoculum cultivation stage and simplifies the production process of H. pluvialis, showing considerable commercial potential.     

The sugar-specific outer membrane channel ScrY contains functional characteristics of general diffusion pores and substrate-specific porins

Escherichia coli K-12 strain PS1-28-37 carries the multicopy plasmid pPSO28-37 containing a DNA fragment coding for two of the proteins that enable bacteria to utilize sucrose as sole carbon source. One of the different gene products of the plasmid is the outer membrane protein, ScrY. This protein was isolated and purified by chromatography across a gel filtration column. Reconstitution experiments with lipid bilayer membrane demonstrated that ScrY formed ion-permeable channels with properties very similar to those of general diffusion pores of enteric bacteria. The presence of sugars in the aqueous phase led to a dose-dependent block of ion transport through the channel, like the situation found with LamB (maltoporin) of Escherichia coli and Salmonella typhimurium. The binding constants of a variety of different sugars were determined. The stability constant for malto-oligosaccharide binding increased with increasing numbers of glucose residues. Disaccharides generally had a larger binding constant than monosaccharides. The binding of different sugars to ScrY and LamB of E. coli is discussed with respect to the kinetics of sugar movement through the channel.