Interaction of Pseudomonas Bacteriophage 2 with the Slime Polysaccharide and Lipopolysaccharide of Pseudomonas aeruginosa Strain BI

Purified slime polysaccharide B and lipopolysaccharide of Pseudomonas aeruginosa strain BI were shown to possess receptor-like properties in inactivating Pseudomonas phage 2, whereas lipoprotein and glycopeptide fractions were devoid of activity. On a weight basis, slime polysaccharide B was more effective than lipopolysaccharide in inactivating phage. The specificity of the reaction with slime polysaccharide B was indicated by the fact that slime polysaccharide A of P. aeruginosa strain EI failed to inactivate phage 2. Electron micrographs showed phage 2 in typical, tail-first position of attachment on intact cells of strain BI, slime polysaccharide B, and lipopolysaccharide. Tail fibers were discernible during phage attachment.     

Pyocyanin Facilitates Extracellular DNA Binding to Pseudomonas aeruginosa Influencing Cell Surface Properties and Aggregation

Pyocyanin is an electrochemically active metabolite produced by the human pathogen Pseudomonas aeruginosa. It is a recognized virulence factor and is involved in a variety of significant biological activities including gene expression, maintaining fitness of bacterial cells and biofilm formation. It is also recognized as an electron shuttle for bacterial respiration and as an antibacterial and antifungal agent. eDNA has also been demonstrated to be a major component in establishing P. aeruginosa biofilms. In this study we discovered that production of pyocyanin influences the binding of eDNA to P. aeruginosa PA14 cells, mediated through intercalation of pyocyanin with eDNA. P. aeruginosa cell surface properties including cell size (hydrodynamic diameter), hydrophobicity and attractive surface energies were influenced by eDNA in the presence of pyocyanin, affecting physico-chemical interactions and promoting aggregation. A ΔphzA-G PA14 mutant, deficient in pyocynain production, could not bind with eDNA resulting in a reduction in hydrodynamic diameter, a decrease in hydrophobicity, repulsive physico-chemical interactions and reduction in aggregation in comparison to the wildtype strain. Removal of eDNA by DNase I treatment on the PA14 wildtype strain resulted in significant reduction in aggregation, cell surface hydrophobicity and size and an increase in repulsive physico-chemical interactions, similar to the level of the ΔphzA-G mutant. The cell surface properties of the ΔphzA-G mutant were not affected by DNase I treatment. Based on these findings we propose that pyocyanin intercalation with eDNA promotes cell-to-cell interactions in P. aeruginosa cells by influencing their cell surface properties and physico-chemical interactions.     

Hydrophobic and Electrostatic Cell Surface Properties of Thermophilic Dairy Streptococci

Microbial adhesion to hydrocarbons (MATH) and microelectrophoresis were done in 10 mM potassium phosphate solutions to characterize the surfaces of thermophilic dairy streptococci, isolated from pasteurizers. Regardless of whether they were grown (in M17 broth) with lactose, sucrose, or glucose added, strains were relatively hydrophilic (showing low initial removal rates by hexadecane) and slightly negatively charged. A tendency exists for cells grown with sucrose added to be more hydrophilic than cells grown with glucose or lactose added. Also, the lowest isoelectric points, i.e., the pH values for which the zeta potentials are zero, were measured for strains with glucose added to the growth medium. The isoelectric points for the strains were all rather high, between pH 3 and 5, indicative of protein-rich surfaces, although X-ray photoelectron spectroscopy did not measure excessively large amounts of nitrogen on the cell surfaces. Both MATH and microelectrophoresis were done as a function of pH. Maxima in hydrophobicity were observed at certain pH values. Usually these pH values were in the range of the isoelectric points of the cells. Thus it appears that MATH measures an interplay of hydrophobicity and electrostatic interactions. MATH measures solely hydrophobicity only when electrostatic interactions are absent, i.e., close to the isoelectric points of the cells. Considering that these thermophilic streptococci are all rather hydrophilic, a possible pathway to prevent fouling in the pasteurization process might be to render the heat exchanger plates of the pasteurizer more hydrophobic.     

The Non-Specific Binding of Fluorescent-Labeled MiRNAs on Cell Surface by Hydrophobic Interaction

Background

MicroRNAs are small noncoding RNAs about 22 nt long that play key roles in almost all biological processes and diseases. The fluorescent labeling and lipofection are two common methods for changing the levels and locating the position of cellular miRNAs. Despite many studies about the mechanism of DNA/RNA lipofection, little is known about the characteristics, mechanisms and specificity of lipofection of fluorescent-labeled miRNAs.

Methods and Results

Therefore, miRNAs labeled with different fluorescent dyes were transfected into adherent and suspension cells using lipofection reagent. Then, the non-specific binding and its mechanism were investigated by flow cytometer and laser confocal microscopy. The results showed that miRNAs labeled with Cy5 (cyanine fluorescent dye) could firmly bind to the surface of adherent cells (Hela) and suspended cells (K562) even without lipofection reagent. The binding of miRNAs labeled with FAM (carboxyl fluorescein) to K562 cells was obvious, but it was not significant in Hela cells. After lipofectamine reagent was added, most of the fluorescently labeled miRNAs binding to the surface of Hela cells were transfected into intra-cell because of the high transfection efficiency, however, most of them were still binding to the surface of K562 cells. Moreover, the high-salt buffer which could destroy the electrostatic interactions did not affect the above-mentioned non-specific binding, but the organic solvent which could destroy the hydrophobic interactions eliminated it.

Conclusions

These results implied that the fluorescent-labeled miRNAs could non-specifically bind to the cell surface by hydrophobic interaction. It would lead to significant errors in the estimation of transfection efficiency only according to the cellular fluorescence intensity. Therefore, other methods to evaluate the transfection efficiency and more appropriate fluorescent dyes should be used according to the cell types for the accuracy of results.     

Interaction of Pseudomonas solanacearum Lipopolysaccharide and Extracellular Polysaccharide with Agglutinin from Potato Tubers

In vitro binding assays were used to study the possible role of a cell wall agglutinin in the attachment to plant cell walls of avirulent strains of the wilt pathogen, Pseudomonas solanacearum. In a nitrocellulose filter assay, radioactively labeled lipopolysaccharide (LPS) from the virulent strain, K60, and the avirulent strain, B1, and extracellular polysaccharide (EPS) from K60 were bound quantitatively by the agglutinin extracted from Katahdin potato tubers. The LPS from B1 had significantly greater agglutinin-binding affinity than that from K60 but not after treatment with deoxycholate, which improved solubility. Highly purified chitotetraose did not inhibit binding of K60 LPS to agglutinin, but binding was inhibited by EPS as well as by diverse anionic polymers (DNA, dextran sulfate, xanthan). Binding of agglutinin to EPS and LPS was inhibited at ionic strengths greater than 0.03 and 0.15 M, respectively. It was concluded that electrostatic charge-charge interactions could account for binding of LPS and EPS to potato agglutinin.     

Surface hydrophobicity and dispersal of Pseudomonas aeruginosa from biofilms

A novel method of cell culture was employed to control the growth-rate of bacterial biofilms [1]. Cell-surface hydrophobicity increased progressively with growth rate for planktonic, chemostatgrown Pseudomonas aeruginosa and also for cells, resuspended from the biofilms. Dependence of surface hydrophobicity upon growth rate was greater for the planktonic cells. Newly-formed daughter cells, shed from the biofilms, were in all cases more hydrophilic than their adherent counterparts and demonstrated only slight growth rate dependency for this property.     

Purification and Properties of Dihydrostreptomyein-Phosphorylating Enzyme from Pseudomonas aeruginosa

The distribution of the dihydrostreptomycin (DHSM)-phosphorylating enzyme was investigated using DHSM-resistant strains of Pseudomonas aeruginosa, indicating that this enzyme was demonstrated from all of 7 DHSM-resistant strains examined but not from a DHSM-sensitive one. The DHSM-phosphorylating enzyme was isolated from P. aeruginosa TI-13 and purified about 205-fold using Sephadex G-75 and DEAE-Sephadex A-50 column chromatography. The optimal pH for the DHSM-inactivation was around 10.0, and both adenosinetriphosphate (ATP) and Mg⁺⁺ were required for the inactivating reaction. It was found that this enzyme inactivated only DHSM but not other aminoglycosidic antibiotics such as kanamycin, aminodeoxykanamycin, neomycin, paromomycin, lividomycin and gentamicin.     

Properties and localization of N-acetylglutamate deacetylase from Pseudomonas aeruginosa

The N-acetylglutamate deacetylase (EC 3.5.1.-) from Pseudomonas aeruginosa, strain PAO1, was purified 15,000-fold to electrophoretic homogeneity. The enzyme was distinct from acetylornithinase and formylglutamate hydrolase. Its molecular weight was estimated to be 90,000 by gel filtration and by sedimentation in sucrose gradients. Electrophoresis in sodium-dodecyl sulphate gels gave a single band corresponding to a molecular weight of 44,000. N-Acetylglutamate deacetylase was L-specific and showed no peptidase activity. Among 17 N-acetyl-L-amino acids tested as substrates, N-acetyl-L-glutamine, N-acetyl-L-methionine and N-acetylglycine were hydrolysed at 20% of the rate of N-acetyl-L-glutamate whereas other N-acetyl-L-amino acids were deacetylated at a rate of less than 10%. The catalytic activity depended on Co2+. The Km of the enzyme with respect to N-acetylglutamate was 1.43 mM. Preparation of spheroplasts with lysozyme in the presence of 0.2 M-MgCl2 led to the release of 80% of the enzyme activity from the cells, indicating the periplasmic localization of N-acetylglutamate deacetylase. Its localization in the periplasmic space explains the inability of P. aeruginosa argA mutants to grow on N-acetylglutamate, which is utilized by the wild-type as a carbon and nitrogen source.     

Properties of an R Factor from Pseudomonas aeruginosa

An R factor from Pseudomonas aeruginosa, which confers resistance to penicillins, kanamycin, and tetracycline, was studied in Escherichia coli K-12. The R factor could coexist with F-like or I-like plasmids and therefore constituted a novel compatibility group. The R factor was transferable from E. coli to bacterial genera outside the Enterobacteriaceae (Pseudomonas and members of the Rhizobiaceae) to which transfer of F-like and I-like plasmids could not be demonstrated.     

Effects of Hydrophobic and Electrostatic Cell Surface Properties of Bacteria on Feeding Rates of Heterotrophic Nanoflagellates

The influence of cell surface hydrophobicity and electrostatic charge of bacteria on grazing rates of three common species of interception-feeding nanoflagellates was examined. The hydrophobicity of bacteria isolated from freshwater plankton was assessed by using two different methods (bacterial adhesion to hydrocarbon and hydrophobic interaction chromatography). The electrostatic charge of the cell surface (measured as zeta potential) was analyzed by microelectrophoresis. Bacterial ingestion rates were determined by enumerating bacteria in food vacuoles by immunofluorescence labelling via strain-specific antibodies. Feeding rates varied about twofold for each flagellate species but showed no significant dependence on prey hydrophobicity or surface charge. Further evidence was provided by an experiment involving flagellate grazing on complex bacterial communities in a two-stage continuous culture system. The hydrophobicity values of bacteria that survived protozoan grazing were variable, but the bacteria did not tend to become more hydrophilic. We concluded that variability in bacterial cell hydrophobicity and variability in surface charge do not severely affect uptake rates of suspended bacteria or food selection by interception-feeding flagellates.     

Surface action of gentamicin on Pseudomonas aeruginosa.

The mode of action of gentamicin has traditionally been considered to be at the 30S ribosomal level. However, the inhibition of bacterial protein synthesis alone appears to be insufficient to entirely explain the bactericidal effects. Bacteriolysis is also mediated through perturbation of the cell surface by gentamicin (J.L. Kadurugamuwa, J.S. Lam, and T.J. Beveridge, Antimicrob. Agents Chemother. 37:715-721, 1993). In order to separate the surface effect from protein synthesis in Pseudomonas aeruginosa PAO1, we chemically conjugated bovine serum albumin (BSA) to gentamicin, making the antibiotic too large to penetrate through the cell envelope to interact with the ribosomes of the cytoplasm. Furthermore, this BSA-gentamicin conjugate was also used to coat colloidal gold particles as a probe for electron microscopy to study the surface effect during antibiotic exposure. High-performance liquid chromatography confirmed the conjugation of the protein to the antibiotic. The conjugated gentamicin and BSA retained bactericidal activity and inhibited protein synthesis on isolated ribosomes in vitro but not on intact cells in vivo because of its exclusion from the cytoplasm. When reacted against the bacteria, numerous gentamicin-BSA-gold particles were clearly seen on the cell surfaces of whole mounts and thin sections of cells, while the cytoplasm was devoid of such particles. Disruption of the cell envelope was also observed since gentamicin-BSA and gentamicin-BSA-gold destabilized the outer membrane, evolved outer membrane blebs and vesicles, and formed holes in the cell surface. The morphological evidence suggests that the initial binding of the antibiotic disrupts the packing order of lipopolysaccharide of the outer membrane, which ultimately forms holes in the cell envelope and can lead to cell lysis. It is apparent that gentamicin has two potentially lethal effects on gram-negative cells, that resulting from inhibition of protein synthesis and that resulting from surface perturbation; the two effects in concert make aminoglycoside drugs particularly effective antibiotics.     

Proteins Released from Cell Envelopes of Pseudomonas aeruginosa on Exposure to Ethylenediaminetetraacetate: Comparison with Dimethylformamide-Extractable Proteins

Isolated cell envelopes of Pseudomonas aeruginosa were treated with N,N'-dimethylformamide (DMF) or with ethylenediaminetetraacetate (EDTA). DMF solubilized 73% of the dry weight of the cell envelope, 76% of the protein, 78% of the carbohydrate, and 76% of the phosphorus. Electron microscopy showed that DMF caused extensive alterations in the appearance of the cell envelope with blebs and bleblike vesicles predominating. After incubation with EDTA, the cell envelopes appeared to have lost material, but still retained the cell-like morphology. Analysis of DMF-solubilized proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed 16 protein bands. There were three major proteins that predominated, however, with molecular masses of 43,000 (protein A), 16,500 (protein B), and 72,000 daltons (protein C). Evidence is presented that protein A and protein B are glycoproteins. Gel electrophoresis of EDTA-solubilized material revealed that a number of proteins were released from the cell envelope. However, electrophoresis of an isolated protein-lipopolysaccharide complex released by EDTA showed that protein A and protein B were the major protein components of this complex. These data suggest that protein A and protein B are components of the outer cell wall membrane of P. aeruginosa. There is suggestive evidence that these proteins may play a role in maintaining the structural integrity of the cell envelope. Whether these proteins also have enzymatic activity could not be discerned from the present study, although it is possible that they may be associated with the terminal stages of lipopolysaccharide synthesis.     

Effect of Carbenicillin on Pseudomonas aeruginosa

The activity of carbenicillin against 200 strains of Pseudomonas aeruginosa was measured by a quantitative agar dilution method. Minimal inhibitory concentrations (M.I.C.''s) for five graded inocula were measured in terms of complete inhibition (CI) and reduced growth (RG). The M.I.C. decreased progressively as inocula were reduced, median values for the 200 strains ranging from 100 to 37.5 μg. per ml. by the CI criterion, and from 75 to 25 μg. per ml. by the RG definition. Ratios of M.I.C. obtained for large and small inocula were usually small. Identical M.I.C.''s by both CI and RG criteria were most often obtained when the inoculum for the RG criterion was 1 or 2 logs higher than that for complete inhibition.Population analysis of 15 strains of Ps. aeruginosa showed that one specific drug concentration usually caused a sharp drop in proportion of viable cells, ranging from 3 to 5 logs. None of the populations were completely non-viable even at 150 μg. per ml. There was evidence that the viability of different-sized populations was reduced disproportionately by carbenicillin.Carbenicillin 300 μg. per ml. exerted appreciable bactericidal effect against nine of 15 strains of Ps. aeruginosa after a 24-hour contact period; after only six hours the bactericidal effect was very small.Quantitative sensitivity measurements for carbenicillin should include M.I.C. values for both CI and RG criteria, using a range of inocula for testing. Such M.I.C. values may well be useful in monitoring carbenicillin therapy of tissue infections.     

Differential Lipopolysaccharide Core Capping Leads to Quantitative and Correlated Modifications of Mechanical and Structural Properties in Pseudomonas aeruginosa Biofilms

Bacterial biofilms are responsible for the majority of all microbial infections and have profound impact on industrial and geochemical processes. While many studies documented phenotypic differentiation and gene regulation of biofilms, the importance of their structural and mechanical properties is poorly understood. Here we investigate how changes in lipopolysaccharide (LPS) core capping in Pseudomonas aeruginosa affect biofilm structure through modification of adhesive, cohesive, and viscoelastic properties at an early stage of biofilm development. Microbead force spectroscopy and atomic force microscopy were used to characterize P. aeruginosa biofilm interactions with either glass substrata or bacterial lawns. Using isogenic migA, wapR, and rmlC mutants with defined LPS characteristics, we observed significant changes in cell mechanical properties among these strains compared to wild-type strain PAO1. Specifically, truncation of core oligosaccharides enhanced both adhesive and cohesive forces by up to 10-fold, whereas changes in instantaneous elasticity were correlated with the presence of O antigen. Using confocal laser scanning microscopy to quantify biofilm structural changes with respect to differences in LPS core capping, we observed that textural parameters varied with adhesion or the inverse of cohesion, while areal and volumetric parameters were linked to adhesion, cohesion, or the balance between them. In conclusion, this report demonstrated for the first time that changes in LPS expression resulted in quantifiable cellular mechanical changes that were correlated with structural changes in bacterial biofilms. Thus, the interplay between architectural and functional properties may be an important contributor to bacterial community survival.Biofilms are sessile microbial communities growing on a surface or at an interface, often enmeshed in polymeric substances. Being the predominant mode of microbial growth in nature, bacterial biofilms are particularly problematic in the context of human health, accounting for up to 80% of all bacterial infections. In industrial processes, bacterial biofilms cause corrosion and biofouling, resulting in considerable loss of productivity. In the natural environment, biofilms play a role in modulating worldwide geochemical cycles. Given the impact of biofilms in these diverse areas, the need for developing effective strategies to control them is of paramount importance. Since bacterial cell surface structures are convenient targets for control agents, their roles in influencing biofilm function and architecture warrant in-depth investigations. To date, most studies of biofilms have focused on genetic regulation, phenotypic differentiation and their contribution to antibiotic resistance. In contrast, the mechanical and structural properties that link the genotypes to phenotypes of bacterial biofilms are not well understood and rarely studied in a quantitative and correlated manner.Pseudomonas aeruginosa is a gram-negative opportunistic pathogen implicated in serious infections in patients with cystic fibrosis and immunocompromised patients. This bacterium has a relatively large genome (6.3 Mb) consistent with its propensity to utilize versatile metabolic pathways, thereby developing antibiotic resistance and producing an arsenal of virulence factors, including lipopolysaccharide (LPS) present on the cell surface. LPS is localized in the outer leaflet of the outer membrane of all gram-negative bacteria, forming the first point of contact between the bacterial cell and any surface that it colonizes or therapeutic agents. The LPS of P. aeruginosa consists of three regions: lipid A, core oligosaccharide (core OS), and O antigen. The O antigen is synthesized as two distinct forms with overlapping pathways: the shorter A-band homopolymer is the so-called “common polysaccharide antigen” among this species and consists of repeating d-rhamnose (d-Rha) subunits, while the longer B-band heteropolymer is composed of repeating tri- to pentasaccharide subunits that vary among the 20 serotypes of P. aeruginosa (42). The core OS is conceptually divided into the highly conserved inner core and the more variable outer core. Depending on the linkage of l-rhamnose (l-Rha) with two distinct d-glucose (d-Glc) residues, two main glycoforms of the core OS exist (see Fig. ​Fig.1A).1A). In the “capped” glycoform, l-Rha is α-1,3 linked to a d-Glc and acts as the acceptor molecule for O antigen, resulting in the production of smooth LPS. In the “uncapped” glycoform, l-Rha is α-1,6 linked to a different d-Glc and is not substituted with O antigen, resulting in the production of rough LPS (39). In addition, the presence or absence of the α-1,6 linked l-Rha substituted with a terminal d-Glc gives rise to the so-called intact or truncated outer core, respectively. The functional significance of this terminal glucose is unclear at present, although a role in host cell binding has been proposed (57).Open in a separate windowFIG. 1.Comparison of LPSs from Pseudomonas aeruginosa wild-type strain PAO1 and mutant strains with LPS core variants. (A) Schematic diagram illustrating the chemical structures of smooth LPS and rough LPS. The gray and black arrows point to the position of outer core truncation and position of O-antigen capping, respectively. (B) Silver-stained SDS-polyacrylamide gels illustrating LPS profiles of planktonic and biofilm cells. The two gray arrows and the black arrows point to the position of O antigen and position of core-plus-one entities, respectively. Planktonic cells (lanes 1 to 4) and biofilm cells (lanes 5 to 8) of strain PAO1 (P), migA mutant (M), wapR mutant (W), and rmlC mutant (R) are shown.Mechanical processes that are important in the biofilm life cycle include bacterial adhesion, cohesion, and viscoelasticity. Bacterial adhesion is a prerequisite for surface colonization and the most important functional determinant in the early stages of biofilm development. Accurate measurement of adhesion is therefore essential for monitoring the tendency of bacteria to attach to surfaces and to switch from a planktonic lifestyle to a biofilm lifestyle. Data accumulated in previous studies suggest that LPS is involved in bacterial cell adhesion to both abiotic (2, 8, 20, 32, 35, 54, 56) and biotic (17, 38, 49, 56, 57) surfaces. Moreover, environmental factors, such as growth temperature, pH, ionic strength, nutrient availability, and oxygen levels, may influence cell adhesion via modification of LPS expression and conformation (16, 36, 46, 47, 53). The effect of LPS on bacterial adhesion to various types of surfaces apparently involves distinct and complex mechanisms that remain to be elucidated.Bacterial cohesion, herein defined as cell-to-cell adherence, is crucial to the formation of microbial flocs and the growth and detachment of established bacterial biofilms. Quantification of cohesion is important for understanding biofilm biology, and such data are crucial for modeling and forecasting biofilm development so that better control strategies can be developed (55). Previous studies of biofilm cohesiveness have characterized it as highly stratified (3, 4, 18, 43), influenced by ionic strength (14, 34), proportional to shear rate (37), and often variable over 3 orders of magnitude (40, 50). Although an earlier study by Spiers and Rainey (48) provided semiquantitative measurements of the role of LPS on bacterial cohesion within a biofilm, a truly quantitative account of the effect of LPS on biofilm cohesion has not been demonstrated.Bacterial viscoelasticity refers to the combined liquid-like and solid-like characteristics in the behavior of polymeric systems such that when deformed under stress, their strain can increase over time (i.e., creep) and their original shape may be only partially restored upon stress relief (19). Although earlier reports suggested that LPS modulates bacterial cell compressibility and helps prevent catastrophic structural failure due to mechanical stress (1, 52), no direct physical evidence of its involvement in these processes has yet been presented. Therefore, monitoring biofilm viscoelasticity is crucial for demonstrating how well biofilms resist stresses, due to, for instance, fluid shear and antimicrobial peptides (5, 6). To date, quantitative data on how LPS affects viscoelastic properties of biofilms are lacking, and existing studies have merely focused on elasticity measurements (7, 52). Recently, our group has developed an atomic force microscopy (AFM)-based technique called microbead force spectroscopy (MBFS) to measure the adhesive forces and viscoelastic properties of cells within bacterial biofilms (28). In this study, we expand the application of this MBFS method to measure cohesive forces between cells at an early stage of biofilm development.Biofilm structure refers to the distribution of biomass or carbonaceous materials associated with cells (including all viable and nonviable cells and their extracellular polymeric substances) within the space occupied by a biofilm. It is known to be very heterogeneous and highly stratified, typically composed of a cohesive basal layer and a relatively fragile top layer (15, 18, 43). Using confocal laser scanning microscopy (CLSM), biofilm structure can be quantitatively described in terms of textural and volumetric parameters (11, 29). Textural parameters characterize the pattern of cell clusters and interstitial voids in a biofilm, whereas volumetric parameters describe the morphological characteristics of bacterial biofilms in three dimensions (3-D) (11). Biomass distribution is affected by the surrounding environment and may reflect fundamental processes occurring within biofilms, such as nutrient transport, accumulation rate, microbial physiology, and mechanical behavior (29). Therefore, quantifying biofilm structure by CLSM will allow us to understand the underlying processes and the relationship between biofilm architecture and behavior (15).To examine the effects of differential LPS core capping on the mechanical properties of early biofilms (here defined as confluent bacterial lawns that have just begun to develop into full-fledged biofilms) and the structural properties of mature biofilms, we compare P. aeruginosa wild-type strain PAO1 with those of its isogenic migA, wapR, and rmlC mutant strains with defects in the respective genes affecting LPS core biosynthesis (22, 31, 39, 41). The migA gene (PA0705) encodes the putative α-1,6-rhamnosyltransferase necessary for the attachment of the terminal d-Glc to the outer core (39). The wapR gene (PA5000) encodes the putative α-1,3-rhamnosyltransferase crucial to the capping of the core with O antigen (39). The rmlC gene (PA5164) encodes a dTDP-4-dehydrorhamnose 3,5-epimerase essential in the biosynthesis of TDP-l-Rha, which is the precursor for the l-Rha in the LPS core (41). Defects in migA, wapR, and rmlC mutants result in the expression of different LPS phenotypes, including a truncated outer core and/or a lack of capping by O antigen (Table ​(Table1).1). In this study, we test the hypothesis that LPS contributes to biofilm function and architecture through modulation of cellular mechanics and microcolony structures, thereby contributing to bacterial community survival. By correlating quantitative mechanical changes in early P. aeruginosa biofilms and structural changes in mature biofilms due to differences in LPS chemistry, we aim to elucidate how the properties of these important bacterial cell surface molecules can alter the physical nature of biofilms.

TABLE 1.

Pseudomonas aeruginosa strains used in this study

Effect of hemolysin from Pseudomonas aeruginosa on cell cultures]

Hemolysin of Pseudomonas aeruginosa has a cytopathic action on blood and tissue culture cells. Lysis and disintegration of the architecture of the cell involving membrane and cytoplasm were demonstrated by morphological changes. The hemolytic activity of hemolysin is inhibited by normal sera and by albumin; inhibition is also observed in the action of hemolysin on K.B. cells, but this inhibition is not complete. The hemolytic and cytopathic actions are explained by assuming that they alter the molecular architecture of the membranes. The variability may relate to the differing availability of reactive sites on the cells, or indicate that the two activities are associated with two different enzymes.     

Lipopolysaccharide changes and cytoplasmic polyphosphate granule accumulation in Pseudomonas aeruginosa during growth on hexadecane

Pseudomonas aeruginosa ATCC 9027 grew on 0.5% (v/v) hexadecane as a sole carbon source in a chemically defined medium which required the addition of Fe3+ and Ca2+. There was a variable and extended lag period before an active growth rate was attained. Visible light microscopic evidence revealed that the bacteria did not adhere to hexadecane droplets suggesting the absence of a bioemulsifier. When compared with glucose-grown cells, hexadecane-grown cells produced 75% less lipopolysaccharide (on a total protein basis); this lipopolysaccharide contained 30-40% less carbohydrate, yet 50-75% more 2-keto-3-deoxyoctonate. These chemical changes made the cell surface appear more hydrophobic when tested in a biphasic hydrophobicity index system. Electron microscopy of thin sections and freeze etchings revealed hexadecane-grown cells contained granules which were judged to be polyphosphate by energy dispersive X-ray analysis. There was no apparent major morphological envelope alteration within the two cell types.