Laboratory studies on adhesion of microalgae to hard substrates

Adhesion of Chlorella vulgaris(chlorophyceae), Nitzschia amphibia(bacillariophceae) and Chroococcus minutus(cyanobacteria) to hydrophobic (perspex, titanium and stainless steel 316-L), hydrophilic (glass) and toxic (copper, aluminium brass and admiralty brass) substrata were studied in the laboratory. The influence of surface wettability, surface roughness, pH of the medium, culture age, culture density, cell viability and presence of organic and bacterial films on the adhesion of Nitzschia amphibia was also studied using titanium, stainless steel and glass surfaces. All three organisms attached more on titanium and stainless steel and less on copper and its alloys. The attachment varied significantly with respect to exposure time and different materials. The attachment was higher on rough surfaces when compared to smooth surfaces. Attachment was higher on pH 7 and above. The presence of organic film increased the attachment significantly when compared to control. The number of attached cells was found to be directly proportional to the culture density. Attachment by log phase cells was significantly higher when compared to stationary phase cells. Live cells attached more when compared to heat killed and formalin killed cells. Bacterial films of Pseudomonas putida increased the algal attachment significantly. %     

Control of microbial attachment by inhibition of ATP and ATP‐mediated autoinducer‐2

In this study, 2,4‐dinitrophenol (DNP), a typical chemical uncoupler, was employed to investigate the possible roles of ATP and autoinducer‐2 (AI‐2) of suspended microorganisms in attachment onto nylon membrane and glass slide surfaces. Results showed that DNP could disrupt ATP synthesis, subsequently led to a reduced production of AI‐2 which is a common signaling molecule for cellular communication. Attachment of suspended microorganisms exposed to DNP was significantly suppressed as compared to microorganisms without contact with DNP. These suggest that an energized state of suspended microorganisms would favor microbial attachment to both nylon membrane and glass slide surfaces. The extent of microbial attachment was found to be positively related to the AI‐2 content of microorganisms. This study offers insights into the control of biofouling by preventing initial microbial attachment through inhibition of energy metabolism. Biotechnol. Bioeng. 2010;107: 31–36. © 2010 Wiley Periodicals, Inc.     

Entamoeba histolytica and Giardia lamblia: effects of cysteine and oxygen tension on trophozoite attachment to glass and survival in culture media

Attachment of Entamoeba histolytica and of Giardia lamblia trophozoites to glass was monitored during the culture cycle. Attachment of each parasite was greatest during the exponential phase of axenic growth. The effects of l-cysteine upon the kinetics of attachment of trophozoites to glass were determined quantitatively. Attachment in complex growth media required cysteine, even under N₂, atmosphere. With cysteine, the rates of attachment were greatest for the first 2 hr, then continued more slowly. The numbers of attached trophozoites decreased immediately upon exposure to medium without cysteine. The role of cysteine in protecting trophozoites of both species from the lethal effects of oxygen was assessed using clonal growth in agar or agarose medium to determine viability following exposure to varying oxygen tensions in liquid medium. Cysteine was required for viability of trophozoites. Without cysteine, decreasing the oxygen tension prolonged survival. Under increased oxygen tension, cysteine delayed the onset of exponential killing. Although it has no thiol reducing group, l-cystine similarly protected E. histolytica.     

Characterisation of Curli Production, Cell Surface Hydrophobicity, Autoaggregation and Attachment Behaviour of Escherichia coli O157

Escherichia coli O157 are an important group of foodborne pathogens with the ability to attach to materials commonly used in food processing environments such as slightly hydrophilic stainless steel. The aim of this study was to characterise six E. coli isolates, including five E. coli O157, for curli production, autoaggregation, hydrophobicity and attachment to highly hydrophilic glass and hydrophobic Teflon^®. Curli production and autoaggregation were determined using absorbance assays; hydrophobicity by bacterial adherence to hydrocarbons, hydrophobic interaction chromatography and contact angle measurements; and attachment using epifluorescence microscopy. Curli production varied between strains and for some strains correlated with autoaggregation. Curli production correlated with decreased hydrophobicity for two strains. Four of the six isolates increased attachment to glass, but decreased attachment to Teflon^® with increased curli production. In contrast, one of the six isolates decreased attachment to glass, but increased attachment to Teflon^® with increasing curli production. Curli production by the remaining isolate did not correlate with hydrophobicity or attachment. Attachment of some E. coli, including E. coli O157, to abiotic surfaces may be influenced by curli production, autoaggregation and hydrophobicity. However, for other strains, a variety of factors may be of greater influence on these properties and ability to attach to abiotic surfaces. This study highlights the complexity of bacterial surface properties and their relationship with bacterial attachment.     

Factors affecting the irreversible attachment of Pseudomonas aeruginosa to stainless steel

To better understand the interaction between bacteria and surfaces, we studied the irreversible attachment of Pseudomonas aeruginosa to a common surfacing material. When brought into contact with the steel, cells began to attach in less than 1 min and the number adhering increased with time. An important physiological variable in attachment was cell motility since adherence decreased at least 90% when flagella were removed by blending. This treatment was shown to be effective because it caused motility loss and not because it removed a structure necessary for adherence. Cell viability was less important since adherence decreased only 50% when the number of viable cells was reduced 4.7 logs by heating or formaldehyde treatment. Significant environmental variables included turbulence and ionic strength. Attachment of motile cells was reduced 90% by agitation, although agitation had little effect on adherence of nonmotile cells. Both motile and nonmotile cells adhered poorly in distilled water with attachment increasing as CaCl2 or NaCl concentration increased to 10 mM. At 100 mM, attachment decreased. Viable cells, both motile and nonmotile, adhered best at a pH of 7 to 8, whereas nonviable cells attached most rapidly at a low pH.     

Interaction of Pseudomonas solanacearum with Suspension-Cultured Tobacco Cells and Tobacco Leaf Cell Walls In Vitro

Attachment of radiolabeled Pseudomonas solanacearum cells to suspension-cultured tobacco cells and tobacco leaf cell walls was measured in vitro by a filtration technique that allowed separation of attached and unattached bacteria. An avirulent strain (B1) attached more rapidly to suspension-cultured cells than did the virulent parent strain (K60), and B1 attachment was less sensitive to inhibition by high ionic strength than was K60. Attachment of B1 bacteria to suspension-cultured cells and to leaf cell walls was comparable (50 to 70%), but only a small proportion (10 to 20%) of K60 bacteria attached to leaf cell walls under optimal conditions. With high bacterial populations (10⁸ bacteria per ml), attachment of K60 to suspension-cultured cells was greatly reduced. Attachment of both strains was completely inhibited by pretreating bacterial cells with heat (41°C) or azide and was partially inhibited by EDTA and kanamycin. The mechanism of attachment is not known, but ionic forces may be involved.     

Attachment of the flagellate Giardia lamblia: role of reducing agents, serum, temperature, and ionic composition.

The flagellated protozoan Giardia lamblia has been grown only in highly complex media under reduced oxygen tension. Therefore, the organic and physiological requirements for in vitro attachment and short-term (12-h) survival of this organism were determined. In defined maintenance media, a thiol reducing agent (e.g., cysteine) was absolutely required for attachment and survival of this aerotolerant anaerobe. The crude bovine serum Cohn III fraction greatly stimulated attachment and survival. Attachment was decreased at a reduced temperature (24 degrees C as compared with 35.5 degrees C) and absent at 12 degrees C or below. Attachment and survival were strongly dependent upon pH and ionic strength, with optima at pH 6.85 to 7.0 and 200 to 300 mosmol/kg. Sodium chloride was better tolerated than KC1. Reduction of Ca2+ and Mg2+ to below 10(-8) M did not significantly affect attachment.     

Col V plasmids and the resistance of Escherichia coli to divalent copper ions

Free organisms of both plasmid-free and plasmid-carrying strains of Escherichia coli were killed by incubation in water containing low levels of cupric ions. Sensitivity was temperature-dependent with killing being more marked at 20° or 25°C than at 10° or 15°C. In contrast to the effects of other inhibitors from natural waters (which affect free Col V⁺organisms more than Col^-ones), free Col^-and Col V⁺organisms were equally sensitive to kill by Cu²⁺. Attachment to glass beads essentially abolished sensitivity to cupric ions with full survival after exposure to 15 μ g/ml. This applied to both p⁺and p^-strains but attachment would have more effect on the survival of p⁺organisms in natural waters because some plasmids markedly enhance attachment.     

Attachment of Mycoplasma pulmonis to rat and mouse synovial cells cultured in vitro

The attachment of Mycoplasma pulmonis m53 organisms to mouse and rat synovial cells was examined by using the organisms and the synovial cells treated in various ways. M. pulmonis treated with trypsin attached to the synovial cells, but the organisms treated with pronase, formaldehyde, glutaraldehyde, or heat did not. These findings suggest that the sites for binding M. pulmonis to the mouse and rat synovial cells are of polypeptide nature. Treatment of M. pulmonis with sialic acid and treatment of the synovial cell sheets with neuraminidase did not affect the attachment. The synovial cell surface for receptors M. pulmonis organisms would be different from those on respiratory cells or erythrocytes for M. pneumoniae or M. gallisepticum. Even nonviable organisms and M. pulmonis membranes attached to the mouse or rat synovial cells. The nature of the receptor of mouse synovial cells would be different from that of rat cells, since rat cells were affected by treatment with formaldehyde or glutaraldehyde, but mouse cells were not.     

Possible association of segregated lipid domains of Mycoplasma gallisepticum membranes with cell resistance to osmotic lysis.

Freeze-fracturing of cholesterol-rich Mycoplasma gallisepticum membranes from cells grown in a medium containing horse serum revealed particle-free patches. The patches appeared in cells quenched from either 4 or 37 degrees C. Particle-free patches also occurred in membranes of cells grown in a serum-free medium supplemented with egg-phosphatidylcholine but not in membranes of cells grown with dioleoylphosphatidylcholine. The appearance of particle-free patches was attributed to the presence of disaturated phosphatidylcholine (PC) molecules in M. gallisepticum membranes, which were synthesized by the insertion of a saturated fatty acid at position 2 of lysophosphatidylcholine derived from exogenous PC present in the growth medium. Consequences of the synthesis of the disaturated PC also included a decrease in osmotic fragility and the ability of the cells to be permeated by K+. Electron paramagnetic resonance and fluorescence polarization measurements revealed that the fluidity of the lipid domain in the protein-rich M. gallisepticum membranes was almost identical to that of an aqueous dispersion of M. gallisepticum membrane lipids. Furthermore, the electron paramagnetic resonance spectra of the membranes were single-component spectra showing no indication of immobilized regions. The possibility that the osmotic resistance of M. gallisepticum cells is associated with the particle-free patches rather than with a restricted membrane fluidity caused by membrane proteins is discussed.     

Germination of Phyllosticta ampelicidaPycnidiospores: Prerequisite of Adhesion to the Substratum and the Relationship of Substratum Wettability

Pycnidiospores of Phyllosticta ampelicida, the causal agent of black rot of grape, were found to germinate only on substrata on which they were firmly attached. Such surfaces were poorly wettable and had advancing contact angles (straight thetaa) formed by a water drop of >80°, e.g., grape leaf, polystyrene, Teflon, polycarbonate, collodion, and glass treated with the silanes n-octadecyltrichlorosilane, dimethyldichlorosilane, or diphenyldichlorosilane. When pycnidiospores were deposited on more wettable surfaces they did not attach firmly and did not germinate. Such highly wettable surfaces had straight thetaa 相似文献   

Virulence plasmid-associated adhesion of Escherichia coli and its significance for chlorine resistance

Introduction of the ColV, I-K94 virulence plasmid into strains of Escherichia coli led (for four out of five strains tested) to a marked increase in the ability of organisms to adhere to glass beads. For strain 1829, the plasmid led to increased attachment to other materials including sand, agar, agarose, chitin and cellulose. The increased adhesion to glass beads was due to the presence of the plasmid and not to its introduction into a variant with altered adhesive properties. The plasmid-encoded VmpA protein did not appear to be necessary for the ColV, I-K94-promoted adhesion but adhesion was absolutely dependent on the presence of derepressed levels of transfer components in the ColV+ strains and partially dependent on the presence of colicin components. The extent of the plasmid-promoted adhesion was greatest for organisms grown at 30 degrees, 37 degrees or 42 decrees C and adhesion was almost abolished by growth at 21 degrees or 25 degrees C; this finding is in accord with transfer and colicin components being involved in adhesion. Of several other plasmids tested for their effects on adhesion, those with derepressed transfer properties showed a marked effect as did the RI resistance plasmid. Because of the ease of handling glass bead-attached organisms, such preparations were used as a model for studying the relevance of attachment to the resistance of E. coli to chlorination in the water purification process. Organisms of 1829 ColV, I-K94, attached to glass beads, were more resistant to damage and killing by chlorine than were unattached organisms. Three findings suggest that such chlorine resistance may be significant for survival during water chlorination. Firstly, ColV, I-K94+ bacteria became attached if incubated in sewage effluent with glass beads at 20 degrees C. Secondly, ColV+ organisms already attached to glass beads maintained their attachment during 24 h incubation in effluent at 20 degrees C and thirdly such effluent incubated organisms remained chlorine resistant provided that they retained their attachment.     

Studies on fouling by the freshwater mussel limnoperna fortunei and the antifouling effects of low energy surfaces

Attachment of the freshwater mussel, Limnoperna fortunei, was tested using non‐treated surfaces, viz. glass, nylon, rubber, silicone and Teflon, together with glass surfaces modified with nine kinds of silane coupling agents. Among the surfaces tested, the mussel avoided attaching to Teflon, silicone, and glass modified with 3‐bromopropyltrimethoxysilane or 3,3,3‐(trifluo‐ropropyl)‐trimethoxysilane. With respect to the relationship between the percentage attachment and the surface free energy (sfe) of the substrates, it was found that attachment was considerably reduced on the substrates which exhibited relatively low sfe, as above. The mean number of secreted byssuses per attaching mussel also decreased with decreasing substrate sfe. Furthermore, when the sfe was divided into the dispersion and polar components, the percentage mussel attachment was related to the polar component. These results suggest that effective antifouling towards L. fortunei is achieved on substrates with a low sfe polar component.     

Nitrate reductase and the membrane composition of pleiotropic chlorate resistant mutants of Escherichia coli K-12.

Attachment of rat hepatocytes to collagen but not to fibronectin substrata was efficiently inhibited by antibodies against the hepatocyte surface. Further analyses of this inhibition suggested that hepatocyte attachment to collagen involves cell surface antigens which are not identical to membrane bound fibronectin or collagen.Rabbit antibodies against rat fibronectin inhibited hepatocyte attachment to rat fibronectin but not to collagen or rabbit fibronectin. After plasmin digestion of fibronectin, peptides were isolated that lacked affinity for collagen but could serve as a substratum for hepatocyte attachment. These results suggested that attachment to fibronectin does not involve membrane bound fibronectin or collagen.     

Localization of an immunodominant 64kDa lipoprotein (LP 64) in the membrane of Mycoplasma gallisepticum and its role in cytadherence

A 64 kDa lipoprotein (LP 64) haemagglutinin (pI 4.9-5.0) was isolated from the membrane of Mycoplasma gallisepticum. Triton X-114 phase partitioning has demonstrated that the hydrophobic nature of this haemagglutinin is due to a lipid portion of the molecule. Autoradiography of [3H]-palmitate-labelled M. gallisepticum revealed the presence of several additional lipoproteins. Immunoelectron microscopy demonstrated the localization of LP 64 to the base of the terminal structure. Densitometric scans of stained polyacrylamide gels of M. gallisepticum showed that LP 64 constitutes 1.7% of the total protein. Scans of immunoblots of M. gallisepticum indicate that LP 64 is highly immunogenic in chickens, accounting for 7.4% of the total serum IgG response at four weeks post-infection. A quantitative value for the IgG response to LP 64, relative to the percentage of total protein (the Relative Immunogenicity Index) was 4.4. LP 64 is conserved among several strains of M. gallisepticum, but its presence could not be detected in Mycoplasma synoviae. Antiserum raised to electroeluted LP 64 reacted specifically with this lipoprotein when assessed on either one- or two-dimensional immunoblots of M. gallisepticum. This antiserum, as well as Fab fragments, inhibited haemagglutination of chicken erythrocytes and inhibited the attachment of 14C-labelled M. gallisepticum to chicken tracheal epithelium in vitro by 62%.     

Kinetics of cholesterol and phospholipid exchange between Mycoplasma gallisepticum cells and lipid vesicles. Alterations in membrane cholesterol and protein content

The kinetics of exchange of radiolabeled cholesterol and phospholipids between intact Mycoplasma gallisepticum cells and unilamellar lipid vesicles were investigated over a wide range of cholesterol/phospholipid molar ratio. The change in cholesterol/phospholipid molar ratio was achieved by adapting the sterol-requiring M. gallisepticum to grow in cholesterol-poor media, providing cells with decreased unesterified cholesterol content. At least 90% of the cholesterol molecules in unsealed M. gallisepticum membranes underwent exchange at 37 degrees C as a single kinetic pool in the presence of albumin (2%, w/v). However, we observed biphasic exchange kinetics with intact cells, indicating that cholesterol translocation from the inner to outer monolayers was rate-limiting in the exchange process. Approximately 50% of the cholesterol molecules were localized in each kinetic pool, independent of the cholesterol/phospholipid molar ratio in the cells and vesicles. A striking change in the kinetic parameters for cholesterol exchange occurred between 20 and 26 mol % cholesterol; for example, when the cholesterol/phospholipid molar ratio was decreased from 0.36 to 0.25, the half-time for equilibration of the two cholesterol pools at 37 degrees C decreased from 4.6 +/- 0.5 to 2.5 +/- 0.1 h. Phospholipid exchange rates were also enhanced on decreasing the membrane cholesterol content. The ability of cholesterol to modulate its own exchange rate, as well as that of phospholipids, is suggested to arise from the sterol's ability to regulate membrane lipid order. Extensive chemical modification of the membrane surface by cross-linking of some of the protein constituents with 1,4-phenylenedimaleimide decreased the cholesterol exchange rate. Depletion of membrane proteins by treatment of growing cultures with chloramphenicol increased the cholesterol exchange rate, possibly because of removal of some of the protein mass that may impede lipid translocation. The observations that phospholipid exchange was one order of magnitude slower than cholesterol exchange and that dimethyl sulfoxide, potassium thiocyanate, and potassium salicylate enhanced the cholesterol exchange rate are consistent with a mechanism involving lipid exchange by diffusion through the aqueous phase.     

Attachment of phenoloxidase to fungal cell walls in arthropod immunity

In crayfish, phenoloxidase was located in the hemocytes. The plasma had infinitesimal enzyme activity. A phenoloxidase preparation from hemocytes precipitated spontaneously after approximately 1.5 hr at 22°C, which became attached spontaneously to glass, Plexiglas, and polystyrene plastic. The enzyme preparation could also become attached to Saccharomyces cerevisiae cell walls. Attachment was mediated by a proteinaceous substance, since trypsin significantly decreased the degree of attachment. Calcium ions were also necessary for attachment. A β-1,3-glucan, laminaran, partially prevented attachment to the fungal cell walls. Heparin caused precipitation of the phenoloxidase preparation from hemocytes. In crayfish cuticle, proteins with associated phenoloxidase activity were attached to cell walls of Aphanomyces astaci as well as to those of S. cerevisiae.     

Schistosoma mansoni: visualization with fluorescent lectins of secretions and surface carbohydrates of living cercariae

Attachment of Schistosoma mansoni cercariae was studied during their explorative movements along a glass surface using labeled lectins as markers. Fluorochrome-labeled lectins selectively labeled surface material produced at the cercarial attachment sites and part of the cercarial surface. The deposited secretions reacted with most of the lectins used but differences in the staining intensity were noted. Secreted material was visualized at the attachment sites within a few seconds after cercarial attachment. The deposited material appeared as "footprints" located at a constant distance from each other. The footprints were formed by a regular cercarial "looping" movement along the glass surface and led to a site of massive deposition of secretions partly covering the body.     

Platelet thrombospondin mediates attachment and spreading of human melanoma cells

Human platelet thrombospondin adsorbed on plastic promotes attachment and spreading of human G361 melanoma cells. Attachment is rapid, and spreading is maximal by 90 min with 60-90% of the attached cells spread. In contrast, thrombospondin promotes attachment but not spreading of human C32 melanoma cells, which attach and spread only on laminin substrates. The specificity of these interactions and the regions of the thrombospondin molecule involved in attachment and spreading were examined using proteolytic fragments of thrombospondin and by inhibition studies. The sulfated fucan, fucoidan, and monoclonal antibody A2.5, which is directed against the heparin-binding domain of thrombospondin, selectively inhibit spreading but only weakly inhibit attachment. Monoclonal antibodies against some other domains of thrombospondin, however, are potent inhibitors of attachment. The amino-terminal heparin-binding domain of thrombospondin does not promote attachment. Large fragments lacking the heparin-binding domain support attachment but not spreading of G361 cells. Attachment activity is lost following removal of the 18-kD carboxyl-terminal domain. These results suggest that at least two melanoma ligands are involved in cell attachment and spreading on thrombospondin. The carboxyl-terminal region and perhaps other regions of the molecule bind to receptor(s) on the melanoma surface that promote initial attachment but not cell spreading. Interaction of the heparin-binding domain with sulfated glycoconjugates on melanoma surface proteoglycans and/or sulfated glycolipids mediates spreading. Monoclonal antibodies A2.5 and C6.7 also reverse spreading of G361 cells growing on glass culture substrates, suggesting that binding to thrombospondin mediates attachment of these melanoma cells in culture.     

Effects of biofilms on zebra mussel postveliger attachment to artificial surfaces

Abstract. The zebra mussel is an introduced fouling organism in North American inland waters. This field study tested whether natural biofilms, formed by covering substrata with a 100-μm mesh that allows microorganisms to attach and films to develop in the absence of postveligers, influenced the attachment of zebra mussel postveligers to artificial surfaces. Low-wettable polycarbonate and wettable glass surfaces were used in the experiments over four field seasons to study biofilm formation (1997–1998) and mussel attachment (1998–2000). The presence of the mesh did not quantitatively affect biofilm development on either substratum as determined by microscopic direct counts and colony-forming units on R2A agar. Natural biofilms on polycarbonate surfaces positively influenced postveliger attachment compared to substrata that initially had no film (ANOVA, p-values ranged from ≤.05 to ≤.001). Biofilms did not influence postveliger attachment to glass surfaces (ANOVA, p>.05). Attachment to both substrata was similar on surfaces with and without previously settled postveligers. Based on these results, we conclude that biofilms can enhance postveliger attachment to some but not all artificial surfaces.