A comparison of three methods for assaying hydrophobicity of pathogenic vibrios

The surface hydrophobicity of strains of Vibrio alginolyticus, V. carchariae, V. damsela, V. harveyi and V. vulnificus , isolated from either diseased cultured grouper ( Epinephelus malabaricus ) or penaeids ( Penaeus monodon and P. japonicus ) was determined using three different methods:the salt aggregation test (SAT), bacterial adhesion to hydrocarbons test (BATH), and adherence to nitrocellulose filters test (NCF). The results obtained indicate that all the strains tested showed some degree of hydrophobicity with the type strain of V. harveyi (ATCC 25919) showing strong hydrophobic properties in all the methods. The SAT method used in the present study was modified to a microtitre tray test, an easier test to read than the conventional in glass slide methodology. All the 13 test strains were positive in the BATH test when n -octane was used as the solvent, but only one strain was positive when n -hexadecane was used as the solvent. It is suggested that this method using n -octane as solvent is suitable for assaying the hydrophobicity of pathogenic vibrios isolated from diseased aquatic animals.     

Influence of the growth conditions on the hydrophobicity of Renibacterium salmoninarum evaluated by different methods

The influence of medium and salinity on the cell surface hydrophobicity of Renibacterium salmoninarum was investigated using three different methods: bacterial adherence to hydrocarbons (BATH), salt agglutination test (SAT), and binding to nitrocellulose filters (NCF). The possible relationship among hydrophobicity, haemagglutination and adherence to cell lines was also evaluated. R. salmoninarum showed to be highly hydrophobic regardless of the growth conditions or technique employed. Nevertheless, slight differences can be detected depending on the method used. In the SAT and NCF assays very uniform values were obtained within the strains. All the R. salmoninarum isolates agglutinated in (NH4)2SO4 in a range of 0.05-0.2 M and displayed a 77-100% of adherence to nitrocellulose filters. However, more variable results were observed in the BATH method depending on the hydrocarbon, buffer and strain employed. Although all of the isolates produced haemagglutinins for homeotherm erythrocytes, the majority of them failed to agglutinate poikilothermic red blood cells and were unable to adhere to fish cell lines. Therefore, a general correlation among hydrophobicity, agglutinating capacity for fish erythrocytes and adherence to fish cells can not be established for R. salmoninarum.     

Lactic acid bacteria: hydrophobicity and strength of attachment to meat surfaces

The hydrophobicity and strength of a ttachment of several lactic acid bacteria with antimicrobial activity were studied. Hydrophobicity was determined by bacterial adherence to hydrocarbons (BATH; octane or xylene), adhesion to nitrocellulose filters (NCF), salt aggregation test (SAT) and adherence to phenyl–Sepharose beads (PSB). The relative hydrophobicity of lactic acid bacteria depended markedly on the method used. No correlation between either SAT or BATH (octane) and strength of attachment (Sr value) existed. However, a significant relationship between strength of attachment and BATH (xylene), NCF and PSB, respectively, was observed, showing the highest correlation coefficient ( r = 0·778) for BATH (xylene).     

Cell surface hydrophobicity and slime production of Staphylococcus epidermidis Brazilian isolates

The cell surface hydrophobicity of 60 isolates and three reference strains of Staphylococcus epidermidis was assayed by means of bacterial aggregation in liquid broth, phosphate-buffered saline, and in ammonium sulfate, as well as by affinity of the bacteria to n-hexadecane and polystyrene surfaces. In order to better characterize the isolates, the influence of bacterial growth time and enzyme treatment on cell hydrophobicity and the analysis of the slime production were also investigated. The strains presented the following profiles when assayed by the ammonium sulfate aggregation test (SAT): SAT < 1M, SAT 1M - <2M, SAT 2M - <4M, and SAT >or=4M. When SAT < 1M, the strains showed positive results for most of the cell surface hydrophobicity tests. None of the strains belonging to the groups with SAT >or= 1M showed spontaneous aggregation (SA), auto-aggregation (AA), or glass adherence, albeit 32 (62.7%) strains were polystyrene adherent and 42 (82.3%) presented weak adherence to n-hexadecane (>20%). The best correlation of the results was found among the AA and glass adherence tests (100%), followed by SA/ glass adherence (98%) and SA/ AA test (98%). The polystyrene adherence test and microbial adherence to n-hexadecane test (MATH) showed 78% correlation. Proteinase K treatment reduced bacterial adherence to polystyrene, but did not influence the SAT values. Three distinct groups of strains were distinguished by the polystyrene micromethod and glass tube adherence assay: 0.0-0.4 O.D. group, including non-glass adherent isolates; 0.5-0.7 O.D. group, including strains with variable profiles (adherent or non-adherent); and 0.8-1.3 O.D. group, composed of glass-adherent strains. Evaluation by a single method seemed not to reliably determine the surface hydrophobicity characteristics of S. epidermidis clinical isolates. Auto-aggregation properties of the strains that adhered to glass seemed related to slime expression, rather than cell surface hydrophobicity. Data also suggested involvement of protein components in adherence to polystyrene, but not in auto-aggregation properties assayed by SAT.     

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.     

Cell Surface Hydrophobicity and Slime Production of <Emphasis Type="Italic">Staphylococcus epidermidis</Emphasis> Brazilian Isolates

The cell surface hydrophobicity of 60 isolates and three reference strains of Staphylococcus epidermidis was assayed by means of bacterial aggregation in liquid broth, phosphate-buffered saline, and in ammonium sulfate, as well as by affinity of the bacteria to n-hexadecane and polystyrene surfaces. In order to better characterize the isolates, the influence of bacterial growth time and enzyme treatment on cell hydrophobicity and the analysis of the slime production were also investigated. The strains presented the following profiles when assayed by the ammonium sulfate aggregation test (SAT): SAT < 1M, SAT 1M − <2M, SAT 2M − <4M, and SAT ≥4M. When SAT < 1M, the strains showed positive results for most of the cell surface hydrophobicity tests. None of the strains belonging to the groups with SAT ≥ 1M showed spontaneous aggregation (SA), auto-aggregation (AA), or glass adherence, albeit 32 (62.7%) strains were polystyrene adherent and 42 (82.3%) presented weak adherence to n-hexadecane (>20%). The best correlation of the results was found among the AA and glass adherence tests (100%), followed by SA/ glass adherence (98%) and SA/ AA test (98%). The polystyrene adherence test and microbial adherence to n-hexadecane test (MATH) showed 78% correlation. Proteinase K treatment reduced bacterial adherence to polystyrene, but did not influence the SAT values. Three distinct groups of strains were distinguished by the polystyrene micromethod and glass tube adherence assay: 0.0–0.4 O.D. group, including non-glass adherent isolates; 0.5–0.7 O.D. group, including strains with variable profiles (adherent or non-adherent); and 0.8–1.3 O.D. group, composed of glass-adherent strains. Evaluation by a single method seemed not to reliably determine the surface hydrophobicity characteristics of S. epidermidis clinical isolates. Auto-aggregation properties of the strains that adhered to glass seemed related to slime expression, rather than cell surface hydrophobicity. Data also suggested involvement of protein components in adherence to polystyrene, but not in auto-aggregation properties assayed by SAT. Received: 13 May 2002 / Accepted: 5 July 2002     

Yeast and bacteria cell hydrophobicity and hydrocarbon biodegradation in the presence of natural surfactants: rhamnolipides and saponins

This study concerns the relation between hydrocarbon biodegradation in the presence of natural surfactants and cell hydrophobicity resulting from the use of these surfactants. The relative capabilities of two bacterial strains (Pseudomonas aeruginosa and Bacillus subtilis) and two yeast strains (Candida maltosa, Yarrowia lipolytica) were investigated. The selected microorganisms were tested separately and in combination in order to achieve the optimal degrading performance. The surface cell hydrophobicity of microorganisms and the degree of hydrocarbon biodegradation were measured. The microbial adhesion to the hydrocarbon (MATH) test was used to denote the surface cell hydrophobicity of the microbial species. The results indicate the correlation between the modification of the surface cell and the degree of hydrocarbon biodegradation; however results for bacteria differ from that obtained for yeast strains. Saponins, as the surfactant, was more effective than rhamnolipides during hydrocarbon biodegradation, though the concentration of this surfactant has no significant influence on the surface cell hydrophobicity.     

High surface hydrophobicity of hemagglutinatingVibrio cholerae and other vibrios

Surface hydrophobicity of hemagglutinatingVibrio cholerae, Vibrio parahaemolyticus, and NAG vibrios has been investigated. Most strains caused mannose-sensitive hemagglutination of monkey, guinea pig, chicken, and mannose-resistant hemagglutination of human erythrocytes with different degrees of hemagglutinating activity. Hemagglutinating strains adsorbed to a hydrophobic gel (Octyl Sepharose), whereas nonhemagglutinating strains failed to adsorb.Vibrio cholerae and other vibrios investigated seem to have pronounced surface hydrophobicity as estimated by Octyl Sepharose and they correspondingly autoaggregated into visible cell clumps in ammonium sulfate solution at low molarity (0.2–0.4 M). Nonhemagglutinating strains did not aggregate even at high (2 M) ammonium sulfate concentration. The presence of surface hemagglutinins of vibrios is growth-media-dependent. Strains, grown in four different liquid media, produced hemagglutinins and expressed pronounced surface hydrophobicity. Studies with electron microscopy revealed the presence of fimbriae on the vibrio cells. The number of fimbriae on the cells varied from strain to strain. Some strains possessed more than 300 fimbriae/cell whereas others had less than 10 fimbriae/cell. Vibrio hemagglutinins are easily detached from the cell surface by heating or sonication, and their cell surface hydrophobicity decreased simultaneously.     

The effects of three non-antibiotic, antimicrobial agents on the surface hydrophobicity of certain micro-organisms evaluated by different methods

The effects of three non-antibiotic, antimicrobial agents (taurolidine, chlorhexidine acetate and providone-iodine) on the surface hydrophobicity of the clinical strains Escherichia coli, Staphylococcus saprophyticus, Staphylococcus epidermidis and Candida albicans were examined. Three recognized techniques for hydrophobicity measurements, Bacterial Adherence to Hydrocarbons (BATH), the Salt Aggregation Test (SAT) and Hydrophobic Interaction Chromatography (HIC) were compared. At concentrations reported to interfere with microbial-epithelial cell adherence, all three agents altered the cell surface hydrophobicity. However, these effects failed to exhibit a uniform relationship. Generally, taurolidine and povidone-iodine treatments decreased the hydrophobicity of the strains examined whereas chlorhexidine acetate effects depended upon the micro-organism treated. Subsequently, the exact contribution of altered cell surface hydrophobicity to the reported microbial anti-adherence effects is unclear. Comparison of the three techniques revealed a better correlation between the results obtained with the BATH test and HIC than the results obtained with the BATH and SAT or SAT and HIC. However, these differences may be due to the inaccuracy associated with the visual assessment of results employed by the SAT.     

The effects of three non-antibiotic, antimicrobial agents on the surface hydrophobicity of certain micro-organisms evaluated by different methods

D.S. JONES, S.P. GORMAN, D.F. MCCAFFERTY AND A.D. WOOLFSON. 1991. The effects of three non-antibiotic, antimicrobial agents (taurolidine, chlorhexidine acetate and providone-iodine) on the surface hydrophobicity of the clinical strains Escherichia coli, Staphylococcus saprophyticus, Staphylococcus epidermidis and Candida albicans were examined. Three recognized techniques for hydrophobicity measurements, Bacterial Adherence to Hydrocarbons (BATH), the Salt Aggregation Test (SAT) and Hydrophobic Interaction Chromatography (HIC) were compared. At concentrations reported to interfere with microbial-epithelial cell adherence, all three agents altered the cell surface hydrophobicity. However, these effects failed to exhibit a uniform relationship. Generally, taurolidine and povidone-iodine treatments decreased the hydrophobicity of the strains examined whereas chlorhexidine acetate effects depended upon the micro-organism treated. Subsequently, the exact contribution of altered cell surface hydrophobicity to the reported microbial anti-adherence effects is unclear. Comparison of the three techniques revealed a better correlation between the results obtained with the BATH test and HIC than the results obtained with the BATH and SAT or SAT and HIC. However, these differences may be due to the inaccuracy associated with the visual assessment of results employed by the SAT.     

Improvement of the salt aggregation test to study bacterial cell-surface hydrophobicity

Abstract An improved salt aggregation test (improved SAT) was developed to sensitize the determination of bacterial cell-surface hydrophobicity. One drop of a fresh bacterial suspension standardized to an A ^1cm₅₄₀ of 20 (equivalent to 5 × 10⁹ cfu/ml), and one drop each of ammonium sulphate solutions stained with methylene blue, were mixed on a white hydrophobic paper card using toothpicks. The bacterial suspensions, methylene blue stock solutions and the ammonium sulphate solutions (0.01–4.0 M) were made in 0.02 M sodium phosphate buffer, pH 6.8. Bacterial aggregations were read immediately after mixing the salt/bacterial suspensions while the card was gently rocked. Readings were also confirmed the next day on dried preparations. The results proved independent of reading time and mixture conditions (wet or dry preparations). The improved SAT technique is very rapid and sensitive, the reaction is easily read with the naked eye, and the paper cards can be stored for documentation of aggregation patterns after drying. In the improved SAT, the Staphylococcus cells of different species aggregated in 5 ways: tiny, medial, flaky granular, particulated and macrofilamentous forms; Salmonella strains aggregated in flaky granular, particulated and macrofilamentous forms.     

Surface hydrophobicity of "rheumatogenic" and "nephritogenic" strains of group A streptococci and the ultrastructural surface feature of pharyngeal cells exposed to group A streptococci.

The present study was carried out to determine the surface hydrophobicity of group A streptococcal strains responsible for rheumatic fever (RF), "rheumatogenic" strains (RG strains) and strains causing glomerulonephritis, "nephritogenic" strains (NG strains) in relation to their adhesion to human pharyngeal cells. Scanning electronmicroscopic (SEM) studies were carried out to the difference, if any, in the adherence of group A streptococci (M type 5) to pharyngeal and buccal cells (PEC and BEC). By employing two techniques for hydrophobicity determination, salt aggregation titre (SAT) and n-hexadecane binding technique, it was observed that RG strains (M5, M1 and M6) were more hydrophobic than NG strain, M49. However, NG strain M12 was almost equally as hydrophobic as RG strains. The adherence of RG strains, except M1 and M24, to PEC was greater in number than that of NG strains. Although M1 strain was hydrophobic, its adherence to PEC was less. Pepsin and trypsin treatment with streptococci reduced the hydrophobicity and adherence of RG and NG strains to PEC. SEM studies revealed firmly adhered indigenous bacteria on PEC and BEC. Streptococci (M5) adhered more to PEC than to BEC. SEM studies also showed that PEC had a peculiar ultrastructural surface feature to which streptococci adhered. These findings suggest that streptococcal hydrophobicity alone does not determine their adhesion to PEC. The surface nature of PEC might be a characteristic feature of the epithelial cells that allows streptococci to adhere and colonize or it might be a consequence of streptococcal adhesion.     

Cell surface hydrophobicity ofStaphylococcus aureus measured by the salt aggregation test (SAT)

Well-defined laboratory strains as well as 72 clinical strains ofStaphylococcus aureus isolated from bovine mastitis were investigated for surface hydrophobicity by the salt aggregation test (SAT).Staphylococcus aureus strain Cowan 1, rich in protein A and fibronectin-binding surface proteins, was found to show high surface hydrophobicity, whereas strain Wood 46, deficient in these surface proteins, showed low surface hydrophobicity. SAT showed a significant difference in surface hydrophobicity (P<0.001) between protein A-positive and A-negative strains measured by ²-test analysis. Comparison of SAT values with results obtained from hydrophobic interaction chromatography (HIC) showed a good correlation (P<0.025). A high-level protein-A-producing mutant (SA 113prA-3) showed increased surface hydrophobicity as compared with the parent strain (SA 113), whereas ten protein-A-negative mutants showed low surface hydrophobicity in SAT. Of the 72 clinical isolates tested by SAT, 47 (65%) showed autoaggregating properties, i.e., the strains aggregated even in isotonic buffers. Tween 80 (1% vol/vol) and ethylene glycol (50% vol/vol) prevented autoaggregation of some hydrophobic strains aggregating in phosphate-buffered saline. However, 2M of a chaotropic agent (NaSCN) was more efficient in preventing autoaggregation of the strains tested. Heating of cell suspensions to 80°C or 100°C as well as trypsin andStreptomyces griseus protease treatment generally caused a decrease in the cell surface hydrophobicity. This indicates that protein A, fibronectin-binding proteins, and probably other as yet unidentified proteins contribute to the high surface hydrophobicity of most strains isolated from bovine mastitis.     

Hydrophobic properties of gram-negative rods colonizing upper respiratory tract of healthy people

The cell surface hydrophobicity is one of the non specific factors of adhesion influencing the ability of microorganisms to colonize nasopharynx. The aim of this paper was to evaluate via salt aggregation test (SAT) the cell surface hydrophobicity of 150 strains of gram-negative rods isolated from the throat or/and nasal specimens of healthy people. It has been found that among the nonfermenting rods hydrophobic strains were predominant. In contrast, the isolates of Enterobacteriaceae family were characterized by the distinctive features of the cell surface within particular genera or even species. The obtained results show that, despite differences in cell surface hydrophobicity, numerous species of gram-negative rods have the ability to colonize the mucous membrane of upper respiratory tract. This suggests that the cell surface hydrophobicity is rather a feature of species or genus, but it is not related to the ecological niche of microorganisms in human body.     

Impact of the exopolysaccharides Pel and Psl on the initial adhesion of Pseudomonas aeruginosa to sand

In this study, the impact of the exopolysaccharides Pel and Psl on the cell surface electron donor-electron acceptor (acid-base) properties and adhesion to quartz sand was investigated by using Pseudomonas aeruginosa PAO1 and its isogenic EPS-mutant strains Δpel, Δpsl and Δpel/Δpsl. The microbial adhesion to hydrocarbon (MATH) test and titration results showed that both Pel and Psl contribute to the surface hydrophobicity of the cell. The results of contact angle measurement, however, showed no correlation with the cell surface hydrophobicity measured by the MATH test and the titration method. Packed-bed column experiments indicated that the exopolysaccharides Pel and Psl are involved in the initial cell attachment to the sand surface and the extent of their impact is dependent on the ionic strength (IS) of the solution. Overall, the Δpel/Δpsl double mutant had the lowest adhesion coefficient to sand compared with the wild-type PAO1, the Δpel mutant and the Δpsl mutant. It is hypothesized that in addition to bacterial surface hydrophobicity and DLVO forces, other factors, eg steric repulsion caused by extracellular macromolecules, and cell surface appendages (flagella and pili) also contribute significantly to the interaction between the cell surface and a sand grain.     

Effect of growth conditions on cell surface hydrophobicity of multiresistant Pseudomonas aeruginosa strains

Bacterial cell surface hydrophobicity (CSH) may promote colonization. The aim of this study was evaluation of the influence of growth conditions and sensitivity to selected antibiotics on hydrophobic properties of multiresistant P. aeruginosa strains by means of salt aggregation test (SAT) and bacterial adhesion to hydrocarbons (BATH). 30 multiresistant P. aeruginosa strains were included in this study. The variables were: microbiological media type (trypticase-soy agar, trypticase-soy agar with 5% sheep blood and trypticase-soy broth), growth temperature (22, 30 and 37 degrees C) and growth time (24 and 48 h). Most of the investigated strains presented hydrophilic properties in both methods. Cultivation in trypticase-soy broth caused statistically relevant decrease of CSH. Growth temperature did not influence CSH. 48 hours of incubation caused statistically relevant drop of the CSH when compared with 24 h incubation. The sensitivity to selected antibiotics did not vary investigated strains, except form cefepime sensitive and intermediate sensitive strains.     

Physicochemical and structural studies onAcinetobacter calcoaceticus RAG-1 and MR-481—Two standard strains in hydrophobicity tests

Acinetobacter calcoaceticus RAG-1 and MR-481, two standard strains used in microbial adhesion to hydrocarbons (MATH), were characterized by contact angles, pH-dependent zeta potentials, elemental surface composition by X-ray photoelectron spectroscopy (XPS), and molecular composition by infrared spectroscopy (IR). Negatively stained (methylamine tungstate) and ruthenium red-stained cells were studied by transmission electron microscopy to reveal the absence or presence of surface appendages. Despite the fact thatA. calcoaceticus RAG-1 is known to be extremely hydrophobic in MATH, whereas MR-481 is a completely non-hydrophobic mutant, neither XPS nor IR indicated a significant difference in chemical composition of the cell surfaces. Contact angles with polar liquids, water and formamide, were considerably higher on RAG-1 than on MR-481, in accordance with their relative hydrophobicities as measured by MATH. However, no significant differences in contact angles were observed between the two strains with apolar liquids like diiodomethane,-bromonaphthalene, and hexadecane. Fibrous extensions on RAG-1, observed after ruthenium red staining, were absent on the non-hydrophobic mutant MR-481. Tentatively, these extensions could be held responsible for the hydrophobicity ofA. calcoaceticus RAG-1.     

Toxin profiles, and cell-surface properties of Salmonella strains isolated from Swedish travelers.

Toxin production, cell-surface hydrophobicity and fibronectin-binding properties of 21 Salmonella strains of different species, isolated from Swedish travelers to different parts of the world, were studied. Cell sonicate supernatants from blood agar grown cultures of 80% of the strains induced rabbit skin permeability reaction in the form of induration and/or blueing while 33% of the strains also produced cell necrotizing factor on rabbit skin. Four strains were negative in the rabbit skin permeability test, while only two were negative when tested on CHO cells. When cultured on blood agar, a majority of the strains (17/21) showed low cell-surface hydrophobicity, showing no aggregation even at 1.5 M ammonium sulfate concentration in salt aggregation test (SAT), while only four strains showed high cell-surface hydrophobicity. Furthermore, these strains could be classified as low fibronectin binders due to their poor interaction with fibronectin or its 29 kDa N-terminal fragment.     

MATH法表征环境微生物细胞表面疏水性的研究进展

环境微生物的细胞表面疏水性对其生长代谢过程以及在环境领域的应用效率具有重要影响。目前用于测试细胞表面疏水性最常用的方法是碳氢吸附能力(Microbial adhesion to hydrocarbons,MATH),该方法因具有操作简便、有一定的准确度等优点在环境、生物工程、医学、食品等领域应用广泛。本文综述了MATH法在环境微生物领域中的污泥絮体性能表征、有机物降解、膜污染和破乳方面的应用,同时介绍了MATH法在实验操作、计数方法和数据分析方面的优化。最后展望了该方法今后的研究方向。