Anna Sotirova

Rhamnolipid–Biosurfactant Permeabilizing Effects on Gram-Positive and Gram-Negative Bacterial Strains

The potential of biosurfactant PS to permeabilize bacterial cells of Pseudomonas aeruginosa, Escherichia coli, and Bacillus subtilis on growing (in vivo) and resting (in vitro) cells was studied. Biosurfactant was shown to have a neutral or detrimental effect on the growth of Gram-positive strains, and this was dependent on the surfactant concentration. The growth of Gram-negative strains was not influenced by the presence of biosurfactant in the media. Cell permeabilization with biosurfactant PS was shown to be more effective with B. subtilis resting cells than with Pseudomonas aeruginosa. Scanning-electron microscopy observations showed that the biosurfactant PS did not exert a disruptive action on resting cells such that it was detrimental to the effect on growing cells of B. subtilis. Low critical micelle concentrations, tender action on nongrowing cells, and neutral effects on the growth of microbial strains at low surfactant concentrations make biosurfactant PS a potential candidate for application in different industrial fields, in environmental bioremediation, and in biomedicine.

The Effect of Rhamnolipid Biosurfactant Produced by Pseudomonas fluorescens on Model Bacterial Strains and Isolates from Industrial Wastewater

In this study, the effect of rhamnolipid biosurfactant produced by Pseudomonas fluorescens on bacterial strains, laboratory strains, and isolates from industrial wastewater was investigated. It was shown that biosurfactant, depending on the concentration, has a neutral or detrimental effect on the growth and protein release of model Gram (+) strain Bacillus subtilis 168. The growth and protein release of model Gram (−) strain Pseudomonas aeruginosa 1390 was not influenced by the presence of biosurfactant in the medium. Rhamnolipid biosurfactant at the used concentrations supported the growth of some slow growing on hexadecane bacterial isolates, members of the microbial community. Changes in cell surface hydrophobicity and permeability of some Gram (+) and Gram (−) isolates in the presence of rhamnolipid biosurfactant were followed in experiments in vitro. It was found that bacterial cells treated with biosurfactant became more or less hydrophobic than untreated cells depending on individual characteristics and abilities of the strains. For all treated strains, an increase in the amount of released protein was observed with increasing the amount of biosurfactant, probably due to increased cell permeability as a result of changes in the organization of cell surface structures. The results obtained could contribute to clarify the relationships between members of the microbial community as well as suggest the efficiency of surface properties of rhamnolipid biosurfactant from Pseudomonas fluorescens making it potentially applicable in bioremediation of hydrocarbon-polluted environments.

The Importance of Rhamnolipid-Biosurfactant-Induced Changes in Bacterial Membrane Lipids of Bacillus subtilis for the Antimicrobial Activity of Thiosulfonates

The antimicrobial properties of methyl (MTS) and ethyl (ETS) esters of thiosulfonic acid alone and in combination with rhamnolipid-biosurfactant (RL) have been characterized for their ability to disrupt the normal physiological functions of living pathogens. Bactericidal and fungicidal activities of MTS and ETS and their combination with rhamnolipid were demonstrated on strains of Pseudomonas aeruginosa, Bacillus subtilis, Alcaligenes faecalis, and Rhizopus ngtricans. It was found that the combination of rhamnolipid and thiosulfonic esters has a synergistic effect leading to decreasing of bactericidal and fungicidal concentrations of MTS and ETS. More extensively was studied the effect of rhamnolipid on the lipid composition of B. subtilis bacterial membrane. To our knowledge, in this article is reported for the first time a remarkable increase of negatively charged phospholipid cardiolipin in the presence of rhamnolipid. The capacity of RL as a surface-active substance was confirmed by scanning electron microscopy (SEM). The occurrence of surface infolds and blebs on B. subtilis shown by SEM, was not accompanied by changes in membrane permeability tested by a live/dead viability staining for fluorescence microscopy. When RL was applied in combination with MTS, a dramatic permeability shift for propidium iodide was observed in vegetative cells.

Evaluation of Different Carbon Sources for Growth and Biosurfactant Production by Pseudomonas fluorescens Isolated from Wastewaters

The indigenous strain Pseudomonas fluorescens, isolated from industrial wastewater, was able to produce glycolipid biosurfactants from a variety of carbon sources, including hydrophilic compounds, hydrocarbons, mineral oils, and vegetable oils. Hexadecane, mineral oils, vegetable oils, and glycerol were preferred carbon sources for growth and biosurfactant production by the strain. Biosurfactant production was detected by measuring the surface and interfacial tension, rhamnose concentration and emulsifying activity. The surface tension of supernatants varied from 28.4 mN m-1 with phenanthrene to 49.6 mN m-1 with naphthalene and heptane as carbon sources. The interfacial tension has changed in a narrow interval between 6.4 and 7.6 mN m-1. The emulsifying activity was determined to be highest in media with vegetable oils as substrates. The biosurfactant production on insoluble carbon sources contributed to a signifi cant increase of cell hydrophobicity and correlated with an increased growth of the strain on these substrates. Based on these results, a mechanism of biosurfactant-enhanced interfacial uptake of hydrophobic substrates could be proposed as predominant for the strain. With hexadecane as a carbon source, the pH value of 7.0 - 7.2 and temperature of (28 ± 2) °C were optimum for growth and biosurfactant production by P. fluorescens cells. The increased specific protein and biosurfactant release during growth of the strain on hexadecane in the presence of NaCl at contents up to 2% could be due to increased cell permeability. The capability of P. fluorescens strain HW-6 to adapt its own metabolism to use different nutrients as energy sources and to keep up relatively high biosurfactant levels in the medium during the stationary phase is a promising feature for its possible application in biological treatments.

Purification and partial characterization of neuraminidase from the non-pathogenic Arthrobacter nicotianae

Abstract Neuraminidase from Arthrobacter nicotianae was purified by chromatography on DEAE-cellulose, gel filtration on Sephadex G-150, and chromatography on CM-cellulose. The molecular mass of the highly purified neuraminidase was found to be approximately 69 kDa by SDS-PAGE. The pH and temperature optima were 5.0 and 45°C, respectively. The enzyme was stable at temperatures up to 50°C, Ca 2+ , Ba 2+ , and Mg 2+ activated the enzyme, but Pb 2+ , Fe 3+ , and the chelating agent EDTA were inhibitory. The purified neuraminidase had a K m value of 3.17 m M when glucomacropeptide was the substrate.

Purification and partial characterization of acid phosphatase from Candida lipolytica

Non-specific acid phosphatase from Candida lipolytica cells was purified 111-fold by chromatography on DEAE-cellulose and gel filtration on Sephadex G-100 and Sepharose 4B. The enzyme is a glycoprotein containing 67% neutral sugars. The molecular mass of the highly purified acid phosphatase was found to be approximately 95 kDa by both SDS-PAGE and gel filtration. The pH and temperature optima were 5.8 and 55 degrees C, respectively. The enzyme was stable at pH values between 3.5 and 5.5 and at temperatures up to 60 degrees C. The purified phosphatase had a Km value of 3.64 mM for p-nitrophenyl phosphate and showed broad substrate specificity.

Role of Microbial Surface-Active Compounds in Environmental Protection

Abstract Recent decades have witnessed a considerable interest in research on biogenic surfactants (microbial surfactants, biosurfactants), products of biosynthesis of various microorganisms, as well as the possibilities for their practical use. The potential role and applications of biosurfactants in protecting the environment, considering their physicochemical and biological properties, are discussed in this chapter. The possible mechanisms of biosurfactant effects on bioremediation are presented, including their ability for desorption and solubilization of pollutants, and the effect on microbial growing and resting cells and on enzyme activities. The role of biosurfactants in of the bioremediation of water and soil, polluted by petroleum products, polyaromatic hydrocarbons, heavy metals, and substances is reviewed. Furthermore, new data on the application of biosurfactants in the pharmaceutical, medicinal, cosmetic, food industry, as well as in the petroleum industry, are presented. This review attempts to provide detailed information on the biosurfactants involved in the biodegradation of various pollutants and proposes ways to overcome the limitations of their practical use.