Lead-Enhanced Siderophore Production and Alteration in Cell Morphology in a Pb-Resistant <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> Strain 4EA

A lead-resistant bacterial strain 4EA from soil contaminated with car battery waste from Goa, India was isolated and identified as Pseudomonas aeruginosa. This lead-resistant bacterial isolate interestingly revealed lead-enhanced siderophore (pyochelin and pyoverdine) production up to 0.5 mM lead nitrate whereas cells exhibit a significant decline in siderophore production above 0.5 mM lead nitrate. The bacterial cells also revealed significant alteration in cell morphology as size reduction when exposed to 0.8 mM lead nitrate. Enhanced production of siderophore was evidently detected by chrome azurol S agar diffusion (CASAD) assay as increase in diameter of orange halo, and reduction in bacterial size along with significant biosorption of lead was recorded by scanning electron microscopy coupled with energy dispersive X-ray spectrometry (SEM-EDX). Pseudomonas aeruginosa strain 4EA also exhibits cross tolerance to other toxic metals viz. cadmium, mercury, and zinc besides resistance to multiple antibiotics such as ampicillin, erythromycin, amikacin, cephalexin, co-trimoxazole, mecillinam, lincomycin, ciphaloridine, oleondamycin, and nalidixic acid.     

Chemical Characterization of Exopolysaccharides from Antarctic Marine Bacteria

Exopolysaccharides (EPS) may have an important role in the Antarctic marine environment, possibly acting as ligands for trace metal nutrients such as iron or providing cryoprotection for growth at low temperature and high salinity. Ten bacterial strains, isolated from Southern Ocean particulate material or from sea ice, were characterized. Whole cell fatty acid profiles and 16S rRNA gene sequences showed that the isolates included representatives of the genera Pseudoalteromonas, Shewanella, Polaribacter, and Flavobacterium as well as one strain, which constituted a new bacterial genus in the family Flavobacteriaceae. The isolates are, therefore, members of the “Gammaproteobacteria” and Cytophaga-Flexibacter-Bacteroides, the taxonomic groups that have been shown to dominate polar sea ice and seawater microbial communities. Exopolysaccharides produced by Antarctic isolates were characterized. Chemical composition and molecular weight data revealed that these EPS were very diverse, even among six closely related Pseudoalteromonas isolates. Most of the EPS contained charged uronic acid residues; several also contained sulfate groups. Some strain produced unusually large polymers (molecular weight up to 5.7 MDa) including one strain in which EPS synthesis is stimulated by low temperature. This study represents a first step in the understanding of the role of bacterial EPS in the Antarctic marine environment.     

Studies on Uranium Removal by the Extracellular Polysaccharide of a Pseudomonas aeruginosa Strain

Extracellular polysaccharide (EPS) produced by a Pseudomonas aeruginosa strain BU2 was characterized for its ability to remove uranium from aqueous solution. The EPS was acidic in nature and found as a potent biosorbent for uranium (U), showing pH dependence and fast saturating metal sorption, being maximum (985 mg U g^{? 1} EPS) at pH 5.0. The polymer showed enhanced uranium sorption capacity and affinity with increasing solution pH, suggesting a preferential sorption of monovalent uranyl hydroxide ions over the nonhydroxylated divalent species. Pseudo-first-order and pseudo-second-order kinetic models were applied to the experimental data, assuming that the external mass transfer limitations in the system can be neglected and biosorption is sorption controlled. Equilibrium metal binding showing conformity to the Freundlich model suggested a multilayer sorption involving specific binding sites with affinity distribution. The presence of two types of metal binding sites corresponding to strong and weak binding affinity was interpreted from the Scatchard model equation. Uranium sorption by EPS was unaffected or only slightly affected in the presence of several interfering cations and anions, except iron and thorium. Fourier transform infrared (FTIR) spectroscopy ascertained the strong binding of uranium with the carboxylic groups of uronic acids of bacterial EPS at pH 5.0, whereas at lower pH, amino and hydroxyl groups played a major role in metal binding.     

Yield and physicochemical properties of EPS from Halomonas sp. strain TG39 identifies a role for protein and anionic residues (sulfate and phosphate) in emulsification of n‐hexadecane

In this study, we investigated the yield and physicochemical properties of the high molecular weight extracellular polymeric substance (HMW–EPS) produced by Halomonas sp. strain TG39 when grown on different types and ratios of substrates. Glucose (1% w/v) and a peptone/yeast extract ratio of 5.1 (0.6% w/v final concentration) yielded an EPS fraction (HMW‐glucose) exhibiting the highest anionic activity (20.5) and specific emulsifying activity (EI₂₄ = 100%) compared to EPS produced by cells grown on mannitol, sucrose, malt extract or no carbon source. The HMW–EPS fractions were capable of binding ≈255–464 mg of methylene blue (MB) per gram of EPS, which represents the highest reported binding of MB by a bacterial EPS. A comparative evaluation of these properties to those of commercial hydrocolloids indicated that the combined effect of protein and anionic residues of the HMW–EPS contributed to its ability to emulsify n‐hexadecane. Liquid chromatography revealed the HMW‐glucose EPS to be a heterogeneous polymer with a polydispersity index of 1.8. This work presents evidence of a correlation between the anionic nature and protein content of bacterial EPS with its emulsifying qualities, and identifies EPS produced by strain TG39 as a high MB‐binding bacterial sorbant with potential biotechnological application. Biotechnol. Bioeng. 2009;103: 207–216. © 2008 Wiley Periodicals, Inc.     

The Fate of Marine Bacterial Exopolysaccharide in Natural Marine Microbial Communities

Most marine bacteria produce exopolysaccharides (EPS), and bacterial EPS represent an important source of dissolved organic carbon in marine ecosystems. It was proposed that bacterial EPS rich in uronic acid is resistant to mineralization by microbes and thus has a long residence time in global oceans. To confirm this hypothesis, bacterial EPS rich in galacturonic acid was isolated from Alteromonas sp. JL2810. The EPS was used to amend natural seawater to investigate the bioavailability of this EPS by native populations, in the presence and absence of ammonium and phosphate amendment. The data indicated that the bacterial EPS could not be completely consumed during the cultivation period and that the bioavailability of EPS was not only determined by its intrinsic properties, but was also determined by other factors such as the availability of inorganic nutrients. During the experiment, the humic-like component of fluorescent dissolved organic matter (FDOM) was freshly produced. Bacterial community structure analysis indicated that the class Flavobacteria of the phylum Bacteroidetes was the major contributor for the utilization of EPS. This report is the first to indicate that Flavobacteria are a major contributor to bacterial EPS degradation. The fraction of EPS that could not be completely utilized and the FDOM (e.g., humic acid-like substances) produced de novo may be refractory and may contribute to the carbon storage in the oceans.     

Biological characterization of Bacillus flexus strain SSAI1 transforming highly toxic arsenite to less toxic arsenate mediated by periplasmic arsenite oxidase enzyme encoded by aioAB genes

Bacillus flexus strain SSAI1 isolated from agro-industry waste, Tuem, Goa, India displayed high arsenite resistance as minimal inhibitory concentration was 25 mM in mineral salts medium. This bacterial strain exposed to 10 mM arsenite demonstrated rapid arsenite oxidation and internalization of 7 mM arsenate within 24 h. The Fourier transformed infrared (FTIR) spectroscopy of cells exposed to arsenite revealed important functional groups on the cell surface interacting with arsenite. Furthermore, scanning electron microscopy combined with electron dispersive X-ray spectroscopy (SEM-EDAX) of cells exposed to arsenite revealed clumping of cells with no surface adsorption of arsenite. Transmission electron microscopy coupled with electron dispersive X-ray spectroscopic (TEM-EDAX) analysis of arsenite exposed cells clearly demonstrated ultra-structural changes and intracellular accumulation of arsenic. Whole-genome sequence analysis of this bacterial strain interestingly revealed the presence of large number of metal(loid) resistance genes, including aioAB genes encoding arsenite oxidase responsible for the oxidation of highly toxic arsenite to less toxic arsenate. Enzyme assay further confirmed that arsenite oxidase is a periplasmic enzyme. The genome of strain SSAI1 also carried glpF, aioS and aioE genes conferring resistance to arsenite. Therefore, multi-metal(loid) resistant arsenite oxidizing Bacillus flexus strain SSAI1 has potential to bioremediate arsenite contaminated environmental sites and is the first report of its kind.

     

Isolation and characterization of environmental bacteria capable of extracellular biosorption of mercury

Accumulation of toxic metals in the environment represents a public health and wildlife concern. Bacteria resistant to toxic metals constitute an attractive biomass for the development of systems to decontaminate soils, sediments, or waters. In particular, biosorption of metals within the bacterial cell wall or secreted extracellular polymeric substances (EPS) is an emerging process for the bioremediation of contaminated water. Here the isolation of bacteria from soil, effluents, and river sediments contaminated with toxic metals permitted the selection of seven bacterial isolates tolerant to mercury and associated with a mucoid phenotype indicative of the production of EPS. Inductively coupled plasma-optical emission spectroscopy and transmission electron microscopy in conjunction with X-ray energy dispersive spectrometry revealed that bacteria incubated in the presence of HgCl2 sequestered mercury extracellularly as spherical or amorphous deposits. Killed bacterial biomass incubated in the presence of HgCl2 also generated spherical extracellular mercury deposits, with a sequestration capacity (40 to 120 mg mercury per g [dry weight] of biomass) superior to that of live bacteria (1 to 2 mg mercury per g [dry weight] of biomass). The seven strains were shown to produce EPS, which were characterized by Fourier transform-infrared (FT-IR) spectroscopy and chemical analysis of neutral-carbohydrate, uronic acid, and protein contents. The results highlight the high potential of Hg-tolerant bacteria for applications in the bioremediation of mercury through biosorption onto the biomass surface or secreted EPS.     

Structural and Functional Properties of Exopolysaccharide Excreted by a Novel <Emphasis Type="Italic">Bacillus anthracis</Emphasis> (Strain PFAB2) of Hot Spring Origin

Exopolysaccharide produced by a unique avirulent Bacillus anthracis strain PFAB2 of hot spring origin has been characterized and its functional properties are investigated which is a first report. Maximum yield of EPS is 7.66 g/l with 2% glucose and 1% peptone as optimum carbon and nitrogen source respectively. The EPS is found to be a homopolymer consisting of only glucose as principle monosaccharide component. Through ¹H NMR study, different dextran-like proton peaks are observed. Molecular weight of the EPS resembles low molecular weight bacterial origin polysaccharides. Melting transition of the EPS has started after 276 °C which indicates good thermal stability. The EPS also shows potent antioxidant activity in terms of DPPH and ABTS mediated free radical scavenging property compared to standard ascorbic acid. Emulsifying property of the EPS is also observed and has shown good emulsification of vegetable oils. The polysaccharide forms a thermo resistant gel during the heating phase, with G′ higher than G″ indicating excellent shear-thinning behaviour and viscoelastic nature of the EPS.     

Purification and characterization of an alpha-haloketone-resistant formate dehydrogenase from Thiobacillus sp. strain KNK65MA, and cloning of the gene

Thiobacillus sp. strain KNK65MA, which produced an NAD-dependent formate dehydrogenase (FDH) highly resistant to alpha-haloketones, was newly isolated, i.e., the enzyme showed no loss of activity after a 5-h incubation with alpha-haloketones, such as ethyl 4-chloro-3-oxobutanoate. The enzyme was also resistant to SH reagents. The enzyme, purified to homogeneity, was a dimer composed of identical subunits. The specific activity was 7.6 u/mg, and the apparent Km values for formate and NAD+ were 1.6 and 0.048 mM, respectively. The cloned gene of FDH contained one open reading frame (ORF) of 1206 base pairs, predicted to encode a polypeptide of 401 amino acids, with a calculated molecular weight of 44,021; this gene was highly expressed in E. coli cells. The deduced amino acid sequence of this FDH had high identity to other bacterial FDHs.     

Isolation of an extracellular polysaccharide (EPS) depolymerase produced byBradyrhizobium japonicum

Bradyrhizobium japonicum is capable of producing an acidic, high molecular weight, extracellular polysaccharide (EPS). An enzyme exhibiting EPS depolymerase activity was detected in cell lysates ofB. japonicum strain 2143. The depolymerase was active against the EPS produced by strain 2143 and the closely related EPS produced by strain 311b 110. Depolymerase activity was characterized by its ability to decrease the viscosity of EPS solutions, to decrease the molecular weight of EPS, and to catalyze the release of reducing groups from EPS. The depolymerase exhibited a sharp activity optimum at pH 6 and had a molecular weight of approximately 45 kD as determined by gel permeation chromatography. Analysis of depolymerase-treated EPS indicates that the enzyme acts as an endo-depolymerase, producing a relatively narrow size range of high molecular weight products.Contribution from the Missouri Agricultural Experiment Station, Journal Series Number 10:959.     

Potato Cell Plasma Membrane Receptors to Ring Rot Pathogen Extracellular Polysaccharides

The interaction of extracellular polysaccharides (EPS) of the potato ring rot bacterial pathogen Clavibacter michiganensis ssp. sepedonicus (Spieck. et Kott.) Skaptason et Burkh. (Cms) with protoplasts isolated both from leaf cells of plants grown in vitro and microsomal membrane fractions obtained from cell suspension cultures of two potato (Solanum tuberosum L.) cultivars contrasted by their resistance to this pathogen was studied. The EPS intensively bind to protoplast surfaces and microsomal membranes of the susceptible cultivar but not to those of the resistant cultivar. Treatment with protease, excess of unlabelled EPS, and with dextran, did not lead to the binding of fluorochrome‐labelled EPS to protoplasts and microsomal membranes (from both cultivars). It is proposed that (a) a great number of receptors to EPS Cms are present in the plasma membranes of potato cells of susceptible cultivars, (b) these receptors contain proteinaceous sites exposed on the external side of the plasma membrane which participate in EPS binding, and (c) the plasma membranes of cells of resistant cultivars contain a small but sufficient quantity of receptors to EPS able to induce defensive responses in plants.     

Reduction of Selenite to Elemental Red Selenium by <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. Strain CA5

A Pseudomonas sp. that may be useful in bioremediation projects was isolated from soil. The strain is of potential value because it reduces selenite to elemental red selenium and is unusual in that it was resistant to high concentrations of both selenate and selenite. Exposure of the strain to 50, 100, and 150 mM selenite reduced growth by 28, 57, and 66%, respectively, while no change in growth was observed when the strain was exposed to 64 mM selenate, the highest level tested. Cells of the strain removed 1.7 mM selenite from the culture fluid during a 7-day incubation. A selenite reductase with a molecular weight of ~115 kD was detected in cell-free extracts and a protein with a molecular weight of ~700 kD was detected that reduced both selenate and nitrate. The bacterial isolate is a strict aerobe, reducing selenite to elemental red selenium under aerobic conditions only. Pseudomonas sp. strain CA5 might be useful as an inoculum for bioreactors used to harvest selenium from selenite-containing groundwater. 16S rRNA gene sequence alignment and fatty acid analysis were used to identify the bacterium as a novel species of Pseudomonas related to P. argentinensis, P. flavescens, and P. straminea.     

Isolation and characterization of mucous exopolysaccharide (EPS) produced by Vibrio furnissii strain VB0S3

Marine bacterial strains were isolated from coastal regions of Goa and screened for the strains that produce the highest amount of mucous exopolysaccharide (EPS). Our screening resulted in the identification of the strain Vibrio furnissii VB0S3 (hereafter called VB0S3), as it produced the highest EPS in batch cultures during the late logarithmic growth phase. The isolate was identified as VB0S3 based on morphological and biochemical properties. Growth and EPS production were studied in mineral salts medium supplemented with NaCl (1.5%) and glucose (0.2%). The exopolymer was recovered from the culture supernatant by using three volumes of cold ethanol precipitation and dialysis procedure. Chemical analyses of EPS revealed that it is primarily composed of neutral sugars, uronic acids, and proteins. Fourier-transform infrared (FT-IR) spectroscopy revealed the presence of carboxyl, hydroxyl, and amide groups, which correspond to a typical heteropolymeric polysaccharide, and the EPS also possessed good emulsification activity. The gas chromatographic analysis of an alditol-acetate derivatized sample of EPS revealed that it was mainly composed of galactose and glucose. Minor components found were mannose, rhamnose, fucose, ribose, arabinose, and xylose. EPS was readily isolated from culture supernatants, which suggests that the EPS was a slime-like exopolysaccharide. This is the first report of exopolysaccharide characterization that describes the isolation and characterization of an EPS expressed by Vibrio furnissii strain VB0S3. The results of the study contribute significantly and go a long way towards an understanding of the correlation between growth and EPS production, chemical composition, and industrial applications of the exopolysaccharide in environmental biotechnology and bioremediation.     

Role of extracellular polymeric substance (EPS) in toxicity response of soil bacteria Bacillus sp. S3 to multiple heavy metals

Heavy metal resistant bacteria are of great interest because of their potential use in bioremediation. Understanding the survival and adaptive strategies of these bacteria under heavy metal stress is important for better utilization of these bacteria in remediation. The objective of this study was to investigate the role of bacterial extracellular polymeric substance (EPS) in detoxifying against different heavy metals in Bacillus sp. S3, a new hyper antimony-oxidizing bacterium previously isolated from contaminated mine soils. The results showed that Bacillus sp. S3 is a multi-metal resistant bacterial strain, especially to Sb(III), Cu(II) and Cr(VI). Toxic Cd(II), Cr(VI) and Cu(II) could stimulate the secretion of EPS in Bacillus sp. S3, significantly enhancing the adsorption and detoxification capacity of heavy metals. Both Fourier transform infrared spectroscopy (FTIR) and three-dimensional excitation–emission matrix (3D-EEM) analysis further confirmed that proteins were the main compounds of EPS for metal binding. In contrast, the EPS production was not induced under Sb(III) stress. Furthermore, the TEM–EDX micrograph showed that Bacillus sp. S3 strain preferentially transported the Sb(III) to the inside of the cell rather than adsorbed it on the extracellular surface, indicating intracellular detoxification rather than extracellular EPS precipitation played an important role in microbial resistance towards Sb(III). Together, our study suggests that the toxicity response of EPS to heavy metals is associated with difference in EPS properties, metal types and corresponding environmental conditions, which is likely to contribute to microbial-mediated remediation.

     

Diversity of heteropolysaccharide-producing lactic acid bacterium strains and their biopolymers

Thirty-one lactic acid bacterial strains from different species were evaluated for exopolysaccharide (EPS) production in milk. Thermophilic strains produced more EPS than mesophilic ones, but EPS yields were generally low. Ropiness or capsular polysaccharide formation was strain dependent. Six strains produced high-molecular-mass EPS. Polymers were classified into nine groups on the basis of their monomer composition. EPS from Enterococcus strains were isolated and characterized.     

Isolation and physico-chemical characterisation of extracellular polymeric substances produced by the marine bacterium Vibrio parahaemolyticus

A marine bacterial strain identified as Vibrio parahaemolyticus by 16S rRNA gene (HM355955) sequencing and gas chromatography (GC) coupled with MIDI was selected from a natural biofilm by its capability to produce extracellular polymeric substances (EPS). The EPS had an average molecule size of 15.278 μm and exhibited characteristic diffraction peaks at 5.985°, 9.150° and 22.823°, with d-spacings of 14.76661, 9.29989 and 3.89650 ?, respectively. The Fourier-transform infrared spectroscopy (FTIR) spectrum revealed aliphatic methyl, primary amine, halide groups, uronic acid and saccharides. Gas chromatography mass spectrometry (GCMS) confirmed the presence of arabinose, galactose, glucose and mannose. (1)HNMR (nuclear magnetic resonance) revealed functional groups characteristic of polysaccharides. The EPS were amorphous in nature (CI(xrd) 0.092), with a 67.37% emulsifying activity, thermostable up to 250°C and displayed pseudoplastic rheology. MALDI-TOF-TOF analysis revealed a series of masses, exhibiting low-mass peaks (m/z) corresponding to oligosaccharides and higher-mass peaks for polysaccharides consisting of different ratios of pentose and hexose moieties. This is the first report of a detailed characterisation of the EPS produced by V. parahaemolyticus, which could be further explored for biotechnological and industrial use.     

Functional activity of exoglycans from Rhizobium leguminosarum bv. viciae 250a and its nitrogen-resistant mutant M-71 during the formation of legume-rhizobia symbiosis against a high-nitrogen background

The functional activity of the exoglycan complex (EGC) polysaccharides from Rhizobium leguminosarum bv. viciae 250a and its nitrogen-resistant mutant M-71 capable of inducing the formation of nitrogen-fixing nodules on pea roots against a high-nitrogen background (4.8 mM NO3-) was studied in vegetation tests. For this purpose, the bacterial inoculum washed free of its own exoglycans was supplemented with EGC of this or another strain grown in the presence of 6 or 20 mM nitrate. The best symbiotic characteristics (nodule number and nitrogenase activity, mass of the roots and aerial parts of plants) were recorded when the inoculum cells and exoglycans were obtained from strain M-71 grown in the presence of 20 mM nitrate. When the plants were inoculated with the cells (grown at 6 mM nitrate) + EGC (obtained at 6 mM nitrate) of this strain, the nodulation characteristics and the effectiveness of symbiosis decreased 1.5-2-fold. Partial recovery of the symbiotic potential of strain M-71 was observed when EGC (obtained at 20 mM nitrate) was substituted for its exoglycans (obtained at 6 mM nitrate). In the presence of exoglycans of the parent strain 250a (obtained at 6 or 20 mM nitrate), the mutant formed a substantially lesser number of nodules with a very low nitrogen-fixing activity. In turn, the mutant exoglycans synthesized in medium with either high or low nitrate nitrogen concentration did not recover the fix+ phenotype of strain 250a capable of forming symbiosis with pea plants only against a low-nitrogen background. When studying the relative content of high-molecular-weight exopolysaccharide components and low-molecular-weight glycans in the exoglycan complex, it was established that, in strain 250a (grown at 6 and 20 mM nitrate), as well as in its mutant M-71 (grown at 6 mM nitrate), exopolysaccharides prevailed, accounting for 72-75% of the sum of both types of glycopolymers, while low-molecular-weight glycans accounted for 25-28%. In contrast, in the EGC of strain M-71 obtained at 20 mM nitrate, which was the most active inducer of the formation of the symbiotrophic system by strain M-71 in the presence of a high mineral nitrogen concentration, low-molecular-weight glycans were the main component, accounting for 61% of total glycopolymers, while the polysaccharide content was 39%. Low-molecular-weight exoglycans are supposed to be involved in maintaining the physiological activity and the symbiotic status of rhizobia under unfavorable environmental conditions.     

Optimization of fermentation conditions for production of exopolysaccharide by Bacillus polymyxa

Production of exopolysaccharide (EPS) from a strain of Bacillus polymyxa was studied. Sucrose and potassium nitrate were found to be efficient carbon and nitrogen sources, respectively, for the production of the EPS. EPS production increased with the increase of sucrose concentration, probably due to the facilitated carbon uptake. Optimal pH was 7–8, and a sufficient supply of oxygen was needed for the EPS production. It was noted that the EPS synthesis by this B. polymyxa was growth-associated, indicating that a sufficient supply of nutrients was required for a high production of the EPS. As high as 54?g/l of EPS with a yield of 63% (g EPS/g sucrose) was obtained in 48?h of fed-batch cultivation with intermittent feeding of sucrose and potassium nitrate.     

Functional Activity of Exoglycans from Rhizobium leguminosarum bv. viciae 250a and Its Nitrogen-Resistant Mutant M-71 during the Formation of Legume–Rhizobia Symbiosis against a High-Nitrogen Background

The functional activity of the exoglycan complex (EGC) polysaccharides from Rhizobium leguminosarum bv. viciae 250a and its nitrogen-resistant mutant M-71, capable of inducing the formation of nitrogen-fixing nodules on pea roots against a high-nitrogen background (4.8 mM NO₃ ^–), was studied in vegetation tests. For this purpose, the bacterial inoculum washed free of its own exoglycans was supplemented with EGC of the same or another strain grown in the presence of 6 or 20 mM nitrate. The best symbiotic characteristics (nodule number and nitrogenase activity, mass of the roots and aerial parts of plants) were recorded when the inoculum cells and exoglycans were obtained from strain M-71 grown in the presence of 20 mM nitrate. When the plants were inoculated with the cells (grown at 6 mM nitrate) + EGC (obtained at 6 mM nitrate) of this strain, the nodulation characteristics and the effectiveness of symbiosis decreased 1.5- to 2-fold. Partial recovery of the symbiotic potential of strain M-71 was observed when EGC (obtained at 20 mM nitrate) was substituted for its exoglycans (obtained at 6 mM nitrate). In the presence of exoglycans of the parent strain 250a (obtained at 6 or 20 mM nitrate), the mutant formed a substantially lesser number of nodules with a very low nitrogen-fixing activity. In turn, the mutant exoglycans synthesized in medium with either high or low nitrate nitrogen concentration did not recover the fix⁺ phenotype of strain 250a, capable of forming symbiosis with pea plants only against a low-nitrogen background. In study of the relative content of high-molecular-weight exopolysaccharide components and low-molecular-weight glycans in the exoglycan complex, it was established that, in strain 250a (grown at 6 and 20 mM nitrate), as well as in its mutant M-71 (grown at 6 mM nitrate), exopolysaccharides prevailed, accounting for 72–75% of the sum of both types of glycopolymers, while low-molecular-weight glycans accounted for 25–28%. In contrast, in the EGC of strain M-71 obtained at 20 mM nitrate, which was the most active inducer of the formation of the symbiotrophic system by strain M-71 in the presence of a high mineral nitrogen concentration, low-molecular-weight glycans were the main component, accounting for 61% of total glycopolymers, while the polysaccharide content was 39%. Low-molecular-weight exoglycans are supposed to be involved in maintaining the physiological activity and the symbiotic status of rhizobia under unfavorable environmental conditions.     

Potential role of bacterial extracellular polymeric substances as biosorbent material for arsenic bioremediation

Carcinogenic effects of arsenic through consumption of contaminated water are an alarming threat and there is an emergent need to reduce extremely high levels of toxic arsenic from environment. Bacterial biofilms produce polyanionic extracellular polymeric substance (EPS) that is considered an excellent biosorbent material for the remediation of toxic metals and metalloids. This study was aimed to investigate the role of bacterial EPS in arsenic bioremediation. EPS was extracted from biofilm forming and arsenic reducer bacterial strains that were isolated from industrial waste water and characterized biochemically. Fourier transform infrared spectroscopy was also performed to study functional groups. Both Exiguobacterium profundum PT2 and Ochrobactrum ciceri SW1 exhibited enhanced EPS production in the presence of arsenic. Arsenic stress increased protein and carbohydrate contents in the EPS of both bacterial strains as indicated by the peaks of 1363 to 1613 and 1035 to 1218?cm^?1 wavenumbers, respectively to cope with arsenic present in the surroundings. Shifting of peaks in As⁵⁺ treated samples from 1363 to 1379, 847 to 800 and 1211 to 1134?cm^?1 demonstrated the involvement of proteins, carbohydrates and phosphates in the sequestration of arsenic. Scanning electron microscopic examination of EPS revealed structural alterations such as the presence of closely embedded large clumps with interstitial spaces between stacked layers of the EPS of E. profundum PT2 treated with As⁵⁺ displayed the enhanced polysaccharide content and arsenic sorption. Therefore, increased production of bacterial EPS with large number of polyanionic functional groups on its surface having tendency to sequester arsenic through electrostatic or covalent interactions presented EPS an excellent biosorbent material for arsenic bioremediation.