Biosorption of Malathion by immobilized cells of Bacillus sp. S14

Abstract

Biosorption is potentially an attractive technology for the treatment of wastewater by removing pesticide molecules from dilute solutions. This study investigated the feasibility of an isolated Bacillus sp. S₁₄ immobilized in calcium alginate that was used as a biosorbent for Malathion removal from aqueous solutions in batch mode. The highest value of Malathion uptake by isolated Bacillus sp. S14 (1.33g L^?1, dry basis) immobilized in 3% calcium alginate was 64.4% at 25°C and pH7.0 when the initial Malathion concentration was 50 mg L^?1. Equilibrium was attained at 8h. The sorption data conformed well to the Fruendlich isotherm model.     

H production by immobilized cells of Clostridium butyricum on porous glass beads

Clostridium butyricum immobilized on porous glass beads in a column reactor evolved H 2 at 715 and 1,150 ml/l.h, with H 2 yields of 2.3 and 1.9 mol H 2 /mol glucose, at retention times of 2.0 and 1.0 h, respectively, with a medium containing 0.5 g glucose/l in continuous cultures without pH control.     

Biodegradation of p-cresol by immobilized cells of Bacillus sp. strain PHN 1

The Bacillus sp. strain PHN 1 capable of degrading p-cresol was immobilized in various matrices namely, polyurethane foam (PUF), polyacrylamide, alginate and agar. The degradation rates of 20 and 40 mM p-cresol by the freely suspended cells and immobilized cells in batches and semi-continuous with shaken cultures were compared. The PUF-immobilized cells achieved higher degradation of 20 and 40 mM p-cresol than freely suspended cells and the cells immobilized in polyacrylamide, alginate and agar. The PUF- immobilized cells could be reused for more than 35 cycles, without losing any degradation capacity and showed more tolerance to pH and temperature changes than free cells. These results revealed that the immobilized cell systems are more efficient than freely suspended cells for degradation of p-cresol.     

Continuous production of bacitracin by immobilized living whole cells of Bacillus sp.

Whole cells of Bacillus sp., a bacitracin-producing bacteria, were immobilized in polyacrylamide gel. The continuous production of bacitracin by an immobilized whole-cell-containing air-bubbled reactor was examined with 0.5% peptone solution. The bacitracin productivity (28 units/ml/hr) obtained with this system was higher than that with a batch system. The effluent bacitracin concentration increased with increasing aeration rate and reached a steady-state maximum above the aeration rate of 3.0 liter/min. A high bacitracin productivity was retained for at least eight days when the gel was washed with sterilized saline at a flow rate of 250 ml/hr for 2 hr once a day. The half-life of the immobilized whole-cell system was about 10 days. Bacitracin productivity by the immobilized whole-cell reactor was higher than that by a conventional continuous fermentation process at high dilution rates.     

抑藻菌株Bacillus sp. hsn03分离鉴定及其对铜绿微囊藻的抑制效果与特征

【背景】蓝藻常形成水华,严重破坏水生环境及威胁水生生物。微生物能够专一性地抑制蓝藻的生长,从而可以被用于蓝藻水华的控制。【目的】分离筛选一株对有害水华藻——铜绿微囊藻(Microcystisaeruginosa)7806有高效抑藻能力的菌株,对其进行生理生化和分子鉴定,并研究其抑藻效果与特征。【方法】通过API试剂条确定其生理生化特征,对细菌的16SrRNA基因进行测序并构建系统进化树,通过探究细菌菌体、上清、发酵液的抑藻效果确定该菌的抑藻方式,通过测定不同温度、pH、蛋白酶K、有机溶剂萃取和透析条件下的抑藻效果及傅里叶红外光谱来确定胞外抑藻物质的性质。【结果】菌株hsn03与芽孢杆菌属(Bacillus sp.)的Bacillus sonorensis NBRC101234有最高相似性,达99.59%;通过分泌胞外抑藻物质对铜绿微囊藻生长表现出抑制效果,且最佳抑藻添加量为7.0%(体积比);胞外抑藻物质为一类分子量大于500 Da且小于1 kD,耐高温,耐酸碱,含有叁键和累积双键,非蛋白、多糖类的小分子物质。【结论】抑藻菌株的挖掘与鉴定对于丰富有害藻华藻的抑藻菌质资源有非常大的促进作用,通过对抑藻方式、效果和特征的研究为进一步将抑藻菌应用于铜绿微囊藻的治理奠定基础。     

Production of Schardinger beta-dextrin by soluble and immobilized cyclodextrin glycosyltransferase of an alkalophilic Bacillus sp.

Succinylated cyclodextrin glycosyltransferase (EC 3.2.1.19) of an alkalophilic Bacillus sp. was adsorbed on a vinylpyridine copolymer. The enzyme had about 25% of the activity of soluble enzyme added. No increase of pH or thermal stability of the enzyme was observed by the adsorption, whereas optimum temperature for the enzyme action was shifted from 50 to 55 degrees C. The enzyme converted starch to cyclodextrine without significant loss of activity under the conditions of 4 times reusing of 6 hr conversion by the batch system or 2 weeks continuous reaction by the column system at 55 degrees C and pH 8.0. About 46% of the potato starch solution [15% (w/v)] was converted to cyclodextrins by the enzyme, and 52% was converted by the simultaneous action of the enzyme and alkaline pullulanase of alkalophilic Bacillus sp. (No. 202-1). These values were almost the same as those obtained by the soluble enzyme or enzymes system.     

Bench scale production of butyramide using free and immobilized cells of Bacillus sp. APB-6

Bioprocess and Biosystems Engineering - Butyramide is a commodity chemical having wide range of applications from material science to biological sciences including synthesis of therapeutic drugs,...     

Use of immobilized biofilm of Citrobacter sp. for the removal of uranium and lead from aqueous flows

Under appropriate growth conditions with suitable support a Citrobacter sp. formed a cohesive biofilm. When subsequently challenged with soluble lead or uranium much of the metal was accumulated, comparable to that of polyacrylamide immobilized cells, with metal deposition visually apparent. Metal uptake occurs via phosphatase mediated cleavage of organic phosphate to precipitate liberated HPO²⁻₄ as insoluble metal phosphate. Both types of immobilized cell liberated comparable amounts of HPO²⁻₄ from metal-free flows, but uranium accumulation was less than that observed for lead. Full potential to accumulate U was attained only after storage of the cells prior to U exposure, while maximum Pb accumulation and HPO²⁻₄ liberation occurred with freshly harvested and stored cells. These findings are discussed.     

Ammonia-nitrogen and orthophosphate removal by immobilized Scenedesmus sp. isolated from municipal wastewater for potential use in tertiary treatment

Scendesmus sp. isolated from municipal wastewater, entrapped in calcium alginate as algal sheets was employed to remove inorganic nutrients (N and P) from artificial and real domestic secondary effluents in parallel-plate bioreactor after starvation. The key factors affecting the removal efficiency (NH4+-N and PO4(3-)-P), system stability and reuse efficiency of screens were studied and discussed. It has been shown that cell density in the mixture of algal gel was the key factor compared with the thickness of the gel and the cell density of the reactor. A complete removal of NH4+-N and PO4(3-)-P was achieved within 4h of treatment in parallel bioreactors with the optimal cell density in the mixture of algal (2 x 10(8) algae mL(-1)) and 3mm gel sheets after second cycle. Nine cycles of wastewater treatment in 21 days were accomplished, holding higher removal efficiency. NH(4)(+)-N removal efficiency was 99.1% after 105 min, 100% after 135 min, PO4(3-)-P removal efficiency was 100% after 15 min in domestic secondary effluents. Immobilized Scendesmus sp. is shown to have great potentialities for removal of inorganic nitrogen and phosphorus from treated effluents.     

Production of α-glucosidase by Bacillus sp. strains

α-Glucosidase was detected in four wild-type amylolytic strains belonging to the Bacillus genus. The strains showed α-glucosidase activity in extracellular and membrane-bound fractions. Kinitic studies of the α-glucosidase synthesis in the batch cultures of four strains of the Bacillus genus showed two profiles: partially and totally growth-linked synthesis. The presence of different activities and production profiles of α-glucosidase in the strains at high or low glucose concentrations in the medium would indicate that α-glucosidase may have a role in the regulation of the metabolism of α-polysaccharides.     

Nitrile degradation by free and immobilized cells of the thermophile Bacillus sp. UG-5B, isolated from polluted industrial waters

A moderately thermophilic Gram-positive, sporulating, rod-shaped strain of Bacillus with nitrile-degrading activity was isolated from polluted industrial waters. Whole cells and cell-free extracts from the end of exponential growth phase expressed 7.6 nkat mg⁻¹ and 2.0 nkat mg⁻¹ benzonitrile-degrading activity, respectively, after cultivation in a fermentor with complex medium containing benzonitrile as an inducer. The benzonitrile degradation took place via the nitrilase pathway directly to benzoic acid without intermediate formation of benzamide. Samples with benzonitrilase activity of 7.6 nkat mg⁻¹ converted 3 mg benzonitrile in 1 h at 45°C. The half-life of benzonitrilase activity for a whole cell suspension and for cells immobilized in 2% agar was 4.5 min and 6 min at 70°C without substrate and 3 min at 90°C with substrate, respectively. The nitrilase had a broad substrate spectrum. The active biocatalyst obtained by immobilization was used in a continuous process and total biodegradation of 14.1 mM benzonitrile and 37.2 mM 4-cyanopyridine in a column bioreactor at 50°C for 5 h was achieved.     

Co-occurrence of non-toxic (cyanopeptolin) and toxic (microcystin) peptides in a bloom of Microcystis sp. from a Chilean lake

A cyanobacterial bloom occurring in 1998 in lake Tres Pascualas (Concepción/Chile) was found to be dominated by Microcystis sp. The bloom contained both non-toxic (cyanopeptolin-type) and hepatotoxic (microcystin-type) peptides. Cyanopeptolin structure of the non-toxic peptides (called cyanopeptolin VW-1 and VW-2, respectively) was revealed by matrix assisted laser desorption ionization mass spectrometry (MALDI-TOF-MS) of whole cells, showing dominant molecular ions at m/z = 975 and m/z 995, respectively. On post source decay (PSD), both cyanopeptolins showed fragments deriving from Ahp-Phe-MTyr (3-amino-6-hydroxy-2-piperidone), the characteristic partial structure of cyanopeptolins. The amounts of each of the two cyanopeptolins could only roughly be estimated to be >0.1% of bloom material dry weight. In addition the blooms contained microcystins (20 microg/g bloom dry weight as determined by RP-HPLC, 13 microg/g according to ELISA determination). MALDI-TOF-MS revealed several structural variants of microcystin: MCYST-RR (microcystin with Arg and Arg, indicated by m/z 1,038 and confirmed by PSD revealing a m/z = 135 fragment deriving from the Adda side chain, MCYST-FR (microcystin with Phe and Arg, indicated by m/z = 1,015). The presence of [Asp(3)]-MCYST-LR (microcystin with Leu and Arg, Asp non-methylated, indicated by m/z 981), and [Asp(3)]-MCYST-YR (microcystin with Tyr and Arg, Asp non-methylated, indicated by m/z 1,031) were likely. The relative amounts of the peptides varied between February, April, and May. Whole cell extracts from the bloom material revealed specific enzyme inhibitory activities. The serin-proteases trypsin, plasmin, elastase were inhibited, assumable due to the cyanopeptolins found. Elastase and the cysteine-protease papain were not inhibited, inhibitions of protein kinase and glutathione S-transferase (GST) were low. Strong inhibition was observed with protein-phosphatase-1, likely due to the microcystins present in the samples.     

Biocatalytic efficacy of immobilized cells of Chryseobacterium sp. Alg-SU10 for simultaneous hydrolysis of urethane and urea

Urethane, a carcinogenic and teratogenic compound, in fermented foods and alcoholic beverages can be eliminated either by direct hydrolysis with urethanase, or by hydrolysis of its precursor molecule urea with acid urease. In the present study, a potent bacterium, which concomitantly produced urethanase and acid urease, was isolated from the decomposed Sargassum species. This bacterial isolate was identified as Chryseobacterium sp. Alg-SU10 by the 16S rRNA gene sequencing approach. The biocatalytic efficacy of the calcium alginate immobilized cells of this bacterium for the hydrolysis of urethane and urea was evaluated by characterizing urethanase and acid urease. The immobilized biocatalyst displayed maximal urethanase and urease activities at pH 5, and retained more than 96% of enzymatic activity at 15% (v/v) ethanol. The values of activation energy, enthalpy and entropy of catalysis were calculated as 43.3?kJ/mol, 40.8?kJ/mol and –116?J/mol/K, respectively, for urethanase and 38.1?kJ/mol, 35.6?kJ/mol and –77.8?J/mol/K, respectively, for acid urease. The overall results indicate the biocatalytic potential of immobilized cells of Chryseobacterium sp. Alg-SU10 for efficient abatement of urethane. This is the first report describing the thermodynamic characteristics of urethanase and acid urease co-produced by Chryseobacterium sp.     

Biodegradation of pyridine by freely suspended and immobilized Pimelobacter sp.

Freely suspended and Ca-alginate-immobilized cells of Pimelobacter sp. were used for degradation of pyridine. When the pyridine concentration was up to 2 g l^–1, freely suspended cells completely degraded pyridine regardless of the initial cell concentrations used. However, when the pyridine concentration increased to 4 g l^–1, the initial cell concentration in freely suspended cell culture should be higher than 1.5 g dry cell weight l^–1 for complete degradation of pyridine. In addition, a freely suspended cell culture with a high initial cell concentration resulted in a high volumetric pyridine-degradation rate, suggesting the potential use of immobilized cells for pyridine-degradation. When the immobilized cells were used for pyridine-degradation, neither specific pyridine-degradation rate nor tolerance against pyridine was improved. However, a high volumetric pyridine-degradation rate in the range 0.082–0.129 g l^–1 hr^–1 could be achieved by the immobilized cells because of the high cell concentration. Furthermore, when the immobilized cells were reused in degrading pyridine at a concentration of 2–4 g l^–1 they did not lose their pyridine-degrading activity for 2 weeks. Taken together, the data obtained here showed the feasibility of using immobilized cells for pyridine-degradation.     

Manganese removal and product characteristics of a marine manganese-oxidizing bacterium Bacillus sp. FF-1

International Microbiology - Biogenic manganese oxides (BioMnOx) have been found all over the world, and most of them were formed by Mn(II)-oxidizing bacteria (MnOB). In this study, a MnOB...     

Anaerobic utilization of phosphite and hypophosphite by Bacillus sp.

A Bacillus sp. capable of utilizing phosphite and hypophosphite under anaerobic conditions was isolated from Cape Canerval soil samples. The organism was isolated on a glucose-mineral salts medium with phosphate deleted. Anaerobic cultivation of this isolate resulted in decreases in the hypophosphite or phosphite concentration, increases in turbidity, cell count, and dry-cell weight, and decreases in pH and glucose concentration. The optimum hypophosphite concentration for this isolate was 60 microgram/ml, whereas the optimum phosphate concentration was greater than 1,000 microgram/ml, suggesting that higher concentrations of hypophosphite may be toxic to this isolate. Hypophosphite or phosphite utilization was accompanied by little or no detectable accumulation of phosphate in the medium, and 32P-labeled hypophosphite was incorporated into the cell as organic phosphate. When phosphate was present in the medium, the isolate failed to metabolize phosphite. In the presence of phosphite and hypophosphite, the isolate first utilized phosphite and then hypophosphite.     

Copper removal by immobilized Microcystis aeruginosa in continuous flow columns at different bed heights: study of the adsorption/desorption cycle

Microcystis aeruginosa immobilized in a natural polymer was tested for its potential to remove Cu²⁺ ions from aqueous solution in a continuous, downflow packed columnar reactor. Various parameters like flow rate, bed height and contact time required for maximum removal of test metals by the immobilized Microcystis aeruginosa were optimized. An increase in bed height from 2 to 10 cm resulted in an apparent decrease in biosorption capacity from 8.94 to 5.34 mg g^–1, but more Cu²⁺ solution was purified at the higher bed height. Efficiency of metal recovery from Cu²⁺-loaded biomass and its subsequent regeneration was also determined. Immobilized M. aeruginosa was found to be effective in Cu²⁺ removal from solution for up to 10 cycles of adsorption–desorption and 1 M HCl is very efficient desorbent for regeneration of Microcystis biomass for reuse.