Thermophilic biodesulfurization and its application in oil desulfurization

To reduce the harm caused to the environment by fuel combustion and meet the increasingly stringent emission standards, the sulfur content of fuels should be reduced. Dibenzothiophene, benzothiophene, and their derivatives are sulfur-containing components of fuels that are difficult to desulfurize and can therefore cause great environmental damage. Biodesulfurization is a desulfurization method that has the advantage of being able to remove dibenzothiophene and its derivatives removed easily under conditions that are relatively mild when compared with hydrodesulfurization. This paper introduces the advantages of thermophilic biodesulfurization compared with mesophilic biodesulfurization; analyzes the desulfurization mechanism, including the desulfurization pathways and enzymic systems of desulfurization bacteria; and discusses the application of biodesulfurization in oil desulfurization. The main problems existing in biodesulfurization and possible solutions are also analyzed in this paper. Biological desulfurization is a promising method for desulfurization; accordingly, more studies investigating biodesulfurization of actual oil are needed to enable the industrialized application of biodesulfurization.

     

Improvement of biodesulfurization rate by assembling nanosorbents on the surfaces of microbial cells

To improve biodesulfurization rate is a key to industrialize biodesulfurization technology. The biodesulfurization rate is partially affected by transfer rate of substrates from organic phase to microbial cell. In this study, gamma-Al2O3 nanosorbents, which had the ability to selectively adsorb dibenzothiophene (DBT) from organic phase, were assembled on the surfaces of Pseudomonas delafieldii R-8 cell, a desulfurization strain. gamma-Al2O3 nanosorbents have the ability to adsorb DBT from oil phase, and the rate of adsorption was far higher than that of biodesulfurization. Thus, DBT can be quickly transferred to the biocatalyst surface where nanosorbents were located, which quickened DBT transfer from organic phase to biocatalyst surface and resulted in the increase of biodesulfurization rate. The desulfurization rate of the cells assembled with nanosorbents was approximately twofold higher than that of original cells. The cells assembled with nanosorbents were observed by a transmission electron microscope.     

生物脱有机硫催化剂的最新研究进展

生物脱有机硫作为常规的加氢脱硫替代方法近几年受到越来越多的重视,也取得了一些重要的结果,这都推动了生物脱硫向产业化应用。本文简要综述了最近几年通过菌株改造提高催化剂活力和消除无机硫抑制以及脱硫酶系纯化方面所取得一些进展。     

Designing recombinant Pseudomonas strains to enhance biodesulfurization.

The dsz biodesulfurization cluster from Rhodococcus erythropolis IGTS8 has been engineered under the control of heterologous broad-host-range regulatory signals to alleviate the mechanism of sulfur repression, and it was stably inserted into the chromosomes of different Pseudomonas strains. The recombinant bacteria were able to desulfurize dibenzothiophene more efficiently than the native host. Furthermore, these new biocatalysts combine relevant industrial and environmental traits, such as production of biosurfactants, with the enhanced biodesulfurization phenotype.     

硫氧化细菌源单质硫的生成、转运和回收

单质硫(硫粒)是硫化物生物氧化的中间产物.按化学计量式精准调控O/S比(溶解氧与硫化物的摩尔比),单质硫可成为硫氧化细菌(Sulfur-oxidizing bacteria,SOB)的主要代谢产物.根据单质硫的分布,单质硫可分为胞内硫粒和胞外硫粒.单质硫由胞内向胞外的跨膜转运过程是泌硫型SOB的重要生理特征.从生物脱硫...     

石油微生物脱硫的研究进展

随着世界各国环保意识的不断提高及对油品含硫量标准规定日趋严格,生物脱硫技术已成为石油脱硫领域内的研究热点之一。本文主要从生物脱硫分子生物学和嗜热脱硫细菌两个方面介绍了国内外近年来的研究进展。     

Cloning of a rhodococcal promoter using a transposon for dibenzothiophene biodesulfurization

The expression of biodesulfurization genes (dsz) in Rhodococcus erythropolis strain KA2-5-1 is repressed by sulfate which is the product of biodesulfurization. The application of a sulfate non-repressible promoter could be effective in enhancing biodesulfurization. A promoter-probe transposon was constructed using the promoterless, red-shifted green fluorescence protein gene (rsgfp). A 340 bp putative promoter element, designated kap1, was isolated from a strain KA2-5-1 recombinant that had shown high fluorescence intensity. The activity of kap1 was not affected by 1 mM sulfate. It gave about a 2-fold greater activity than the 16S ribosomal RNA promoter in R. erythropolis strain KA2-5-1 and is therefore useful for expressing desulfurization genes in rhodococcal strains.     

Cloning of a rhodococcal promoter using a transposon for dibenzothiophene biodesulfurization

The expression of biodesulfurization genes (dsz) in Rhodococcus erythropolis strain KA2-5-1 is repressed by sulfate which is the product of biodesulfurization. The application of a sulfate non-repressible promoter could be effective in enhancing biodesulfurization. A promoter-probe transposon was constructed using the promoterless, red-shifted green fluorescence protein gene (rsgfp). A 340 bp putative promoter element, designated kap1, was isolated from a strain KA2-5-1 recombinant that had shown high fluorescence intensity. The activity of kap1 was not affected by 1 mM sulfate. It gave about a 2-fold greater activity than the 16S ribosomal RNA promoter in R. erythropolis strain KA2-5-1 and is therefore useful for expressing desulfurization genes in rhodococcal strains.     

Substrate preferences in biodesulfurization of diesel range fuels by Rhodococcus sp. strain ECRD-1

The range of sulfur compounds in fuel oil and the substrate range and preference of the biocatalytic system determine the maximum extent to which sulfur can be removed by biodesulfurization. We show that the biodesulfurization apparatus in Rhodococcus sp. strain ECRD-1 is able to attack all isomers of dibenzothiophene including those with at least four pendant carbons, with a slight preference for those substituted in the alpha-position. With somewhat less avidity, this apparatus is also able to attack substituted benzothiophenes with between two and seven pendant carbons. Some compounds containing sulfidic sulfur are also susceptible to desulfurization, although we have not yet been able to determine their molecular identities.     

Relation between bacterial strain resistance to solvents and biodesulfurization activity in organic medium

Microorganisms used in biodesulfurization of petroleum products have to withstand high concentrations of hydrocarbons. The capacities of seven desulfurizing strains of Rhodococcus to be active in the presence of solvents were evaluated. Octanol and toluene (log P=2.9) were selected as toxic solvents. The effect of the solvents was determined by measuring either inhibition of growth or the decrease in respiratory activity of the cells. Differences among strains in their resistance to solvent responses were observed, but these variations were dependent on the test used. Resistance to solvents was then compared to the capacity of the different strains to retain biodesulfurization activity in the presence of hexadecane. Inhibition of desulfurization by high concentrations of hexadecane was found to be well correlated to the sensitivity of the strains to respiration inhibition by toluene, but not to growth inhibition. This result also showed that the respirometric test was a rapid and reliable test to select solvent-resistant strains for use as resting cells in biocatalysis processes, such as biodesulfurization, in organic media.     

Enhanced dibenzothiophene biodesulfurization in a microchannel reactor

A microchannel reactor system was used in a biodesulfurization process in which the rate of biodesulfurization in the oil/water phase of the microchannel reaction was more than nine-fold that in a batch (control) reaction. In addition, the microchannel reaction system using a bacterial cell suspension degraded alkylated dibenzothiophene that was not degraded by the batch reaction system. This work provides a foundation for the application of a microchannel reactor system consisting of biological catalysts using an oil/water phase reaction.     

Medium composition overturns the widely accepted sulfate-dependent repression of desulfurization phenotype in Rhodococcus qingshengii IGTS8

Microbial desulfurization has been extensively studied as a promising alternative to the widely applied chemical desulfurization process. Sulfur removal from petroleum and its products becomes essential, as the environmental regulations become increasingly stringent. Rhodococcus qingshengii IGTS8 has gained ground as a naturally occurring model biocatalyst, due to its superior specific activity for desulfurization of dibenzothiophene (DBT). Recalcitrant organic sulfur compounds—DBT included—are preferentially removed by selective carbon-sulfur bond cleavage to avoid a reduction in the calorific value of the fuel. The process, however, still has not reached economically sustainable levels, as certain limitations have been identified. One of those bottlenecks is the repression of catalytic activity caused by ubiquitous sulfur sources such as inorganic sulfate, methionine, or cysteine. Herein, we report an optimized culture medium for wild-type stain IGTS8 that completely alleviates the sulfate-mediated repression of biodesulfurization activity without modification of the natural biocatalyst. Medium C not only promotes growth in the presence of several sulfur sources, including DBT, but also enhances biodesulfurization of resting cells grown in the presence of up to 5 mM sulfate. Based on the above, the present work can be considered as a step towards the development of a more viable commercial biodesulfurization process.     

Substrate Preferences in Biodesulfurization of Diesel Range Fuels by Rhodococcus sp. Strain ECRD-1

The range of sulfur compounds in fuel oil and the substrate range and preference of the biocatalytic system determine the maximum extent to which sulfur can be removed by biodesulfurization. We show that the biodesulfurization apparatus in Rhodococcus sp. strain ECRD-1 is able to attack all isomers of dibenzothiophene including those with at least four pendant carbons, with a slight preference for those substituted in the α-position. With somewhat less avidity, this apparatus is also able to attack substituted benzothiophenes with between two and seven pendant carbons. Some compounds containing sulfidic sulfur are also susceptible to desulfurization, although we have not yet been able to determine their molecular identities.     

Improvement of biodesulfurization activity of alginate immobilized cells in biphasic systems

The immobilization of Pseudomonas delafieldii R-8 in calcium alginate beads has been studied in order to improve biodesulfurization activity in oil/water (O/W) biphasic systems. A gas jet extrusion technique was performed to produce immobilized beads. The specific desulfurization rate of 1.5 mm diameter beads was 1.4-fold higher than that of 4.0 mm. Some nonionic surfactants can significantly increase the activity of immobilized cells. The desulfurization rate with the addition of 0.5% Span 80 increased 1.8-fold compared with that of the untreated beads. The rate of biodesulfurization was markedly enhanced by decreasing the size of alginate beads and adding the surfactant Span 80, most likely resulting from the increasing mass transfer of substrate to gel matrix.     

Biodesulfurization: a model system for microbial physiology research

Biological desulfurization (biodesulfurization) of dibenzothiophene (DBT) by the 4S pathway is a model system for an enviromentally benign way to lower the sulfur content of petroleum. Despite a large amount of effort the efficiency of the 4S pathway is still too low for a commercial oil biodesulfurization process, but the 4S pathway could potentially be used now for commercial processes to produce surfactants, antibiotics, polythioesters and other chemicals and for the detoxification of some chemical warfare agents. Proteins containing disulfide bonds are resistant to temperature, pH, and solvents, but the production of disulfide-rich proteins in microbial hosts is challenging. The study of the 4S pathway can provide insights as to how to maximize the production of disulfide-rich proteins. Engineering of the operon encoding the 4S pathway to contain a greater content of methionine and cysteine may be able to link use of DBT as a sole sulfur source to increasing 4S pathway activity by increasing the nutritional demand for sulfur. This strategy could result in the development of biocatalysts suitable for use in an oil biodesulfurization process, but the study of the 4S pathway can also lead to a better understanding of microbial physiology to optimize activity of a mult-step co-factor-requiring pathway, as well as the production of highly stable industrially relevant enzymes for numerous applications.     

Biodesulfurization of refractory organic sulfur compounds in fossil fuels

The stringent new regulations to lower sulfur content in fossil fuels require new economic and efficient methods for desulfurization of recalcitrant organic sulfur. Hydrodesulfurization of such compounds is very costly and requires high operating temperature and pressure. Biodesulfurization is a non-invasive approach that can specifically remove sulfur from refractory hydrocarbons under mild conditions and it can be potentially used in industrial desulfurization. Intensive research has been conducted in microbiology and molecular biology of the competent strains to increase their desulfurization activity; however, even the highest activity obtained is still insufficient to fulfill the industrial requirements. To improve the biodesulfurization efficiency, more work is needed in areas such as increasing specific desulfurization activity, hydrocarbon phase tolerance, sulfur removal at higher temperature, and isolating new strains for desulfurizing a broader range of sulfur compounds. This article comprehensively reviews and discusses key issues, advances and challenges for a competitive biodesulfurization process.     

Use of biotechnology in mining and metallurgy

Biotechnology continued to gain importance in the mineral industry during the past four years. This upsurge of interest is especially expressed in the areas of biodesulfurization of coal, recovery of precious metals from pyrite- and arsenopyrite- containing minerals, biosorption processes and biogenetic engineering.     

Biodesulfurization using Pseudomonas delafieldii in magnetic polyvinyl alcohol beads

AIMS: To immobilize Pseudomonas delafieldii R-8 cells in magnetic polyvinyl alcohol (PVA) beads for biodesulfurization. METHODS AND RESULTS: Magnetic PVA beads were prepared by a freezing-thawing technique under liquid nitrogen. The beads have distinct super-paramagnetic properties and their saturation magnetization is 8.02 emu g(-1). The desulfurization rate of the immobilized cells could reach 40.2 mmol kg(-1) h(-1). Desulfurization patterns of dibenzothiophene in model oil with the immobilized and free cells were represented by the Michaelis-Menten equation. The Michaelis constant for both immobilized and free cells was 1.3 mmol l(-1). CONCLUSIONS: The cells immobilized in magnetic PVA beads could be stably stored and be repeatedly used over 12 times for biodesulfurization. The immobilized cells could be easily separated by magnetic field. SIGNIFICANCE AND IMPACT OF THE STUDY: Magnetic PVA beads are easy to prepare. The immobilization process in the paper is to increase the efficiency of cells and to decrease the cost of operations.     

Reconstruction of a genome-scale metabolic network of Rhodococcus erythropolis for desulfurization studies

The remarkable catabolic diversity of Rhodococcus erythropolis makes it an interesting organism for bioremediation and fuel desulfurization. However, a model that can describe and explain the combined influence of various intracellular metabolic activities on its desulfurizing capabilities is missing from the literature. Such a model can greatly aid the development of R. erythropolis as an effective desulfurizing biocatalyst. This work reports the reconstruction of the first genome-scale metabolic model for R. erythropolis using the available genomic, experimental, and biochemical information. We have validated our in silico model by successfully predicting cell growth results and explaining several experimental observations in the literature on biodesulfurization using dibenzothiophene. We report several in silico experiments and flux balance analyses to propose minimal media, determine gene and reaction essentiality, and compare effectiveness of carbon, nitrogen, and sulfur sources. We demonstrate the usefulness of our model by studying a few in silico mutants of R. erythropolis for improved biodesulfurization, and comparing the desulfurization abilities of R. erythropolis with an in silico mutant of E. coli.