Microbial desulfurization of alkylated dibenzothiophene and alkylated benzothiophene by recombinant Rhodococcus sp. strain T09

The dibenzothiophene (DBT) desulfurizing operon, dsz, was introduced into various benzothiophene (BT)-desulfurizing bacteria using a Rhodococcus-E. coli shuttle vector. Of the tested recombinant bacteria, only those from Rhodococcus sp. strain T09 grew with both DBT and BT as the sole sulfur source. These recombinant cells desulfurized not only alkylated BTs, but also various alkylated DBTs, producing alkylated hydroxybiphenyls as the desulfurized products. Recombinant strain T09 also desulfurized alkylated DBT in an oil-water, two-phase resting-cell reaction. The dsz operon had the same desulfurizing activity when inserted into the vector in either orientation, indicating that the promoter region of the operon was functional in strain T09.     

De-repression and comparison of oil–water separation activity of the dibenzothiophene desulfurizing bacterium, <Emphasis Type="Italic">Mycobacterium</Emphasis> sp. G3

Expression of the desulfurization genes (dsz) in Mycobacterium sp. G3 is repressed by sulfate, which is the product of biodesulfurization. An expression clone, pSMTABC, was constructed by placing the dsz genes downstream of the hsp60 promoter and the constructed plasmid was electroporated into G3. The recombinant strain G3-1 desulfurized dibenzothiophene in the presence of 0.5 mM sulfate while the Dsz phenotype was completely repressed in the wild-type strain. However, there was no significant increase in the amount of desulfurization enzymes in G3-1. In addition, G3 had superior separation of diesel oil–water separation activity compared to E. coli, which is superior to desulfurizing rhodococci.     

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.     

Multi-criteria comparison of resting cell activities of bacterial strains selected for biodesulfurization of petroleum compounds

Five isolates able to utilize dibenzothiophene (DBT) as a sole sulfur source and to convert it to 2-hydroxybiphenyl (HBP) with high rates were selected to investigate their potentialities as biocatalysts of a diesel oil biodesulfurization process. Conventional and chemotaxonomic analyses and 16S ribosomal DNA (rDNA) sequencing showed that these strains belonged to the Rhodococcus/Gordonia cluster. The desulfurizing activities of resting cells were compared under various conditions to evaluate their stability in both aqueous and organic media, their sensitivity to the presence of hexadecane and their sulfur substrate selectivity. In spite of their taxonomic similarity, the five strains exhibited different properties. This diversity was not confirmed by the analysis of the desulfurizing genes by amplification and sequencing of large fragments of dszA, dszB, dszC, and dszD genes which revealed that four of the five selected strains had a dsz genotype identical to those of the reference strain, Rhodococcus erythropolis IGTS8.     

Genomic structure and promoter analysis of the dsz operon for dibenzothiophene biodesulfurization from Gordonia alkanivorans RIPI90A

The bacterium Gordonia alkanivorans RIPI90A has been previously reported as dibenzothiophene-desulfurizing strain. The present study provides a complete investigation of the dsz operon including dsz promoter analysis from desulfurization competent strain belonging to the genus Gordonia. PCR was used to amplify the dszABC genes and adaptor ligation-based PCR-walking strategy used to isolate the dsz promoter. Unlike the dsz operon of Rhodococcus erythropolis, the operon of RIPI90A was located on chromosome. Despite the remarkably high homology between dsz genes of G. alkanivorans RIPI90A and R. erythropolis IGST8, promoter sequences of the strains were not very similar. The dsz promoter of G. alkanivorans RIPI90A shows only 52.5% homology to that of R. erythropolis IGTS8 and Gordonia nitida. Deletion analysis of the dsz promoter from RIPI90A using luciferase as a reporter gene revealed that the dsz promoter was located in regions from −156 to −50.     

Characterization of free and immobilized (<Emphasis Type="Italic">S</Emphasis>)-aminotransferase for acetophenone production

Gordonia amicalis F.5.25.8 has the unique ability to desulfurize dibenzothiophene and to metabolize carbazole [Santos et al., Appl Microbiol Biotechnol 71:355–362, 2006]. Efforts to amplify the dsz genes from G. amicalis F.5.25.8 based on polymerase chain reaction (PCR) primers designed using the dsz gene sequences of Rhodococcus erythropolis IGTS8 were mostly unsuccessful. A comparison of the protein sequences of dissimilar desulfurization enzymes (DszABC, BdsABC, and TdsABC) revealed multiple conserved regions. PCR primers targeting some of the most highly conserved regions of the desulfurization genes allowed us to amplify dsz genes from G. amicalis F.5.25.8. DNA sequence data that include nearly the entirety of the desulfurization operon as well as the promoter region were obtained. The most closely related dsz genes are those of G. alkinovorans strain 1B at 85% identity. The PCR primers reported here should be useful in microbial ecology studies and the amplification of desulfurization genes from previously uncharacterized microbial cultures.     

Desulfurization of dibenzothiophene by Bacillus subtilis recombinants carrying dszABC and dszD genes

The desulfurization (dsz) genes from Rhodococcus erythropolis DS-3 were successfully integrated into the chromosomes of Bacillus subtilis ATCC 21332 and UV1 using an integration vector pDGSDN, yielding two recombinant strains, B. subtilis M29 and M28 in which the integrated dsz genes were expressed efficiently under the promoter, Pspac. The dibenzothiophene (DBT) desulfurization efficiency of M29 was 16.2 mg DBT l⁻¹ h⁻¹ at 36 h, significantly higher than that of R. erythropolis DS−3 and B. subtilis M28 and also showed no product inhibition. The interfacial tension of the supernatant fermented by M29 varied from 48 mN m⁻¹ to 4.2 mN m⁻¹, lower than that of the recombinant strain, M28, reveals that the biosurfactant secreted from M29 may have an important function in the DBT desulfurization process.     

Characterization of Gordonia sp. strain F.5.25.8 capable of dibenzothiophene desulfurization and carbazole utilization

A dibenzothiophene (DBT)-degrading bacterial strain able to utilize carbazole as the only source of nitrogen was identified as Gordonia sp. F.5.25.8 due to its 16S rRNA gene sequence and phenotypic characteristics. Gas chromatography (GC) and GC–mass spectroscopy analyses showed that strain F.5.25.8 transformed DBT into 2-hydroxybiphenyl (2-HBP). This strain was also able to grow using various organic sulfur or nitrogen compounds as the sole sulfur or nitrogen sources. Resting-cell studies indicated that desulfurization occurs either in cell-associated or in cell-free extracts of F.5.25.8. The biological responses of F.5.25.8 to a series of mutagens and environmental agents were also characterized. The results revealed that this strain is highly tolerant to DNA damage and also refractory to induced mutagenesis. Strain F.5.25.8 was also characterized genetically. Results showed that genes involved in desulfurization (dsz) are located in the chromosome, and PCR amplification was observed with primers dszA and dszB designed based on Rhodococcus genes. However, no amplification product was observed with the primer based on dszC.     

Optimization of the copy number of dibenzothiophene desulfurizing genes to increase the desulfurization activity of recombinant Rhodococcus sp.

Dibenzothiophene (DBT) degradation activity of recombinant Rhodococcus sp. T09/pRKPP was increased by about 3.5-fold by introduction of the NAD(P)H/FMN oxidoreductase gene (dszD), while DBT desulfurization activity remained the same with production of dibenzo[1,2]oxathiin-6-oxide, which was caused by insufficient activity of the last desulfurization step involving a desulfinase. Introduction of an additional dsz operon resulted in a 3.3-fold increase DBT desulfurization activity (31 mol g dry cell^–1 h^–1) compared with that of T09/pRKPP (9.5 mol g dry cell^–1 h^–1). Furthermore, optimization of DBT at 25 mg l^–1 and glucose at 10 g l^–1, increased the total DBT desulfurization activity 2- to 3-fold due to increases in the DBT desulfurizing specific activity and the final cell concentration.     

Cloning, sequencing and enhanced expression of the Trichoderma reesei endoxylanase II (pI 9) gene xln2

The Trichoderma reesei xln2 gene coding for the pI 9.0 endoxylanase was isolated from the wild-type strain QM6a. The gene contains one intron of 108 nucleotides and codes for a protein of 223 amino acids in which two putative N-glycosylation target sites were found. Three different T. reesei strains were transformed by targeting a construct composed of the xln2 gene, including its promoter, to the endogenous cbh1 locus. Highest overall production levels of xylanase were obtained using T. reesei ALK02721, a genetically engineered strain, as a host. Integration into the cbh1 locus was not required for enhanced expression under control of the xln2 promoter.     

Sulfur-selective desulfurization of dibenzothiophene and diesel oil by newly isolated Rhodococcus sp. strains

New desulfurizing bacteria able to convert dibenzothiophene into 2-hydroxybiphenyl and sulfate were isolated from contaminated soils collected in Mexican refineries. Random amplified polymorphic DNA analysis showed they were different from previously reported Rhodococcus erythropolis desulfurizing strains. According to 16S rRNA gene sequencing and fatty acid analyses, these new isolates belonged to the genus Rhodococcus. These strains could desulfurize 4,6-dimethyldibenzothiophene which is one of the most difficult dibenzothiophene derivatives to remove by hydrodesulfurization. A deeply hydrodesulfurized diesel oil containing significant amounts of 4,6-dimethyldibenzothiophene was treated with Rhodococcus sp. IMP-S02 cells. Up to 60% of the total sulfur was removed and all the 4,6-dimethyldibenzothiophene disappeared as a result of this treatment.     

Alkylated benzothiophene desulfurization by Rhodococcus sp. strain T09

A benzothiophene desulfurizing bacterium was isolated and identified as Rhodococcus sp. strain T09. Growth assays revealed that this strain assimilated, as the sole sulfur source, various organosulfur compounds that cannot be assimilated by the well-studied dibenzothiophene-desulfurizing Rhodococcus sp. IGTS8. The cellular growth rate of strain T09 for the alkylated benzothiophenes depended on the alkylated position and the length of the alkyl moiety.     

Cultivation of a desulfurizing bacterium, Mycobacterium strain G3

Various carbon and sulfur sources on the growth and desulfurization activity of Mycobacterium strain G3, which is a dibenzothiophene (DBT)-degrading microorganism, were studied. Ethanol, glucose or glycerol as the sole carbon source and MgSO₄, taurine or dimethyl sulfoxide (DMSO) as the sole sulfur source were suitable for the growth. In addition, desulfurization activity was expressed in medium containing taurine, MgSO₄ or DMSO at 0.1 mM, when 217 mM ethanol was used as the sole carbon source. The highest desulfurization activity was in the stationary phase cells after 5 days' growth, rather than those harvested during active growth, when Mycobacterium G3 was cultivated in medium containing 217 mM ethanol and 0.1 mM MgSO₄. Thus alternative sulfur sources to DBT can be used for the cultivation of this desulfurizing microorganism.     

Desulfurization of light gas oil by a novel recombinant strain from Pseudomonas aeruginosa

The dsz desulfurization gene cluster from Rhodococcus erythropolis KA2-5-1 was transferred into the chromosomes of Pseudomonas aeruginosa NCIMB 9571 by using a transposon vector. Resting cells of the recombinant strain, PAR41, desulfurized 63 mg sulfur l^–1 of light gas oil (LGO) containing 360 mg S l^–1. The desulfurization activity for LGO by the resting cells of strain PAR41 grown with n-tetradecane (50% v/v) was much higher (1018-fold) than in glucose-grown cells. P. aeruginosa NCIMB 9571 is able to take up water-insoluble compounds from an oil phase which is enhanced by n-alkane.     

Recombinant Pseudomonas putida carrying both the dsz and hcu genes can desulfurize dibenzothiophene in n-tetradecane

Pseudomonas putida IFO13696, a recombinant strain with dsz desulfurization genes, desulfurized dibenzothiophene (DBT) in water but not in n-tetradecane. By introducing into this recombinant strain the hcuABC genes that take part in the uptake of DBT in the oil phase into the cell, 82% of 1 mM DBT in n-tetradecane was degraded in 24 h by resting cells. The products of hcuABC genes thus acted in the uptake of DBT in n-tetradecane into the cells and were effective in desulfurization of DBT in the hydrocarbon phase.     

Development of HIV-1 protease expression methods using the T7 phage promoter system

New and simple human immunodeficiency virus type 1 (HIV-1) protease expression methods in Escherichia coli were developed using the T7 phage promoter system. In order to suppress leaky HIV-1 protease expression under the control of the T7 polymerase, two new methods were tested. One involved the introduction of supplementary T7 promoter regions into host cells [E. coli BL-21(DE3)] containing the HIV-1 protease gene under the control of the T7 promoter. It was expected that the supplementary T7 promoter regions would compete with the HIV-1 protease expression vector for the T7 polymerase binding. The other involved the infection of late-log-phase cultures of E.␣coli JM109 harboring the same HIV-1 protease expression vector with the M13 phage expressing T7 polymerase. Both methods were effective, and transformants with the mature HIV-1 protease expression vector showed ten times higher HIV-1 protease activity than activities obtained with the autoprocessing vector. The expression systems described here are convenient and are also easily applicable for the expression of other proteins toxic for E. coli. Received: 5 September 1996 / Received last revision: 1 November 1996 / Accepted: 15 November 1996     

Biodesulfurization of dibenzothiophene by a newly isolated Rhodococcus erythropolis strain

A new dibenzothiophene (DBT) desulfurizing bacterium was isolated from oil-contaminated soils in Iran. HPLC analysis and PCR-based detection of the presence of the DBT desulfurization genes (dszA, dszB and dszC) indicate that this strain converts DBT to 2-hydroxybiphenyl (2-HBP) via the 4S pathway. The strain, identified as Rhodococcus erythropolis SHT87, can utilize DBT, dibenzothiophene sulfone, thiophene, 2-methylthiophene and dimethylsulfoxide as a sole sulfur source for growth at 30 °C.The maximum specific desulfurization activity of strain SHT87 resting cells in aqueous and biphasic organic–aqueous systems at 30 °C was determined to be 0.36 and 0.47 μmol 2-HBP min⁻¹ (g dry cell)⁻¹, respectively. Three mM DBT was completely metabolized by SHT87 resting cells in the aqueous and biphasic systems within 10 h. The rate and the extent of the desulfurization reaction by strain SHT87 suggest that this strain can be used for the biodesulfurization of diesel oils.     

In vivo evolution of the Rhodococcus sp. strain DS7: selection of recombinants able to desulfurize both dibenzothiophene and benzothiophene

Rhodococcus sp. DS7, isolated from a polluted soil, has shown good desulfurizing activity towards dibenzothiophene (DBT) and its derivatives, but is not able to desulfurize benzothiophene (BT), the other thiophenic molecule recalcitrant to the chemical hydrodesulfurization (HDS) process, and most abundant in gasoline. To select a Rhodococcus DS7 derivative strain able to desulfurize both DBT and BT, we took advantage of the verified capacity of this strain to integrate exogenous DNA randomly, with a good efficiency. Heterologous chromosomal DNA, digested with restriction enzymes, from two BT but not DBT desulfurizing strains, Rhodococcus sp. ATCC 27778 and Gordonia sp. ATCC 19067, was electroporated into Rhodococcus DS7. Selection on minimal medium with BT as sole sulfur source allowed us to isolate several DS7 derivatives with the capacity to desulfurize both thiophenic molecules. Two strains, one derived from the integration and recombination of DNA from ATCC 27778, and the other from ATCC 19067, have been partially characterized. These recombinant microorganisms are an interesting starting point to develop new biodesulfurization processes.