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.     

Desulfurization of 2,4,6,8-tetraethyl dibenzothiophene by recombinant Mycobacterium sp. strain MR65

Recombinant Mycobacterium sp. strain MR65 harboring dszABCD genes was used to desulfurize alkyl dibenzothiophenes (C_x-DBTs) in n-hexadecane. The specific desulfurization activity for 2,4,6,8-tetraethyl DBT (C₈-DBT) by DszC enzyme was about twice that for 4,6-dipropyl DBT (C₆-DBT). However, the degradation rate of 2,4,6,8-tetraethyl DBT in n-hexadecane by resting cells of strain MR65 was only about 40% of that of 4,6-dipropyl DBT. These results indicated that the desulfurization ability for Cx-DBTs by resting cells depends on carbon number substituted at positions 4 and 6 and that the rate-limiting step in the desulfurization reaction of highly alkylated C_x-DBTs is the transfer process from the oil phase into the cell.     

Production of Dicarboxylic Acids by Candida cloacae Mutant Unable to Assimilate n-Alkane

Strain MR-12 which was derived from Candida cloacae M-l as a mutant unable to assimilate n-alkane showed marked increase in dicarboxylic acid (DC) productivity from n-alkane.

Resting cells of strain MR-12 produced 42.7g/liter of n-tetradecane 1,14-dicarboxylic acid (DC-16) from n-hexadecane (n-C₁₆) after 72 hr’ incubation. DC degradation activities of strain M-1 and MR-12 were found to be markedly reduced and their activities against DC-16 decreased to 40% and 10% of that of the parent strain, respectively.

Strain M-1 and MR-12 produced DC from the various oxidized derivatives of n-alkane such as alcohol, diol, aldehyde, fatty acid and methyl- or ethylester of fatty acid other than n-alkane.

The carbon balance in n-C₁₆ oxidation was determined by using resting cells of strain MR-12 and about 60% of utilized carbon was recovered as DC-16 and about 40% was recovered as CO₂.     

Isolation and study of a strain of Candida tropicalis growing on n-alkanes

Summary A strain of Candida tropicalis has been isolated from soil using a mineral medium that contained n-tetradecane as sole source of carbon. This strain has been studied and variants have been isolated. In contrast to the original strain in which hydrocarbon degradation is linked to enzymatic induction mechanisms, the variant 101 behaves like a constitutive strain for n-tetradecane.     

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.     

Isolation and study of the enzymes involved in the metabolism of hydrocarbons by Candida tropicalis

Summary In cell free extracts prepared from protoplasts of n-tetradecane grown cells of Candida tropicalis we have found an ATP and NAD⁺ dependent alkane-dehydrogenase, an alcohol-dehydrogenase, an aldehyde-dehydrogenase and acyl-CoA synthetases. The study of these enzymes and their regulation allows us to propose a scheme of degradation of n-decane.     

Selective Desulfurization of Dibenzothiophene by Rhodococcus erythropolis D-1

A dibenzothiophene (DBT)-degrading bacterium, Rhodococcus erythropolis D-1, which utilized DBT as a sole source of sulfur, was isolated from soil. DBT was metabolized to 2-hydroxybiphenyl (2-HBP) by the strain, and 2-HBP was almost stoichiometrically accumulated as the dead-end metabolite of DBT degradation. DBT degradation by this strain was shown to proceed as DBT → DBT sulfone → 2-HBP. DBT at an initial concentration of 0.125 mM was completely degraded within 2 days of cultivation. DBT at up to 2.2 mM was rapidly degraded by resting cells within only 150 min. It was thought this strain had a higher DBT-desulfurizing ability than other microorganisms reported previously.     

Degradation of dibenzothiophene and its metabolite 3-hydroxy-2-formylbenzothiophene by an environmental isolate

Microbial degradation of dibenzothiophene (DBT) beyond 3-hydroxy-2-formylbenzothiophene (HFBT), a commonly detected metabolite of the Kodama pathway for DBT metabolism, and the catabolic intermediates leading to its mineralization are not fully understood. The enrichment cultures cultivated from crude oil contaminated soil led to isolation of ERI-11; a natural mixed culture, selected for its ability to deplete DBT in basal salt medium (BSM). A bacterial strain isolated from ERI-11, and tentatively named A₁₁, degraded more than 90 % of the initial DBT (270 µM), present as the sole carbon and sulfur source, in 72 h. Gas chromatography–mass spectrophotometry (GC–MS) analyses of the DBT degrading A₁₁ culture medium extracts led to detection of HFBT. The metabolite HFBT, produced using A₁₁, was used in degradation assays to evaluate its metabolism by the bacteria isolated in this study. Ultra violet–visible spectrophotometry and high-performance liquid chromatography analyses established the ability of the strain A₁₁ to deplete HFBT, present as the sole sulfur and carbon source in BSM. GC–MS analyses showed the presence of 2-mercaptobenzoic acid in the HFBT degrading A₁₁ culture extracts. The findings in this study establish that the environmental isolate A₁₁ possesses the metabolic capacity to degrade DBT beyond the metabolite HFBT. The compound 2-mercaptobenzoic acid is an intermediate formed on HFBT degradation by A₁₁.     

Microbial Oxidation of Tetradecanols and Related Substances in Organic Solvents

Microbial oxidations of n-tetradecane, tetradecanols and tetradecanoic acid were investigated by using intact cells of Corynebacterium equi, a hydrocarbon-assimilating bacterium, in an aqueous phase and organic solvents. The bacterial cells were hydrophobic and could be well dispersed in all organic solvents employed to give homogeneous reaction mixtures, and among them, isooctane was found to be the best for the reaction. n-Tetradecane and tetradecanoic acid were completely oxidized in the aqueous phase, but not in isooctane. In contrast, 1-tetradecanol was oxidized much more readily in isooctane than in the aqueous phase, and an oxidation product identified as myristyl myristate was accumulated in isooctane at the conversion rate of 80%. 2-Tetradecanol was also readily oxidized in isooctane, and 2-tetradecanone was obtained at the conversion rate of nearly 100%. Similar results were obtained when toluene and n-hexane were used as the solvent in place of isooctane, while no reaction was observed when chloroform was employed.     

Combining co-culturing of Paenibacillus strains and Vitreoscilla hemoglobin expression as a strategy to improve biodesulfurization

Enhancement of the desulfurization activities of Paenibacillus strains 32O-W and 32O-Y were investigated using dibenzothiophene (DBT) and DBT sulfone (DBTS) as sources of sulphur in growth experiments. Strains 32O-W, 32O-Y and their co-culture (32O-W plus 32O-Y), and Vitreoscilla hemoglobin (VHb) expressing recombinant strain 32O-Yvgb and its co-culture with strain 32O-W were grown at varying concentrations (0·1–2 mmol l⁻¹) of DBT or DBTS for 96 h, and desulfurization measured by production of 2-hydroxybiphenyl (2-HBP) and disappearance of DBT or DBTS. Of the four cultures grown with DBT as sulphur source, the best growth occurred for the 32O-Yvgb plus 32O-W co-culture at 0·1 and 0·5 mmol l⁻¹ DBT. Although the presence of vgb provided no consistent advantage regarding growth on DBTS, strain 32O-W, as predicted by previous work, was shown to contain a partial 4S desulfurization pathway allowing it to metabolize this 4S pathway intermediate.     

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.     

Analysis of Bitter Orange Petitgrain Essential Oil by Combined Gas Chromatography-Mass Spectrometry

Candida catenulata CBS 1904, the previous type strain of C. ravautii, was selected as the best strain for the production of threo-O_s-isocitric acid from water-insoluble carbon sources, non-carbohydrates. The addition of surfactants, lipophilic polyoxyethylene nonyl phenyl ethers, was essential for the acid production, because the cell surface of the strain was less lipophilic. «-Alkanes, ranging from C_n to C_l4, gave the acid in high yields. The acid was produced in ajar fermentor in an about 90% yield on a weight basis as to «-tetradecane supplied. The acid was easily recovered, as crystals of its monopotassium salt, from the concentrated culture broth filtrate.     

Comparative studies of phenotypic and genetic characteristics between two desulfurizing isolates of Rhodococcus erythropolis and the well-characterized R. erythropolis strain IGTS8

Two Rhodococcus erythropolis isolates, named A66 and A69, together with the well-characterized R. erythropolis strain IGTS8 were compared biochemically and genetically. Both isolates, like strain IGTS8, desulfurized DBT to 2-hydroxybiphenyl (2-HBP), following the 4S pathway of desulfurization. Strain IGTS8 showed the highest (81.5%) desulfurization activity in a medium containing DBT at 30 °C. Strain A66 showed approximately the same desulfurization activity either when incubated at 30 °C or at 37 °C, while strain A69 showed an increase of desulfurization efficiency (up to 79%) when incubated at 37 °C. Strains A66 and A69 were also able to grow using various organosulfur or organonitrogen-compounds as the sole sulfur or nitrogen sources. The biological responses of A66, A69 and IGTS8 strains to a series of mutagens and environmental agents were evaluated, trying to mimic actual circumstances involved in exposure/handling of microorganisms during petroleum biorefining. The results showed that strains A69 and IGTS8 were much more resistant to UVC treatment than A66. The three desulfurization genes (dszA, dszB and dszC) present in strains A66 and A69 were partially characterized. They seem to be located on a plasmid, not only in the strain IGTS8, but also in A66 and A69. PCR amplification was observed using specific primers for dsz genes in all the strains tested; however, no amplification product was observed using primers for carbazole (car) or quinoline (qor) metabolisms. All this information contributes to broaden our knowledge concerning both the desulfurization of DBT and the degradation of organonitrogen compounds within the R. erythropolis species.     

Microbial Production of Long-chain Dicarboxylic Acids from n-Alkanes

Strain M-l which was derived from Candida cloacae 310 as a mutant unable to assimilate dicarboxylic acid (DC) produced large amount of DCs from n-alkanes, as expected. It produced DCs with the same number of carbon atoms as those of n-alkanes used (9 to 18 carbon atoms). Among DCs produced, n-tetradecane ω,φ′-dicarboxylic acid (DC-16) from n-hexadecane (n-C₁₆) was most abundantly accumulated and the highest level of DC-16, i.e., 29.3g/liter was obtained by resting cells.

On the other hand, since the growth rate of strain M-l on n-alkane markedly decreased in comparison with that of the parent strain, other carbon source which supported the growth of strain M-l was necessary for the production of DC from n-alkane by growing cells. When acetic acid was used as carbon source for the growth in DC-16 production from n-C₁₆, the highest level of DC-16, i.e., 21.8 g/liter was obtained ofter 3 days' cultivation.     

Verification of Degradation of <Emphasis Type="Italic">n</Emphasis>-Alkanes in Diesel Oil by <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> Strain WatG in Soil Microcosms

Degradation of n-alkanes in diesel oil by Pseudomonas aeruginosa strain WatG (WatG) was verified in soil microcosms. The total petroleum hydrocarbon (TPH) degradation level in two bioaugmentation samples was 51% and 46% for 1 week in unsterilized and sterilized soil microcosms, respectively. The TPH degradation in the biostimulation was of control level (15%). The TPH degradation in aeration-limited samples was clearly reduced when compared with that in aeration-unlimited ones under both sterilized and unsterilized conditions. Addition of WatG into soil microcosms was accompanied by dirhamnolipid production only in the presence of diesel oil. These findings suggest that degradation of n-alkanes in diesel oil in soil microcosms would be facilitated by bioaugmentation of WatG, with production of dirhamnolipid, and also by participation of biostimulated indigenous soil bacteria.     

Directed microbial biosynthesis of deuterated biosurfactants and potential future application to other bioactive molecules

Deuterated rhamnolipids were produced using strain AD7 of Pseudomonas aeruginosa, which was progressively adapted to increasing levels of deuterium in D₂O and carbon substrates. Fourteen different deuterated rhamnolipid structures, including structural isomers, were produced which is similar to normal protonated structures. There were two main products monorhamnolipid Rha-C₁₀-C₁₀ and dirhamnolipid Rha₂-C₁₀-C₁₀. The levels of deuteration varied from 16% with 25% D₂O + h-glycerol to 90% with 100% D₂O + d-glycerol. When d-tetradecane was used with H₂O, virtually all the deuterium appeared in the lipid chains while using h-tetradecane + D₂O led to the majority of deuterium in the sugars. The adaptation to growth in deuterium appeared to be metabolic since no genetic changes could be found in the key rhamnolipid biosynthetic genes, the rhamnosyl transferases RhlB and RhlC. Deuterated sophorolipids were similarly produced using Candida bombicola and Candida apicola although in this case, no adaptation process was necessary. Up to 40 different sophorolipids were produced by these yeasts. However, unlike the rhamnolipids, use of D₂O did not lead to any deuteration of the lipid chains, but direct incorporation into the lipid was achieved using d-isostearic acid. The results from these experiments show the feasibility of producing deuterated bioactive compounds from microorganisms coupled with the possibility of manipulating the pattern of labelling through judicious use of different deuterated substrates.     

Polycyclic Aromatic Hydrocarbon Degradation of Phytoplankton-Associated Arenibacter spp. and Description of Arenibacter algicola sp. nov., an Aromatic Hydrocarbon-Degrading Bacterium

Pyrosequencing of the bacterial community associated with a cosmopolitan marine diatom during enrichment with crude oil revealed several Arenibacter phylotypes, of which one (OTU-202) had become significantly enriched by the oil. Since members of the genus Arenibacter have not been previously shown to degrade hydrocarbons, we attempted to isolate a representative strain of this genus in order to directly investigate its hydrocarbon-degrading potential. Based on 16S rRNA sequencing, one isolate (designated strain TG409^T) exhibited >99% sequence identity to three type strains of this genus. On the basis of phenotypic and genotypic characteristics, strain TG409^T represents a novel species in the genus Arenibacter, for which the name Arenibacter algicola sp. nov. is proposed. We reveal for the first time that polycyclic aromatic hydrocarbon (PAH) degradation is a shared phenotype among members of this genus, indicating that it could be used as a taxonomic marker for this genus. Kinetic data for PAH mineralization rates showed that naphthalene was preferred to phenanthrene, and its mineralization was significantly enhanced in the presence of glass wool (a surrogate for diatom cell surfaces). During enrichment on hydrocarbons, strain TG409^T emulsified n-tetradecane and crude oil, and cells were found to be preferentially attached to oil droplets, indicating an ability by the strain to express cell surface amphiphilic substances (biosurfactants or bioemulsifiers) as a possible strategy to increase the bioavailability of hydrocarbons. This work adds to our growing knowledge on the diversity of bacterial genera in the ocean contributing to the degradation of oil contaminants and of hydrocarbon-degrading bacteria found living in association with marine eukaryotic phytoplankton.     

Poduction of Biotin by Microbial Transformation of dl-cis-Tetrahydro-2-oxo-4-n-pentyl-thieno-(3,4-d)-imidazoline (dl-TOPTI)

The conditions for biotin production were investigated. Urea was a more effective nitrogen source than ammonium chloride and ammonium sulfate. About 60% conversion from dl-cis-tetrahydro-2-oxo-4-n-pentyl-thieno-(3,4-d)-imidazoline (dl-TOPTI) to biotinol and biotin occurred using Corynebacterium sp. B–321. Strain M–6318 which derived from B–321 as a mutant incapable of assimilating n-alkane produced large amounts of dl-biotin from dl-TOPTI. The inability of the microbe to assimilate n-alkane resulted in repression of biotin degradation. Maximum conversion (80%) was obtained by growing cultures of strain M–6318 in the constant presence of n-paraffin.     

The effect ofn-alkanes in the degradation of dibenzothiophene and of organic sulfur compounds in heavy oil by aPseudomonas sp.

Summary The microbial degradation of organic sulfur compounds was examined in aerobic conditions employing a pure culture of aPseudomonas sp., isolated from the soil. The effect ofn-alkanes on the degradation of dibenzothiophene (DBT) showed that the assimilation of the sulfur compound by the microorganism is favoured byn-dodecane. Moreover, the saturated fraction was seen to enhance the degradation of the sulfur compounds to be found in a deasphaltenated heavy oil.     

一株耐碱高效长链烷烃降解菌C24MT1的筛选及其降解特性

【背景】石油被称为“液体黄金”,人类的工业生产活动在利用其创造巨大社会价值的同时,也对自然环境造成了严重的污染。微生物修复技术是现阶段治理石油类污染有效的手段之一,具有经济、高效、无二次污染等优点。【目的】从受石油污染的土壤中分离高效降解长链烷烃正二十四烷的菌株,探究其降解特性及在微生物修复中的应用前景。【方法】通过形态学及16S rRNA基因测序进行菌株鉴定,采用气相色谱法检测菌株对正二十四烷的降解效果,并结合气相色谱-质谱(gas chromatography-mass spectrometer, GC-MS)分析降解中间产物以推测其潜在代谢途径。【结果】筛选到一株可高效降解正二十四烷的菌株C24MT1,经鉴定为不动杆菌属(Acinetobacter)。该菌株最适降解条件为30 °C、pH 9.0、盐度2 g/L,该条件下生长7 d对9 g/L正二十四烷的降解率高达86.63%;与此同时,菌株在强碱性环境(pH 11.0)中生长良好(OD₆₀₀为0.39)并保持较高烷烃降解率(75.38%),对极端环境具备较强的耐受能力;对降解中间产物进行分析,推断菌株代谢长链烷烃正二十四烷的途径可能包括末端氧化及次末端氧化。【结论】不动杆菌C24MT1具有良好的环境适应能力及烷烃降解能力,在后续微生物菌剂开发和石油类污染土壤的环境修复领域具有巨大的应用前景。本研究可为盐碱地区高浓度石油类污染土壤的修复提供优良菌种,并进一步丰富石油烃类生物降解的菌种资源库。