Identification of Novel Genes Involved in Long-Chain n-Alkane Degradation by Acinetobacter sp. Strain DSM 17874

Acinetobacter sp. strain DSM 17874 is capable of utilizing n-alkanes with chain lengths ranging from that of decane (C₁₀H₂₂) to that of tetracontane (C₄₀H₈₂) as a sole carbon source. Two genes encoding AlkB-type alkane hydroxylase homologues, designated alkMa and alkMb, have been shown to be involved in the degradation of n-alkanes with chain lengths of from 10 to 20 C atoms in this strain. Here, we describe a novel high-throughput screening method and the screening of a transposon mutant library to identify genes involved in the degradation of n-alkanes with C chain lengths longer than 20, which are solid at 30°C, the optimal growth temperature for Acinetobacter sp. strain DSM 17874. A library consisting of approximately 6,800 Acinetobacter sp. strain DSM 17874 transposon mutants was constructed and screened for mutants unable to grow on dotriacontane (C₃₂H₆₆) while simultaneously showing wild-type growth characteristics on shorter-chain n-alkanes. For 23 such mutants isolated, the genes inactivated by transposon insertion were identified. Targeted inactivation and complementation studies of one of these genes, designated almA and encoding a putative flavin-binding monooxygenase, confirmed its involvement in the strain's metabolism of long-chain n-alkanes. To our knowledge, almA represents the first cloned gene shown to be involved in the bacterial degradation of long-chain n-alkanes of 32 C's and longer. Genes encoding AlmA homologues were also identified in other long-chain n-alkane-degrading Acinetobacter strains.     

Alkane‐degrading properties of Dietzia sp. H0B,a key player in the Prestige oil spill biodegradation (NW Spain)

Aims: Investigation of the alkane‐degrading properties of Dietzia sp. H0B, one of the isolated Corynebacterineae strains that became dominant after the Prestige oil spill. Methods and Results: Using molecular and chemical analyses, the alkane‐degrading properties of strain Dietzia sp. H0B were analysed. This Grampositive isolate was able to grow on n‐alkanes ranging from C₁₂ to C₃₈ and branched alkanes (pristane and phytane). 8‐Hexadecene was detected as an intermediate of hexadecane degradation by Dietzia H0B, suggesting a novel alkane‐degrading pathway in this strain. Three putative alkane hydroxylase genes (one alkB homologue and two CYP153 gene homologues of cytochrome P450 family) were PCR‐amplified from Dietzia H0B and differed from previously known hydroxylase genes, which might be related to the novel degrading activity observed on Dietzia H0B. The alkane degradation activity and the alkB and CYP153 gene expression were observed constitutively regardless of the presence of the substrate, suggesting additional, novel pathways for alkane degradation. Conclusions: The results from this study suggest novel alkane‐degrading pathways in Dietzia H0B and a genetic background coding for two different putative oil‐degrading enzymes, which is mostly unexplored and worth to be subject of further functional analysis. Significance and Impact of the Study: This study increases the scarce information available about the genetic background of alkane degradation in genus Dietzia and suggests new pathways and novel expression mechanisms of alkane degradation.     

Multiple alkane hydroxylase systems in a marine alkane degrader, Alcanivorax dieselolei B-5

Alcanivorax dieselolei strain B-5 is a marine bacterium that can utilize a broad range of n-alkanes (C(5) -C(36) ) as sole carbon source. However, the mechanisms responsible for this trait remain to be established. Here we report on the characterization of four alkane hydroxylases from A. dieselolei, including two homologues of AlkB (AlkB1 and AlkB2), a CYP153 homologue (P450), as well as an AlmA-like (AlmA) alkane hydroxylase. Heterologous expression of alkB1, alkB2, p450 and almA in Pseudomonas putida GPo12 (pGEc47ΔB) or P. fluorescens KOB2Δ1 verified their functions in alkane oxidation. Quantitative real-time RT-PCR analysis showed that these genes could be induced by alkanes ranging from C(8) to C(36) . Notably, the expression of the p450 and almA genes was only upregulated in the presence of medium-chain (C(8) -C(16) ) or long-chain (C(22) -C(36) ) n-alkanes, respectively; while alkB1 and alkB2 responded to both medium- and long-chain n-alkanes (C(12) -C(26) ). Moreover, branched alkanes (pristane and phytane) significantly elevated alkB1 and almA expression levels. Our findings demonstrate that the multiple alkane hydroxylase systems ensure the utilization of substrates of a broad chain length range.     

Genome Sequence of the Alkane-Degrading Bacterium Alcanivorax hongdengensis Type Strain A-11-3

Alcanivorax hongdengensis A-11-3^T was isolated from an oil-enriched consortium enriched from the surface seawater of Hong-Deng dock in the Straits of Malacca and Singapore. Strain A-11-3^T can degrade n-alkane and produce a lipopeptide biosurfactant. Here we report the genome of A-11-3^T and the genes associated with alkane degradation.     

红灯食烷菌(Alcanivorax hongdengensis)黄素结合单加氧酶(AlmA)的基因克隆及其烷烃诱导表达

【目的】研究海洋烷烃降解菌新种模式菌株Alcanivorax hongdengensis A-11-3降解长链烷烃的分子机制。【方法】PCR克隆编码黄素结合单加氧酶的基因序列,利用生物信息学软件对序列进行分析,运用RT-PCR和实时荧光定量PCR技术分析基因在不同烷烃诱导下的表达水平。【结果】从菌株A-11-3中克隆获得了两个黄素结合单加氧酶基因片段(almA1和almA2)。它们编码的氨基酸序列与菌株Acinetobacter sp.DSM17874的AlmA同源性分别为58.6%和53.2%。实时荧光定量PCR分析表明,almA1基因只在长链烷烃(C28-C32)的诱导下上调表达,而almA2基因中能在更宽范围的长链烷烃(C24-C34)和支链烷烃诱导下上调表达。两者均在C9-C22的烷烃诱导下没有上调表达。【结论】黄素结合单加氧酶可能是A-11-3降解长链烷烃和支链烷烃的关键酶。     

Growth, natural relationships, cellular fatty acids and metabolic adaptation of sulfate-reducing bacteria that utilize long-chain alkanes under anoxic conditions

Natural relationships, improvement of anaerobic growth on hydrocarbons, and properties that may provide clues to an understanding of oxygen-independent alkane metabolism were studied with two mesophilic sulfate-reducing bacteria, strains Hxd3 and Pnd3. Strain Hxd3 had been formerly isolated from an oil tank; strain Pnd3 was isolated from marine sediment. Strains Hxd3 and Pnd3 grew under strictly anoxic conditions on n-alkanes in the range of C₁₂–C₂₀ and C₁₄–C₁₇, respectively, reducing sulfate to sulfide. Both strains shared 90% 16 S rRNA sequence similarity and clustered with classified species of completely oxidizing, sulfate-reducing bacteria within the δ-subclass of Proteobacteria. Anaerobic growth on alkanes was stimulated by α-cyclodextrin, which served as a non-degradable carrier for the hydrophobic substrate. Cells of strain Hxd3 grown on hydrocarbons and α-cyclodextrin were used to study the composition of cellular fatty acids and in vivo activities. When strain Hxd3 was grown on hexadecane (C₁₆H₃₄), cellular fatty acids with C-odd chains were dominant. Vice versa, cultures grown on heptadecane (C₁₇H₃₆) contained mainly fatty acids with C-even chains. In contrast, during growth on 1-alkenes or fatty acids, a C-even substrate yielded C-even fatty acids, and a C-odd substrate yielded C-odd fatty acids. These results suggest that anaerobic degradation of alkanes by strain Hxd3 does not occur via a desaturation to the corresponding 1-alkenes, a hypothetical reaction formerly discussed in the literature. Rather an alteration of the carbon chain by a C-odd carbon unit is likely to occur during activation; one hypothetical reaction is a terminal addition of a C₁ unit. In contrast, fatty acid analyses of strain Pnd3 after growth on alkanes did not indicate an alteration of the carbon chain by a C-odd carbon unit, suggesting that the initial reaction differed from that in strain Hxd3. When hexadecane-grown cells of strain Hxd3 were resuspended in medium with 1-hexadecene, an adaptation period of 2 days was observed. Also this result is not in favor of an anaerobic alkane degradation via the corresponding 1-alkene. Received: 25 June 1998 / Accepted: 29 July 1998     

Cloning and expression of three ladA-type alkane monooxygenase genes from an extremely thermophilic alkane-degrading bacterium Geobacillus thermoleovorans B23

An extremely thermophilic bacterium, Geobacillus thermoleovorans B23, is capable of degrading a broad range of alkanes (with carbon chain lengths ranging between C11 and C32) at 70 °C. Whole-genome sequence analysis revealed that unlike most alkane-degrading bacteria, strain B23 does not possess an alkB-type alkane monooxygenase gene. Instead, it possesses a cluster of three ladA-type genes, ladAα_B23, ladAβ_B23, and ladB _B23, on its chromosome, whose protein products share significant amino acid sequence identities, 49.8, 34.4, and 22.7 %, respectively, with that of ladA alkane monooxygenase gene found on a plasmid of Geobacillus thermodetrificans NG 80-2. Each of the three genes, ladAα_B23, ladAβ_B23, and ladB _B23, was heterologously expressed individually in an alkB1 deletion mutant strain, Pseudomonas fluorescens KOB2Δ1. It was found that all three genes were functional in P. fluorescens KOB2Δ1, and partially restored alkane degradation activity. In this study, we suggest that G. thermoleovorans B23 utilizes multiple LadA-type alkane monooxygenases for the degradation of a broad range of alkanes.     

ANALYSIS OF N-ALKANES FROM THREE SPECIES OF CLARKIA

Sixteen n-alkanes were isolated and identified from the herb Clarkia unguiculata, fourteen from C. exilis and seven from C. tembloriensis. These alkanes ranged from C₂₀H₄₂ to C₃₅H₇₂. In all three taxa, the odd numbered alkanes were generally present in greater quantities than even numbered ones, which is similar to the alkane patterns of Monarda that were observed in our laboratories. Clarkia tembloriensis has a characteristically high percentage (95%) of the C₂₀ alkane.     

Effects of Chain-length of Alkane Substrate on Fatty Acid Composition and Biosynthetic Pathway in Some Candida Yeasts

Cellular fatty acid compositions of Candida tropicalis pK 233 and Candida lipolytica NRRL Y -6795 and the time-course changes during yeast growth were studied using individual n-alkanes of various chain lengths (from C₁₁ to C₁₈) and a mixture of n-alkanes (C₁₁ to C₁₈) as a sole carbon source. Observed relationships of the chain-length of n-alkane substrate to time-course changes and final patterns of the fatty acid compositions of these yeasts, especially those of the cells grown on odd-carbon alkanes, indicated that “intact incorporation mechanism,” that is, accumulation of the fatty acid having the same chain-length as that of the alkane substrate used was predominant in the yeasts cultivated on a longer alkane such as n-heptadecane and n-octadecane. On the other hand, “chain elongation pathway” and “de novo synthesis pathway” following β-oxidation of substrate were simultaneously operative in the cells growing on a relatively shorter alkane such as undecane and dodecane.     

The Rheology of 6-Propyl Duodecane and 5-Dibutyl Nonane by Non-Equilibrium Molecular Dynamics Simulations

Abstract

In recent papers, we reported non-equilibrium molecular dynamics (NEMD) simulations of planar Couette flow for liquid n- and i-butane, and liquid n-decane and 4-propyl heptane, using two collapsed atom models and an atomistically detailed model. It was found that the collapsed atom models predict the viscosities of the n-butane and n-decane quite well, and that the atomistically detailed model does not yield quantitative agreement with the viscosity of the n-alkanes or the branched alkanes, but it does have the one positive feature that the calculated viscosities of the branched alkanes are higher than these of the n-alkanes. In the present paper, we report results of NEMD simulations of planar Couette flow for liquid 6-propyl duodecane and 5-dibutyl nonane at 296 K and 0.782 g/cc, using an expanded collapsed atom model for simplicity. The strain rate dependent viscosity shows three different regions—two shear thinning ones and a Newtonian one. The slopes of the log-log plot for the branched-chain alkanes at high strain rate are different from those at intermediate strain rate, which is characterized as a rheological behavior of branched-chain alkanes. The Newtonian viscosity of the branched-chain alkanes can be extrapolated from the plateau value of the strain rate dependent viscosity at low strain rate as for straight-chain alkanes [J. Chem. Phys., 105, 1214 (1996)]. The results indicate that more-branched alkanes have a larger viscosity than less-branched C₁₇ alkanes.     

Differential protein expression during growth on linear versus branched alkanes in the obligate marine hydrocarbon-degrading bacterium Alcanivorax borkumensis SK2T

Alcanivorax borkumensis SK2^T is an important obligate hydrocarbonoclastic bacterium (OHCB) that can dominate microbial communities following marine oil spills. It possesses the ability to degrade branched alkanes which provides it a competitive advantage over many other marine alkane degraders that can only degrade linear alkanes. We used LC–MS/MS shotgun proteomics to identify proteins involved in aerobic alkane degradation during growth on linear (n-C₁₄) or branched (pristane) alkanes. During growth on n-C₁₄, A. borkumensis expressed a complete pathway for the terminal oxidation of n-alkanes to their corresponding acyl-CoA derivatives including AlkB and AlmA, two CYP153 cytochrome P450s, an alcohol dehydrogenase and an aldehyde dehydrogenase. In contrast, during growth on pristane, an alternative alkane degradation pathway was expressed including a different cytochrome P450, an alcohol oxidase and an alcohol dehydrogenase. A. borkumensis also expressed a different set of enzymes for β-oxidation of the resultant fatty acids depending on the growth substrate utilized. This study significantly enhances our understanding of the fundamental physiology of A. borkumensis SK2^T by identifying the key enzymes expressed and involved in terminal oxidation of both linear and branched alkanes. It has also highlights the differential expression of sets of β-oxidation proteins to overcome steric hinderance from branched substrates.     

Identification of alkane hydroxylase genes in Rhodococcus sp. strain TMP2 that degrades a branched alkane

Rhodococcus sp. TMP2 is an alkane-degrading strain that can grow with a branched alkane as a sole carbon source. TMP2 degrades considerable amounts of pristane at 20 degrees C but not at 30 degrees C. In order to gain insights into microbial alkane degradation, we characterized one of the key enzymes for alkane degradation. TMP2 contains at least five genes for membrane-bound, non-heme iron, alkane hydroxylase, known as AlkB (alkB1-5). Phylogenetical analysis using bacterial alkB genes indicates that TMP2 is a close relative of the alkane-degrading bacteria, such as Rhodococcus erythropolis NRRL B-16531 and Q15. RT-PCR analysis showed that expressions of the genes for AlkB1 and AlkB2 were apparently induced by the addition of pristane at a low temperature. The results suggest that TMP2 recruits certain alkane hydroxylase systems to utilize a branched alkane under low temperature conditions.     

Identification of different alkane hydroxylase systems in Rhodococcus ruber strain SP2B,an hexane‐degrading actinomycete

Aims: To investigate the alkane‐hydroxylating system of isolate SP2B, closely related to Rhodococcus ruber DSM 43338^T and uncharacterized so far for its alkane degradation genes. Methods and Results: Although isolate SP2B and reference strain can grow on by‐products from hexane degradation, the type strain R. ruber was unable, unlike SP2B isolate, to use short‐chain alkanes, as assessed by gas chromatography. Using PCR with specific or degenerated primers, inverse PCR and Southern blot, two alkane hydroxylase encoding genes (alkB) were detected in both bacteria, which is in agreement with their alkane range. The first AlkB was related to Rhodococcus AlkB7 enzymes and contains a nonbulky residue at a specific position, suggesting it might be involved in medium‐ and long‐chain alkane oxidation. The second partial alkB gene potentially belongs to alkB5‐type, which was found in bacteria unable to use hexane. Moreover, a partial P450 cytochrome alkane hydroxylase, thought to be responsible for the hexane degradation, was detected only in the isolated strain. Conclusions: Rhodococcus ruber SP2B should prove to be a promising candidate for bioremediation studies of contaminated sites because of its large degradation range of alkanes. Significance and Impact of the Study: This is the first thorough study on R.ruber alkane degradation systems.     

Microaerophilic alkane degradation in <Emphasis Type="Italic">Pseudomonas extremaustralis</Emphasis>: a transcriptomic and physiological approach

Diesel fuel is one of the most important sources of hydrocarbon contamination worldwide. Its composition consists of a complex mixture of n-alkanes, branched alkanes and aromatic compounds. Hydrocarbon degradation in Pseudomonas species has been mostly studied under aerobic conditions; however, a dynamic spectrum of oxygen availability can be found in the environment. Pseudomonas extremaustralis, an Antarctic bacterium isolated from a pristine environment, is able to degrade diesel fuel and presents a wide microaerophilic metabolism. In this work RNA-deep sequence experiments were analyzed comparing the expression profile in aerobic and microaerophilic cultures. Interestingly, genes involved in alkane degradation, including alkB, were over-expressed in micro-aerobiosis in absence of hydrocarbon compounds. In minimal media supplemented with diesel fuel, n-alkanes degradation (C13–C19) after 7 days was observed under low oxygen conditions but not in aerobiosis. In-silico analysis of the alkB promoter zone showed a putative binding sequence for the anaerobic global regulator, Anr. Our results indicate that some diesel fuel components can be utilized as sole carbon source under microaerophilic conditions for cell maintenance or slow growth in a Pseudomonas species and this metabolism could represent an adaptive advantage in polluted environments.     

Structure and Biosynthesis of Cuticular Lipids: Hydroxylation of Palmitic Acid and Decarboxylation of C(28), C(30), and C(32) Acids in Vicia faba Flowers

The structure and composition of the cutin monomers from the flower petals of Vicia faba were determined by hydrogenolysis (LiAlH₄) or deuterolysis (LiAlD₄) followed by thin layer chromatography and combined gas-liquid chromatography and mass spectrometry. The major components were 10, 16-dihydroxyhexadecanoic acid (79.8%), 9, 16-dihydroxyhexadecanoic acid (4.2%), 16-hydroxyhexadecanoic acid (4.2%), 18-hydroxyoctadecanoic acid (1.6%), and hexadecanoic acid (2.4%). These results show that flower petal cutin is very similar to leaf cutin of V. faba. Developing petals readily incorporated exogenous [1-¹⁴C]palmitic acid into cutin. Direct conversion of the exogeneous acid into 16-hydroxyhexadecanoic acid, 10, 16-dihydroxy-, and 9, 16-dihydroxyhexadecanoic acid was demonstrated by radio gas-liquid chromatography of their chemical degradation products. About 1% of the exogenous [1-¹⁴C]palmitic acid was incorporated into C₂₇, C₂₉, and C₃₁n-alkanes, which were identified by combined gas-liquid chromatography and mass spectrometry as the major components of the hydrocarbons of V. faba flowers. The radioactivity distribution among these three alkanes (C₂₇, 15%; C₂₉, 48%; C₃₁, 38%) was similar to the per cent composition of the alkanes (C₂₇, 12%; C₂₉, 43%; C₃₁, 44%). [1-¹⁴C]Stearic acid was also incorporated into C₂₇, C₂₉, and C₃₁n-alkanes in good yield (3%). Trichloroacetate, which has been postulated to be an inhibitor of fatty acid elongation, inhibited the conversion of [1-¹⁴C]stearic acid to alkanes, and the inhibition was greatest for the longer alkanes. Developing flower petals also incorporated exogenous C₂₈, C₃₀, and C₃₂ acids into alkanes in 0.5% to 5% yields. [G-³H]n-octacosanoic acid (C₂₈) was incorporated into C₂₇, C₂₉, and C₃₁n-alkanes. [G-³H]n-triacontanoic acid (C₃₀) was incorporated mainly into C₂₉ and C₃₁ alkanes, whereas [9, 10, 11-³H]n-dotriacontanoic acid (C₃₂) was converted mainly to C₃₁ alkane. Trichloroacetate inhibited the conversion of the exogenous acids into alkanes with carbon chains longer than the exogenous acid, and at the same time increased the amount of the direct decarboxylation product formed. These results clearly demonstrate direct decarboxylation as well as elongation and decarboxylation of exogenous fatty acids, and thus constitute the most direct evidence thus far obtained for an elongation-decarboxylation mechanism for the biosynthesis of alkanes.     

Effects of gasoline components on MTBE and TBA cometabolism by <Emphasis Type="Italic">Mycobacterium austroafricanum</Emphasis> JOB5

In this study we have examined the effects of individual gasoline hydrocarbons (C_5–10,12,14 n-alkanes, C_5–8 isoalkanes, alicyclics [cyclopentane and methylcyclopentane] and BTEX compounds [benzene, toluene, ethylbenzene, m-, o-, and p-xylene]) on cometabolism of methyl tertiary butyl ether (MTBE) and tertiary butyl alcohol (TBA) by Mycobacterium austroafricanum JOB5. All of the alkanes tested supported growth and both MTBE and TBA oxidation. Growth on C_5–8 n-alkanes and isoalkanes was inhibited by acetylene whereas growth on longer chain n-alkanes was largely unaffected by this gas. However, oxidation of both MTBE and TBA by resting cells was consistently inhibited by acetylene, irrespective of the alkane used as growth-supporting substrate. A model involving two separate but co-expressed alkane-oxidizing enzyme systems is proposed to account for these observations. Cyclopentane, methylcyclopentane, benzene and ethylbenzene did not support growth but these compounds all inhibited MTBE and TBA oxidation by alkane-grown cells. In the case of benzene, the inhibition was shown to be due to competitive interactions with both MTBE and TBA. Several aromatic compounds (p-xylene > toluene > m-xylene) did support growth and cells previously grown on these substrates also oxidized MTBE and TBA. Low concentrations of toluene (<10 μM) stimulated MTBE and TBA oxidation by alkane-grown cells whereas higher concentrations were inhibitory. The effects of acetylene suggest strain JOB5 also has two distinct toluene-oxidizing activities. These results have been discussed in terms of their impact on our understanding of MTBE and TBA cometabolism and the enzymes involved in these processes in mycobacteria and other bacteria.     

Functional characterization of two alkane hydroxylases in a versatile <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> strain NY3

Pseudomonas aeruginosa strain NY3 has an extraordinary capacity to utilize a wide range of substrates, including n–alkanes of lengths C₅ to C₃₄, aromatic compounds, phenols, diesel and crude oil, and it can produce a variety of small bioactive molecules, including rhamnolipids, which can enhance its metabolic capacity for hydrophobic organic pollutants. This capacity makes NY3 a good candidate for use in environmental pollution remediation. Alkane hydroxylases catalyze both the initial and rate-limiting step of the terminal oxidation of n–alkanes. To better understand the genetic mechanisms by which P. aeruginosa NY3 degrades such a wide range of n–alkanes, two putative coding genes of alkane hydroxylases were functionally characterized using a gene-knockout approach with three different degradation systems. The single n–alkane test indicated that the hydroxylase AlkB2 acted in the early growth phase and played a major role in the utilization of C₁₂–C₁₈. However, a double mutant showed a trend towards recovery when C₂₀–C₂₄ were used as sole carbon source. This suggests that there are other enzymes capable of utilizing n–alkanes longer than C₂₀. Tests of both artificial n–alkanes mixture and crude oil-containing waste water showed similar results, suggesting that both AlkB1 and AlkB2 are involved in n–alkane degradation, and, moreover, that AlkB2 plays a major role. Finally, given the wider functional range of both AlkBs in the mixture of n–alkanes compared to that of single n–alkanes, these results hint at co-metabolism.     

Assessing the role of alkane hydroxylase genotypes in environmental samples by competitive PCR

AIMS: A molecular tool for extensive detection of prokaryotic alkane hydroxylase genes (alkB) was developed. AlkB genotypes involved in the degradation of short-chain alkanes were quantified in environmental samples in order to assess their occurrence and ecological importance. METHODS AND RESULTS: Four primer pairs specific for distinct clusters of alkane hydroxylase genes were designed, allowing amplification of alkB-related genes from all tested alkane-degrading strains and from six of seven microcosms. For the primer pair detecting alkB genes related to the Pseudomonas putida GPo1 alkB gene and the one targeting alkB genes of Gram-positive strains, both involved in short-chain alkane degradation (相似文献