Diane Labbé

Characterization of Hydrocarbon-Degrading Microbial Populations in Contaminated and Pristine Alpine Soils

ABSTRACT Biodegradation of petroleum hydrocarbons in cold environments, including Alpine soils, is a result of indigenous cold-adapted microorganisms able to degrade these contaminants. In the present study, the prevalence of seven genotypes involved in the degradation of n-alkanes (Pseudomonas putida GPo1 alkB; Acinetobacter spp. alkM; Rhodococcus spp. alkB1, and Rhodococcus spp. alkB2), aromatic hydrocarbons (P. putida xylE), and polycyclic aromatic hydrocarbons (P. putida ndoB and Mycobacterium sp. strain PYR-1 nidA) was determined in 12 oil-contaminated (428 to 30,644 mg of total petroleum hydrocarbons [TPH]/kg of soil) and 8 pristine Alpine soils from Tyrol (Austria) by PCR hybridization analyses of total soil community DNA, using oligonucleotide primers and DNA probes specific for each genotype. The soils investigated were also analyzed for various physical, chemical, and microbiological parameters, and statistical correlations between all parameters were determined. Genotypes containing genes from gram-negative bacteria (P. putida alkB, xylE, and ndoB and Acinetobacter alkM) were detected to a significantly higher percentage in the contaminated (50 to 75%) than in the pristine (0 to 12.5%) soils, indicating that these organisms had been enriched in soils following contamination. There was a highly significant positive correlation (P < 0.001) between the level of contamination and the number of genotypes containing genes from P. putida and Acinetobacter sp. but no significant correlation between the TPH content and the number of genotypes containing genes from gram-positive bacteria (Rhodococcus alkB1 and alkB2 and Mycobacterium nidA). These genotypes were detected at a high frequency in both contaminated (41.7 to 75%) and pristine (37.5 to 50%) soils, indicating that they are already present in substantial numbers before a contamination event. No correlation was found between the prevalence of hydrocarbon-degradative genotypes and biological activities (respiration, fluorescein diacetate hydrolysis, lipase activity) or numbers of culturable hydrocarbon-degrading soil microorganisms; there also was no correlation between the numbers of hydrocarbon degraders and the contamination level. The measured biological activities showed significant positive correlation with each other, with the organic matter content, and partially with the TPH content and a significant negative correlation with the soil dry-mass content (P < 0.05 to 0.001).

Gene Cloning and Characterization of Multiple Alkane Hydroxylase Systems in Rhodococcus Strains Q15 and NRRL B-16531

ABSTRACT The alkane hydroxylase systems of two Rhodococcus strains (NRRL B-16531 and Q15, isolated from different geographical locations) were characterized. Both organisms contained at least four alkane monooxygenase gene homologs (alkB1, alkB2, alkB3, and alkB4). In both strains, the alkB1 and alkB2 homologs were part of alk gene clusters, each encoding two rubredoxins (rubA1 and rubA2; rubA3 and rubA4), a putative TetR transcriptional regulatory protein (alkU1; alkU2), and, in the alkB1 cluster, a rubredoxin reductase (rubB). The alkB3 and alkB4 homologs were found as separate genes which were not part of alk gene clusters. Functional heterologous expression of some of the rhodococcal alk genes (alkB2, rubA2, and rubA4 [NRRL B-16531]; alkB2 and rubB [Q15]) was achieved in Escherichia coli and Pseudomonas expression systems. Pseudomonas recombinants containing rhodococcal alkB2 were able to mineralize and grow on C12 to C16n-alkanes. All rhodococcal alkane monooxygenases possessed the highly conserved eight-histidine motif, including two apparent alkane monooxygenase signature motifs (LQRH[S/A]DHH and NYXEHYG[L/M]), and the six hydrophobic membrane-spanning regions found in all alkane monooxygenases related to the Pseudomonas putida GPo1 alkane monooxygenase. The presence of multiple alkane hydroxylases in the two rhodococcal strains is reminiscent of other multiple-degradative-enzyme systems reported in Rhodococcus.

Prevalence of alkane monooxygenase genes in Arctic and Antarctic hydrocarbon-contaminated and pristine soils.

Abstract The prevalence of four alkane monooxygenase genotypes (Pseudomonas putida GPo1, Pp alkB; Rhodococcus sp. strain Q15, Rh alkB1 and Rh alkB2; and Acinetobacter sp. strain ADP-1, Ac alkM) in hydrocarbon-contaminated and pristine soils from the Arctic and Antarctica were determined by both culture-independent (PCR hybridization analyses) and culture-dependent (colony hybridization analyses) molecular methods, using oligonucleotide primers and DNA probes specific for each of the alk genotypes. PCR hybridization of total soil community DNA detected the rhodococcal alkB genotypes in most of the contaminated (Rh alkB1, 18/20 soils; Rh alkB2, 13/20) and many pristine soils (Rh alkB1, 9/10 soils; Rh alkB2, 7/10), while Pp alkB was generally detected in the contaminated soils (15/20) but less often in pristine soils (5/10). Ac alkM was rarely detected in the soils (1/30). The colony hybridization technique was used to determine the prevalence of each of the alk genes and determine their relative abundance in culturable cold-adapted (5 degrees C) and mesophilic populations (37 degrees C) from eight of the polar soils. The cold-adapted populations, in general, possessed relatively higher percentages of the Rh alkB genotypes (Rh alkB1, 1.9% (0.55); Rh alkB2, 2.47% (0.89)), followed by the Pp alkB (1.13% (0.50)), and then the Ac alkM (0.53% (0.36)). The Rh alkB1 genotype was clearly more prevalent in culturable cold-adapted bacteria (1.9% (0.55)) than in culturable mesophiles (0.41 (0.55)), suggesting that cold-adapted bacteria are the predominant organisms possessing this genotype. Overall, these results indicated that (i) Acinetobacter spp. are not predominant members of polar alkane degradative microbial communities, (ii) Pseudomonas spp. may become enriched in polar soils following contamination events, and (iii) Rhodococcus spp. may be the predominant alkane-degradative bacteria in both pristine and contaminated polar soils.

Identification of a membrane protein and a truncated LysR-type regulator associated with the toluene degradation pathway in Pseudomonas putida F1

A 3 kb DNA region upstream of the toluene degradation (tod) genes, todFC1C2BADEGIH, in Pseudomonas putida F1 (PpF1) was sequenced. Two divergently arranged open reading frames, todR and todX, were identified. A toluene-inducible promoter was localized in front of todX, and the transcription start point was mapped. This promoter is probably responsible for the expression of all tod structural genes. TodX was found to be a membrane protein. Its predicted amino acid sequence (453 residues; Mr 48265) exhibits considerable similarity with the FadL protein of Escherichia coli, an outer membrane protein required for binding and transport of long-chain fatty acids. An apparent function of TodX is likely to be involved in facilitating the delivery of exogenous toluene inside the PpF1 cells. The sequence of TodR (100 residues) exhibits extensive homology with the DNA-binding domain of transcriptional activators of the LysR family, but todR was found to have a negligible role in tod gene regulation.

Degradation of a mixture of hydrocarbons, gasoline, and diesel oil additives by Rhodococcus aetherivorans and Rhodococcus wratislaviensis.

ABSTRACT Two strains, identified as Rhodococcus wratislaviensis IFP 2016 and Rhodococcus aetherivorans IFP 2017, were isolated from a microbial consortium that degraded 15 petroleum compounds or additives when provided in a mixture containing 16 compounds (benzene, toluene, ethylbenzene, m-xylene, p-xylene, o-xylene, octane, hexadecane, 2,2,4-trimethylpentane [isooctane], cyclohexane, cyclohexanol, naphthalene, methyl tert-butyl ether [MTBE], ethyl tert-butyl ether [ETBE], tert-butyl alcohol [TBA], and 2-ethylhexyl nitrate [2-EHN]). The strains had broad degradation capacities toward the compounds, including the more recalcitrant ones, MTBE, ETBE, isooctane, cyclohexane, and 2-EHN. R. wratislaviensis IFP 2016 degraded and mineralized to different extents 11 of the compounds when provided individually, sometimes requiring 2,2,4,4,6,8,8-heptamethylnonane (HMN) as a cosolvent. R. aetherivorans IFP 2017 degraded a reduced spectrum of substrates. The coculture of the two strains degraded completely 13 compounds, isooctane and 2-EHN were partially degraded (30% and 73%, respectively), and only TBA was not degraded. Significant MTBE and ETBE degradation rates, 14.3 and 116.1 μmol of ether degraded h−1 g−1 (dry weight), respectively, were measured for R. aetherivorans IFP 2017. The presence of benzene, toluene, ethylbenzene, and xylenes (BTEXs) had a detrimental effect on ETBE and MTBE biodegradation, whereas octane had a positive effect on the MTBE biodegradation by R. wratislaviensis IFP 2016. BTEXs had either beneficial or detrimental effects on their own degradation by R. wratislaviensis IFP 2016. Potential genes involved in hydrocarbon degradation in the two strains were identified and partially sequenced.

Bioremediation treatability assessment of hydrocarbon-contaminated soils from Eureka, Nunavut

Abstract The bioremediation potential of three hydrocarbon-contaminated soil samples with diverse soil physical/chemical characteristics from Eureka, Ellesmere Island, Nunavut, was assessed. Microbial enumeration by viable plate counts and MPN analyses combined with molecular analysis (PCR and colony hybridization) for hydrocarbon catabolic genes (alkB+, xylE+, ndoB+) demonstrated the presence of significant numbers of aerobic cold-adapted hydrocarbon-degrading organisms in the three contaminated soils. The degradative activities of the indigenous microbial populations were assessed by mineralization of 14C-labelled hexadecane (C16) and naphthalene at 5°C or 23°C in untreated and treated soil microcosms. Although very low rates of C16 and naphthalene mineralization were observed in untreated microcosms, nutrient supplementation with a commercial inorganic fertilizer (20:20:20) markedly increased mineralization in the soil microcosms, indicating that these soil are nutrient-deficient. Increasing the incubation temperature to 23°C markedly decreased the acclimation period and increased the rate of mineralization in soil microcosms supplemented with 20:20:20. Optimal treatments resulting in the greatest rates and levels of mineralization for each soil were determined: Soil #1, 20:20:20+tilling; Soil #2, 20:20:20+peat moss; Soil #3, 20:20:20+water to 60% WHC. Total petroleum hydrocarbon (TPH) analysis of cold soil microcosms revealed that, similar to the soil mineralization assays, the optimal treatments increased TPH degradation compared with fertilizer treatment alone. TPH levels in the contaminated Eureka soils were reduced from 5166 to 2966 ppm in Soil #1, from ∼4256 to 2466 ppm in Soil #2, and from 4500 to 1933 ppm in Soil #3 following the appropriate treatment after 16 weeks incubation at 5°C. These results indicate that the bioremediation potential of the Eureka soils at low ambient summer temperatures is considerable. It is suggested that the on-site treatment planned for the 2000 summer include the application of a commercial fertilizer and, if feasible, additional treatments such as tilling, addition of peat moss, or water, depending on the contaminated soils physical/chemical characteristics.

Sequence and expression of the todGIH genes involved in the last three steps of toluene degradation by Pseudomonas putida F1.

The todFC1C2BADE gene cluster in Pseudomonas putida F1 encodes enzymes for the first four steps of toluene degradation, leading to the formation of 2-hydroxypenta-2,4-dienoate (HPD). Here, we report the nucleotide (nt) sequence and expression of the remaining three genes of the tod pathway, downstream from todE and arranged in the order, todGIH. The deduced amino acid (aa) sequences of TodG [HPD hydratase (268 aa)], TodH [4-hydroxy-2-oxovalerate (HO) aldolase (352 aa)] and TodI [acylating aldehyde (AA) dehydrogenase (316 aa)] are compared with the isofunctional proteins present in the meta-cleavage pathways of other bacteria. New sequence motifs are identified. The highly conserved TodH and TodI sequences are potentially useful DNA probes for biomonitoring purposes.

Sequence and expression of the bpdC1C2BADE genes involved in the initial steps of biphenyl/chlorobiphenyl degradation by Rhodococcus sp. M5

The nucleotide (nt) sequence of the bpdC1C2BADE genes which encode the first three enzymes in the biphenyl (BP) degradation pathway of Gram+ Rhodococcus sp. M5 (formerly Arthrobacter M5) was determined. Except for the ferredoxin component (BpdB) of the initial BP dioxygenase, the predicted amino acid (aa) sequences of the remaining proteins are found to be more closely related to the counterpart proteins (TodC1C2BADE) present in the toluene-degrader, Pseudomonas putida F1, than those of three BP-degrading pseudomonads. The cloned bpd genes were verified by their expression in the Escherichia coli T7 RNA polymerase/promoter system. In E. coli, BpdA was able to complement TodC1C2B in indigo biosynthesis, although the M5 native or cloned BP dioxygenase does not carry out this reaction.

n-Alkane assimilation and tert-butyl alcohol (TBA) oxidation capacity in Mycobacterium austroafricanum strains

Mycobacterium austroafricanum IFP 2012, which grows on methyl tert-butyl ether (MTBE) and on tert-butyl alcohol (TBA), the main intermediate of MTBE degradation, also grows on a broad range of n-alkanes (C2 to C16). A single alkB gene copy, encoding a non-heme alkane monooxygenase, was partially amplified from the genome of this bacterium. Its expression was induced after growth on n-propane, n-hexane, n-hexadecane and on TBA but not after growth on LB. The capacity of other fast-growing mycobacteria to grow on n-alkanes (C1 to C16) and to degrade TBA after growth on n-alkanes was compared to that of M. austroafricanum IFP 2012. We studied M. austroafricanum IFP 2012 and IFP 2015 able to grow on MTBE, M. austroafricanum IFP 2173 able to grow on isooctane, Mycobacterium sp. IFP 2009 able to grow on ethyl tert-butyl ether (ETBE), M. vaccae JOB5 (M. austroaafricanum ATCC 29678) able to degrade MTBE and TBA and M. smegmatis mc2 155 with no known degradation capacity towards fuel oxygenates. The M. austroafricanum strains grew on a broad range of n-alkanes and three were able to degrade TBA after growth on propane, hexane and hexadecane. An alkB gene was partially amplified from the genome of all mycobacteria and a sequence comparison demonstrated a close relationship among the M. austroafricanum strains. This is the first report suggesting the involvement of an alkane hydroxylase in TBA oxidation, a key step during MTBE metabolism.

LOCATION AND SEQUENCE ANALYSIS OF A 2-HYDROXY-6-OXO-6-PHENYLHEXA-2,4-DIENOATE HYDROLASE-ENCODING GENE (BPDF) OF THE BIPHENYL/POLYCHLORINATED BIPHENYL DEGRADATION PATHWAY IN RHODOCOCCUS SP. M5

The 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate (HOPD) hydrolase-encoding gene (bpdF) in the biphenyl (BP)/polychlorinated biphenyl (PCB)-degrading bacterium, Rhodococcus sp. M5 (M5), was found to be located within a 4.5-kb HindIII-BamHI genomic DNA that was 5.4 kb downstream from the bpdC1C2BADE gene cluster. The deduced amino acid (aa) sequence of bpdF revealed that the hydrolase contains 297 aa (32679 Da) that was verified by expression in the Escherichia coli T7 RNA polymerase/promoter system. Unlike previously known HOPD hydrolases, the aa sequence of BpdF appears unique. Interestingly, all HOPD hydrolases and related proteins from the phenol and toluene/xylene degradation pathways, were found to have a bias in the codon usage in the catalytic Ser within the conserved VGNS(M/F)GG motif.