Previous Article | Next Article 
Appl Environ Microbiol, July 1998, p. 2578-2584, Vol. 64, No. 7
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Biodegradation of Variable-Chain-Length Alkanes at
Low Temperatures by a Psychrotrophic Rhodococcus
sp.
Lyle G.
Whyte,1,*
Jalal
Hawari,1
Edward
Zhou,1
Luc
Bourbonnière,1
William E.
Inniss,2 and
Charles
W.
Greer1
NRC-Biotechnology Research Institute,
Montreal, Quebec,1 and
Department of
Biology, University of Waterloo, Waterloo,
Ontario,2 Canada
Received 11 March 1998/Accepted 12 May 1998
 |
ABSTRACT |
The psychrotroph Rhodococcus sp. strain Q15 was
examined for its ability to degrade individual n-alkanes
and diesel fuel at low temperatures, and its alkane catabolic pathway
was investigated by biochemical and genetic techniques. At 0 and 5°C,
Q15 mineralized the short-chain alkanes dodecane and hexadecane to a
greater extent than that observed for the long-chain alkanes
octacosane and dotriacontane. Q15 utilized a broad range of aliphatics
(C10 to C21 alkanes, branched alkanes, and a
substituted cyclohexane) present in diesel fuel at 5°C.
Mineralization of hexadecane at 5°C was significantly greater in both
hydrocarbon-contaminated and pristine soil microcosms seeded with Q15
cells than in uninoculated control soil microcosms. The detection of
hexadecane and dodecane metabolic intermediates (1-hexadecanol and
2-hexadecanol and 1-dodecanol and 2-dodecanone, respectively) by
solid-phase microextraction-gas chromatography-mass spectrometry and
the utilization of potential metabolic intermediates indicated that Q15
oxidizes alkanes by both the terminal oxidation pathway and the
subterminal oxidation pathway. Genetic characterization by PCR and
nucleotide sequence analysis indicated that Q15 possesses an aliphatic
aldehyde dehydrogenase gene highly homologous to the Rhodococcus
erythropolis thcA gene. Rhodococcus sp. strain Q15
possessed two large plasmids of approximately 90 and 115 kb (shown to
mediate Cd resistance) which were not required for alkane mineralization, although the 90-kb plasmid enhanced mineralization of
some alkanes and growth on diesel oil at both 5 and 25°C.
| |
INTRODUCTION |
In many temperate and cold climates,
the bioremediation of sites contaminated with aliphatic hydrocarbons,
resulting from the spillage or leakage of diesel fuels or kerosenes, is
possible, although it is hampered by low ambient temperatures for much
of the year. In many Arctic sites, the rates of biodegradation are thought to be too low to rapidly remove hydrocarbon contaminants, and
consequently, the contaminants remain in cold Arctic ecosystems for
long periods following contamination (3, 12). At low temperatures, the viscosity of oil increases, reducing the degree of
spreading of the oil in soil and aquatic matrices. Conversely, low
temperatures retard the volatilization of short-chain alkanes (<C10), which can increase their solubility in the aqueous
phase and, consequently, increase their microbial toxicity, which may delay the onset of biodegradation (3, 12). The degradation of long-chain alkanes, many of which are solid at temperatures of
<10°C, is hindered by their limited bioavailability. Nevertheless, biodegradation of many of the components of petroleum hydrocarbons has
been observed at low temperatures in a variety of soil, water, and
marine systems from temperate, sub-Arctic, Arctic, Antarctic, and
alpine sites (3, 4, 12, 15, 16, 31). The observed biodegradation is a result of the activity of indigenous psychrophilic and psychrotrophic microorganisms, which are characterized by low-temperature growth ranges of 
0 to 15 to 20°C and 0 to 30 to
35°C, respectively.
To optimize the biodegradative activity of psychrophiles and
psychrotrophs in contaminated sites, it is essential to develop a basic
understanding of their physiology and ecology as well as the genetics
and biochemistry of their catabolic pathways. These latter traits of
cold-adapted bacteria are relatively poorly understood compared with
those of mesophilic bacteria, which are metabolically inactive at
temperatures of 8 to 10°C. For example, only the genetics of the
alk pathway of the mesophile Pseudomonas oleovorans (28), which oxidizes short-chain alkanes
(C5 to C12), has been thoroughly characterized.
The microbial catabolic pathways for the degradation of
n-alkanes from a wide variety of bacteria, fungi, and yeasts
have been biochemically characterized. These include the common
hydroxylation pathways, such as the terminal oxidation pathway, the
terminal oxidation pathway followed by 
oxidation, and the less
common subterminal oxidation pathway (30). In the terminal
oxidation pathway, the initial oxidation step is catalyzed by a
monooxygenase to give the corresponding primary alcohol, which is
further oxidized to the corresponding aldehyde by alcohol
dehydrogenases and then to the corresponding fatty acid by aldehyde
dehydrogenases. In the subterminal pathway, the alkane is oxidized by a
monooxygenase to the corresponding secondary alcohol, then to the
ketone, and eventually to a fatty acid. Dioxygenase systems also exist
in some microorganisms, where the n-alkane is initially
oxidized to the corresponding hydroperoxide and then is transformed to
the corresponding primary alcohol (30) or to the
corresponding aldehyde, as originally postulated by Finnerty
(6) and recently demonstrated by Sakai et al.
(23) in Acinetobacter sp. strain M-1.
In an initial investigation, a number of psychrotrophic bacteria were
isolated from environmental samples, obtained from both contaminated
and noncontaminated sites across Canada, and shown to mineralize a
variety of petroleum hydrocarbon components (toluene, naphthalene, and
alkanes) at 5°C (32). One psychrotrophic bacterium, originally isolated from Lake Ontario and tentatively identified as
Rhodococcus sp. strain Q15, readily mineralized both
shorter-chain C-labelled alkanes (dodecane and
hexadecane) and longer-chain alkanes (octacosane and dotriacontane) at
23°C. In the present study, we further characterized this bacterium
and studied its ability to mineralize alkanes and diesel oil at low
temperatures. The genetic and biochemical bases of its alkane catabolic
pathway were also examined.
| |
MATERIALS AND METHODS |
Isolation and characterization of Rhodococcus sp.
strain Q15.
The psychrotrophic strain used in this study was
previously isolated from the Bay of Quinte, Ontario, Canada
(10), and tentatively identified as a Rhodococcus
sp. (32). The strain, designated Q15, was further
characterized in the present study by standard morphological,
physiological, and biochemical techniques (13) and was
identified by substrate utilization (Biolog GP microplate identification system; Biolog, Hayward, Calif.), cell wall fatty acid
analysis (Microcheck Inc., Northfield Falls, Vt.), and 16S ribosomal
DNA (rDNA) sequencing (essentially as described by Denis-Larose et al.
[5]). Strain Q15 and other psychrotrophic and
mesophilic alkane-degradative strains used in this study were grown on
Trypticase soy agar (TSA) at 24 or 37°C (psychrotrophic and
mesophilic strains, respectively) and maintained at 4°C. Resistance
to cadmium was determined by monitoring the growth of Q15 in Trypticase
soy broth (TSB) supplemented with various concentrations of Cd in the
form of Cd(NO3)2 · 5H2O.
Mineralization of alkanes at low temperatures by
Rhodococcus sp. strain Q15.
The mineralization of
dodecane by Rhodococcus sp. strain Q15 and that by the
mesophilic alkane-degradative strain P. oleovorans ATCC
29347 were compared at 10, 20, and 30°C by a serum bottle assay with
mineral salts medium (MSM) as previously described (32). The
ability of Rhodococcus sp. strain Q15 to mineralize the
shorter-chain alkanes, dodecane (C12) and hexadecane
(C16), and longer-chain alkanes, octacosane
(C28) and dotriacontane (C32), was also
examined at 0 and 5°C. All assays which included uninoculated controls were performed in duplicate. The 14C-labelled
organic substrates (Sigma, St. Louis, Mo.) used in the mineralization
assays were [1-14C]dodecane (specific activity, 3.7 mCi/mmol), [1-14C]hexadecane (specific activity, 2.2 mCi/mmol), [14,15-14C]octacosane (specific activity, 11.7 mCi/mmol), and [16,17-14C]dotriacontane (specific
activity, 8.8 mCi/mmol).
Utilization of diesel oil by Rhodococcus sp. strain
Q15 at 5°C.
To determine the range of alkanes utilized by Q15,
the growth of the organism on diesel fuel, which consists mostly of
linear and branched alkanes, was examined. Erlenmeyer flasks containing MSM (50 ml) supplemented with 0.1% (vol/vol) diesel fuel and 0, 5, or
10 ppm of yeast extract (YE) were inoculated with Q15 to an initial
optical density at 600 nm (OD600) of 0.025. The flasks were
sealed tightly with screw caps, and the cultures were incubated at
5°C for 14 or 28 days, or at 24°C for 4 days, with shaking (150 rpm) (i.e., until heavy growth was observed). An uninoculated control
flask was incubated in parallel to monitor abiotic losses of the diesel
substrate. Following the incubation periods, the diesel oil was
extracted from the growth medium and analyzed by gas
chromatography-mass spectrometry (GC-MS) essentially as described by
Geerdink et al. (7). An extraction standard (docosane) was added to each flask (final concentration, 10 ppm), the pH of the growth
medium was adjusted to pH 13 with 10 N NaOH, and the suspension was
extracted three times with 10 ml of diethyl ether in a separatory funnel. The diethyl ether phase was collected from the flasks, the
volume of each extract was adjusted to 30 ml, and the extract was
dehydrated with 1 to 2 g of Na2SO4. Twenty
microliters of an injection standard (1,3,5-trichlorobenzene; 1.7 g/liter) was added to each extract (0.5 ml) to a final concentration of
40 ppm. The samples were analyzed by GC-MS in a model 5890 GC
(Hewlett-Packard, Avondale, Pa.) connected to a model 5970 quadrupole
MS (EI70 eV) (Hewlett-Packard). A DB-5 capillary column (30 m by 0.25 mm by 0.25 µm; J & W Scientific, Folsom, Calif.) was used, with He as the carrier gas and a temperature program consisting of an initial oven
temperature of 55°C for 3 min increased at a rate of 4°C/min to
245°C for 5 min. The injector and detector were maintained at 250 and
280°C, respectively. To determine the extent of degradation of
various hydrocarbon components of diesel fuel, the areas of individual
peaks (from duplicate samples) were quantified by integration, normalized to the phytane peak from each sample, and expressed as the
percentage degraded relative to the amount of the corresponding peak
remaining in the appropriate abiotic control samples. Phytane was not
degraded by this organism.
Determination of the alkane catabolic pathway of
Rhodococcus sp. strain Q15 by SPME-GC-MS and substrate
utilization.
To elucidate the alkane degradation pathway of
Rhodococcus sp. strain Q15, two analyses were performed (i)
to identify potential metabolic intermediates resulting from the growth
of Q15 on dodecane or hexadecane and (ii) to examine the organism's
ability to grow on terminal and subterminal pathway intermediates. For
the identification of metabolic intermediates, Q15 cells were grown at
24°C with shaking (150 rpm) in MSM (50 ml) supplemented with 25 ppm
of YE and 50 ppm of dodecane or hexadecane. The presence of metabolic intermediates in the culture broth was monitored daily by collecting 1 ml of the growth medium in a 1.0-ml glass vial. Bacterial cells were
removed by centrifugation in a microcentrifuge (12,000 × g for 2 min), and the supernatant was collected and stored
at 
20°C. Metabolic intermediates were extracted from the 1-ml
samples by solid-phase microextraction (SPME) (2, 21) by
immersing an SPME fiber, coated with a 75-µm-thick film of
polyacrylate (Supelco, Bellefonte, Pa.) to adsorb hydrophobic organic
compounds, in the sample for 20 min. The SPME fiber was inserted into
the GC injection port and held for 10 min to thermally desorb analytes from the SPME fiber into the GC injector for analysis by GC-MS. A
Varian GC-MS equipped with a Saturn 4D ion trap detector and integrated
with a split or splitless injector and a DB-5 column (15-m by 0.25-mm
by 0.25-µm film) with He as the carrier gas was used for GC-MS
analysis. The temperature program had an initial oven temperature of
90°C for 2 min, which was then increased at a rate of 7°C/min to
270°C. The injector, with a front pressure of 11 lb/in2,
was set at 270°C in the splitless mode for 5 min and then changed to
the split mode of 1/10 to the column. The MS had a mass range of 30 to
400 atomic mass units at a scan rate of 0.5 s per scan. The
acquisition time was set for 25 min. Various metabolic intermediates were identified by matching the retention times and mass spectra with
authentic standards which had been extracted from aqueous medium by
SPME and analyzed by GC-MS, as described above. To ensure that detected
metabolic intermediates were a result of Q15 biotic activity, sterile
controls were supplemented with dodecane or hexadecane and run in
parallel with the inoculated media and were analyzed by SPME-GC-MS.
The growth of Q15 on potential metabolic intermediates of dodecane and
hexadecane was studied by monitoring respiration. Serum bottles (100 ml) containing 20 ml of MSM and a 5-ml test tube containing 1 ml of 0.1 N KOH to trap CO2 were supplemented with 100 ppm of the
primary substrate (hexadecane or dodecane) or their various metabolic
intermediates (1-hexadecanol, 2-hexadecanol, 2-hexadecanone,
hexadecanedioic acid, 1-dodecanol, 2-dodecanol, 1-dodecanal,
2-dodecanone, and docanedioc acid) as the sole carbon and energy source
and were inoculated with Q15 to a final OD600 of 0.025 and
sealed with Teflon septa and crimp caps. The serum bottles were
incubated at 24°C in a G24 incubator-shaker (New Brunswick
Scientific, Edison, N.J.) at 150 rpm. CO2 was periodically recovered from the KOH trap, precipitated, and quantified as described by Anderson (1) and was reported as micromoles of
CO2 evolved (essentially as described by Whyte et al.
[33]). Uninoculated controls and bottles inoculated
with Q15 but not supplemented with a carbon or energy source were
monitored for background CO2 evolution. All analyses were
performed in triplicate.
PCR and plasmid analyses of Rhodococcus sp. strain
Q15.
In an initial investigation (32), PCR and Southern
analyses indicated that Q15 may possess a gene with low homology to
P. oleovorans alkB, encoding alkane hydroxylase, which is
responsible for the hydroxylation of short-chain alkanes
(C5 to C12) in the first step of the alkane
degradation pathway of P. oleovorans (28). In the
present study, Q15 was examined by PCR analysis essentially as
described by Whyte et al. (32) for the presence of other
recently described bacterial genes potentially involved in alkane
catabolism, including the Acinetobacter calcoaceticus rubredoxin and rubredoxin reductase genes, which are required by that
bacterium for growth on dodecane and hexadecane (8), and for
the aldehyde dehydrogenase gene (thcA) of Rhodococcus erythropolis NI86/21, which transforms C3 to
C10 aliphatic aldehydes to the corresponding aliphatic
acids (20). To verify PCR amplification, the putative
thcA PCR fragment obtained from Rhodococcus sp.
strain Q15 and the "alkB" PCR fragment previously
obtained from Rhodococcus sp. strain Q15 (32)
were purified and sequenced and the nucleotide sequences obtained were
analyzed as previously described (33).
Rhodococcus sp. strain Q15 was screened for the presence of
large catabolic plasmids, similar to the alkane catabolic plasmid
OCT
found in
P. oleovorans, using a modified alkaline lysis
method
(
5). Southern analyses of the plasmid and chromosomal
bands
found in
Rhodococcus sp. strain Q15, using DNA probes
specific
for
alkB from
Rhodococcus sp. strain Q15
(
32) and
thcA from
Rhodococcus sp.
strain Q15, were performed essentially as described
by Whyte et al.
(
33), employing high-stringency hybridization
and washing
conditions at 65°C. Plasmid curing of Q15 was performed
by growing
the organism at 35.5°C (the maximum growth temperature
of Q15) in
Luria-Bertani medium with shaking (150 rpm) for 3 days.
After being
subcultured eight times, isolated colonies, obtained
on Luria-Bertani
agar plates, were screened for the presence of
the large plasmids as
described above. Southern analysis was performed
on plasmid
preparations from the parental strain and strains lacking
one or both
plasmids, using a DNA probe constructed from an ~4-kb
EcoRI fragment obtained from the Q15 90-kb plasmid by
standard
molecular biology techniques (
24). Plasmid-cured
strains were
tested for their ability to mineralize C
12,
C
16, and C
28; growth
in MSM supplemented with
0.1% diesel fuel; and resistance to cadmium
(100 ppm), as described
above.
Mineralization of hexadecane in soils bioaugmented with
Rhodococcus sp. strain Q15.
Hexadecane mineralization
in contaminated and pristine soils was monitored in soil microcosms to
determine if bioaugmentation with Rhodococcus sp. strain Q15
could enhance the biodegradation of alkanes at low temperatures. The
contaminated soil (a silty clay soil with 30% water content and
~5,000 mg of total petroleum hydrocarbons/kg) was collected from a
crude-oil-contaminated site at Ville St. Pierre, Quebec, Canada. For
comparison, a nonimpacted soil (pristine) with similar physiochemical
characteristics was collected near a water treatment plant in
Stanstead, Quebec, Canada. Soil aliquots (20 g) were placed in 100-ml
serum bottles. For bioaugmentation, a cellular suspension of Q15 was
prepared by growing Q15 in TSB overnight at 23°C. The cells were
harvested by centrifugation at 5,000 × g for 10 min at
4°C, and the pellet was washed twice with cold 0.1% sodium
tetrapyrophosphate and then resuspended in the wash buffer to an
OD600 of 10. Appropriate volumes (~100 µl) of the Q15
cellular suspension were added to the soil microcosms to give final
concentrations of ~108 cells/g (wet weight) of soil and
were mixed with a sterile spatula. The actual number of cells added to
each soil microcosm was determined by viable plate counts on TSA. A
small test tube containing 1 ml of 0.5 M KOH (a CO2 trap)
was placed inside each serum bottle, and 20-µl aliquots of
14C-labelled hexadecane were added to the soil microcosms,
resulting in final concentrations of 100 ppm of hexadecane and
~100,000 dpm. The serum bottles were sealed with rubber stoppers and
aluminum crimps and incubated at 5°C, and the amount of radioactivity
trapped in the KOH trap was determined (9) at regular
intervals. To monitor mineralization of hexadecane by the indigenous
microbial population, nonbioaugmented soil microcosms were examined as
described above. All soil microcosms were set up in triplicate.
Nucleotide sequence accession number.
The Q15 16S rDNA
sequence has been submitted to GenBank and assigned accession no.
AF046885.
| |
RESULTS |
Characterization of Rhodococcus sp. strain Q15.
The alkane biodegradative strain was a gram-positive, oxidase-negative,
catalase-positive rod and produced creamy white circular colonies on
TSA which became mucoid following extended growth at 5°C. The isolate
possessed a growth temperature range of 0 to ~35°C with an optimum
growth temperature of ~30°C, indicating that the bacterium should
be classified as a psychrotroph. The psychrotroph did not reduce
nitrate to nitrite but was urease positive. The strain could grow in
TSB supplemented with up to 200 mg of Cd/liter. Preliminary
identification of Q15 by the Biolog GP microplate identification system
and by fatty acid composition indicated that the isolate belonged to
the genus Rhodococcus. 16S rDNA sequence analysis of Q15
showed 99.5% identity to the DNA sequence of Nocardia
calcarea (EMBL accession no. X80618), which is a synonym for
R. erythropolis, a species belonging to Rhodococcus rDNA group IV (the largest
Rhodococcus cluster) (22), and 99.4% identity to
the DNA sequence of an undescribed Rhodococcus isolate, DN22
(EMBL accession no. X89240). On the basis of these data, the
psychrotrophic strain is referred to as Rhodococcus sp.
strain Q15.
Mineralization of alkanes at low temperatures by
Rhodococcus sp. strain Q15.
The ability of Q15 to
mineralize dodecane was compared with that of the mesophile P. oleovorans at 10, 20, and 30°C (Fig. 1). As shown by the rates and extents of
dodecane mineralization, both organisms readily mineralized dodecane at
20 and 30°C. However, at 10°C, only negligible amounts of dodecane
were mineralized by the mesophile, while the psychrotroph readily
mineralized this alkane at the lower temperature, demonstrating the
intrinsic advantage psychrotrophic microorganisms possess for degrading
contaminants at lower temperatures. At 5°C, Rhodococcus
sp. strain Q15 mineralized the shorter-chain alkanes dodecane
(C12) and hexadecane (C16) to a greater extent
than that observed for the longer-chain alkanes octacosane
(C28) and dotriacontane (C32) (Fig.
2). After 102 days of incubation at
0°C, Q15 mineralized C12 (8%), C16 (6.1%),
C28 (1.6%), and C32 (4.3%), but at markedly
lower rates and to a lesser extent than was observed at 5°C, as
expected. The organism was unable to mineralize
14C-labelled toluene or naphthalene. Cumulative background
levels of 14CO2 in the uninoculated serum
bottles for all of the tested substrates were less than 1% at the end
of the incubation period.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 1.
Mineralization of [1-14C]dodecane by the
psychrotroph Rhodococcus sp. strain Q15 and the mesophile
P. oleovorans at 10, 20, and 30°C. Mineralization by
Rhodococcus sp. strain Q15 and P. oleovorans was
determined in 20 ml of MSM supplemented with 50 mg of YE/liter, as
described in Materials and Methods. Each point represents the mean from
duplicate cultures.
|
|
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 2.
Mineralization of [1-14C]dodecane,
[1-14C]hexadecane, [14,15-14C]octacosane,
or [16,17-14C]dotriacontane by Rhodococcus sp.
strain Q15 at 5°C, determined as described in the legend to Fig. 1.
Each point represents the mean from duplicate cultures.
|
|
Utilization of diesel oil by Rhodococcus sp. strain
Q15.
After 28 days of growth at 5°C in MSM containing 0.1%
diesel fuel, Rhodococcus sp. strain Q15 degraded almost all
the n-alkanes (C10 to C21) and, to a
lesser degree, many of the branched alkanes found in diesel fuel (Fig.
3). The remaining peaks were naphthalene and naphthalene derivatives as well as some branched alkanes, including
phytane and pristane, which did not appear to be degraded by the
organism. During shorter incubation periods, the ability of Q15 to grow
on and catabolize diesel fuel components was markedly enhanced by
supplementing MSM with a small amount of YE (10 ppm) (Fig.
4). After 2 weeks of growth at 5°C, the
alkane peaks were degraded to a lesser extent (15 to 53%), while
branched alkanes were not utilized in MSM containing only diesel fuel
(Fig. 4). In comparison, Q15 readily degraded the various diesel fuel
components after 14 days at 5°C in MSM containing 10 ppm of YE,
similar to the degradation observed following 4 weeks of incubation at
5°C in MSM alone. Four weeks of incubation at 5°C in MSM
supplemented with YE did not markedly increase overall degradation in
comparison with that in MSM alone. Supplementation of the growth medium
with YE also noticeably enhanced diesel fuel utilization at 24°C
after 4 days (data not shown). Overall, this bacterium is capable of utilizing a broad range of alkanes and aliphatic components present in
diesel fuel at low and moderate temperatures, and although a
constituent(s) present in YE increased the rate of diesel fuel degradation by Q15, it was not found to be essential.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 3.
GC profiles of diesel oil extracted from the aqueous
phase of MSM medium after 28 days of incubation at 5°C with and
without inoculation with Rhodococcus sp. strain Q15. (A)
Abiotic control (uninoculated); (B) inoculated with Q15. IS, injection
standard; ES, extraction standard; C10 to C21, n-alkanes
(numbers designate the number of C atoms); B1 to
B5, branched alkanes; C, substituted cyclohexane; Na,
naphthalene; N1 to N4, substituted
naphthalenes; Pr, pristane; Ph, phytane. The alkane, naphthalene,
phytane, and pristane peaks were identified by comparison of their
retention times and mass spectra with authentic standards. The branched
alkanes, substituted naphthalenes, and substituted cyclohexane were
tentatively identified by mass spectra database comparisons following
GC-MS analysis.
|
|
View larger version (51K):
[in this window]
[in a new window]
|
FIG. 4.
Degradation of specific diesel fuel components by
Rhodococcus sp. strain Q15 at 5°C in MSM containing 0.1%
(vol/vol) diesel fuel after 14 days of growth in MSM alone (solid bars)
or supplemented with 10 ppm of YE (hatched bars) and after 28 days of
growth in MSM alone (shaded bars) or supplemented with 10 ppm of
YE (open bars). Abbreviations are described in the legend to Fig. 3 and
correspond to the peaks shown in Fig. 3. Each point represents the mean
from duplicate cultures.
|
|
Determination of the alkane catabolic pathway of
Rhodococcus sp. strain Q15.
Metabolic intermediates
were extracted from Q15 culture broth by SPME and identified by GC-MS.
After 24 h of incubation on hexadecane, both 1-hexadecanol and
2-hexadecanol were identified by comparison of their retention times
and mass spectra with authentic standards (Fig.
5). After 48 h, both the
1-hexadecanol and 2-hexadecanol peaks had disappeared but traces of
hexadecanoic acid could be detected (data not shown). After 24 h
of incubation on dodecane, 1-dodecanol and 2-dodecanone were detected
and identified by GC-MS. A third peak was observed that had a retention
time and a mass spectrum similar to those of 2-dodecanol or 1-dodecanal
(which had identical retention times and very similar mass spectra), but this peak's exact identity was not resolved by mass spectral analysis. After 96 h of incubation, the 1-dodecanol peak had
almost disappeared while the 2-dodecanone peak had increased in size. Peaks corresponding to dodecane or hexadecane metabolic intermediates were not seen in parallel sterile controls.
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 5.
GC profile of intermediate metabolites of hexadecane
degradation by Rhodococcus sp. strain Q15. Q15 was grown in
MSM supplemented with 50 ppm of hexadecane and 50 ppm of YE at 23°C.
Metabolic intermediates were extracted from the culture supernatant by
SPME and analyzed by GC-MS. (A) Intermediates extracted at time zero;
(B) intermediates extracted after 24 h of incubation.
|
|
The growth of Q15 on potential dodecane or hexadecane metabolic
intermediates as the sole carbon and energy sources at 24°C
was also
monitored by CO
2 respiration to confirm the SPME-GC-MS
results. The highest levels of CO
2 respiration were
observed during
the growth of Q15 on the primary substrates dodecane
and hexadecane,
followed by the
-oxidation pathway intermediates
dodecanedioic
acid and hexadecanedioic acid (Fig.
6). Less CO
2 was produced
from both the hexadecane subterminal pathway metabolites
2-hexadecanol
and 2-hexadecanone and the hexadecane terminal pathway
metabolite
1-hexadecanol. Significant levels of CO
2 were
produced from the
dodecane terminal pathway intermediates 1-dodecanal
and, to a
lesser extent, 1-dodecanol (Fig.
6). Respiration during
growth
on the subterminal dodecane intermediates 2-dodecanol and
2-dodecanone
was only slightly greater than that observed in the
control medium
containing no carbon source.
View larger version (34K):
[in this window]
[in a new window]
|
FIG. 6.
Utilization of dodecane and hexadecane and their
potential metabolic intermediates by Rhodococcus sp. strain
Q15 at 23°C. Q15 was grown in MSM supplemented with 100 ppm of the
indicated n-alkane or metabolic intermediate as the sole
carbon and energy source. Bacterial growth was monitored by
CO2 respiration. Each point represents the mean number of
micromoles of CO2 evolved from triplicate samples, with the
error bars representing the standard deviations of the means. The
control values represent the background CO2 respired from
MSM inoculated with Rhodococcus sp. strain Q15 but lacking a
carbon source.
|
|
PCR and plasmid analyses of Q15.
PCR analysis indicated that
Rhodococcus sp. strain Q15 was negative for the rubredoxin
and rubredoxin reductase genes of A. calcoaceticus but was
positive for thcA and, as shown previously, for
alkB. However, subsequent DNA sequence analysis of the
Rhodococcus sp. strain Q15 "alk" PCR fragment
revealed that it had 46% identity to the nucleotide sequence of
P. oleovorans alkB and the derived amino acid sequence of
Q15 "AlkB" had very low similarity (~10%) with that of P. oleovorans AlkB. Further comparison of the derived amino acid
sequences of Q15 AlkB with data bank entries revealed homology with
eubacterial metabolite transporter proteins (~50% DNA sequence
identity and ~60% amino acid similarity), suggesting that the
alkB primers probably amplified a Rhodococcus
gene homologous to eubacterial metabolite transporter genes rather than
an alkB-homologous gene. Sequence analysis of the Q15
thcA fragment, comprising 45% of the R. erythropolis
thcA gene, revealed that it had 95% identity with the nucleotide
sequence of R. erythropolis thcA. The derived amino acid
sequence of Q15 ThcA had 98% similarity with the amino acid sequence
of R. erythropolis ThcA and contained glutamic
acid-catalytic and cysteine-catalytic consensus sequences and the
glycine NAD+ coenzyme binding motif characteristic of
aldehyde dehydrogenases (20).
Plasmid analysis of
Rhodococcus sp. strain Q15 revealed the
presence of two large cryptic plasmids (Fig.
7) of approximately
90 and 115 kb, as
determined by comparison with other previously
sized plasmids in our
laboratory (data not shown). A DNA probe
constructed from the Q15
thcA PCR fragment hybridized to the chromosomal
DNA band
from
Rhodococcus sp. strain Q15 but not to the large
plasmids (data not shown). Following plasmid curing by high-temperature
treatment, 31% (8 of 26) of the isolated Q15 colonies tested lacked
the larger, 115-kb plasmid (Fig.
7). One of these isolates, designated
Q15 H, was subsequently cured of the smaller plasmid by the same
plasmid-curing protocol, resulting in a plasmidless strain designated
Q15 NP, as shown by plasmid analysis and Southern hybridization
with a
4-kb
EcoRI restriction fragment obtained from the 90-kb
plasmid (Fig.
7). Similar analysis with a 6-kb
EcoRI
restriction
fragment obtained from the 115-kb plasmid showed that both
Q15
H and Q15 NP lacked the larger plasmid (data not shown). Despite
repeated attempts, it was not possible to obtain a strain of Q15
cured
of only the smaller plasmid. At both 24 and 5°C, Q15 strains
lacking
the larger plasmid or both plasmids mineralized C
12,
C
16,
and C
28, strongly indicating that alkane
catabolism in this
Rhodococcus sp. is not plasmid mediated.
However, the rate and extent of C
12 mineralization by Q15
NP was less than that observed with Q15
and Q15 H at both temperatures,
as was C
28 mineralization at 5°C.
Compared with that of
Q15 and Q15 H, growth of Q15 NP in MSM supplemented
with 0.1% diesel
fuel was also markedly reduced at 5 and 24°C.
Both Q15 H and Q15 NP
were unable to grow in the presence of 100
mg of Cd/liter, indicating
that Cd resistance in Q15 is mediated
by the larger, 115-kb plasmid.
View larger version (67K):
[in this window]
[in a new window]
|
FIG. 7.
Detection of plasmids in parental Rhodococcus
sp. strain Q15 and the plasmid-cured strains Q15 H and Q15 NP by
plasmid and Southern analyses. Total DNA (chromosomal and plasmid DNAs)
from the three strains was isolated and examined by agarose gel
electrophoresis. (A) Agarose gel electrophoresis (0.7%) showing the
presence of the ~90- and ~115-kb plasmids in Q15, the ~90-kb
plasmid in Q15 H, and the lack of both plasmids in Q15 NP. (B) Southern
hybridization analysis of chromosomal and plasmid DNAs shown in panel A
transferred to a nylon membrane and probed with a DNA probe constructed
from an ~4-kb EcoRI fragment derived from the Q15 90-kb
plasmid. Lanes 1, lambda (HindIII) ladder; lanes 2, Rhodococcus sp. strain Q15; lanes 3, Q15 H; lanes 4, Q15
NP.
|
|
Mineralization of hexadecane in soils bioaugmented with
Rhodococcus sp. strain Q15.
In both
hydrocarbon-contaminated and pristine soil microcosms, mineralization
of 14C-labelled hexadecane at 5°C was significantly
greater in soil microcosms which were seeded with 108
Rhodococcus sp. strain Q15 cells/g (wet weight) of soil than in uninoculated control soil microcosms (Fig.
8). Bioaugmentation with 105
Q15 cells/g (wet weight) of soil did not enhance mineralization significantly in either the pristine or the contaminated soils (data
not shown), indicating that a threshold inoculum level is required to
effectively enhance biodegradation of alkanes in soil. Surprisingly, in
the hydrocarbon-contaminated soil, very little indigenous microbial
mineralization activity was observed.
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 8.
The effect of bioaugmentation with
Rhodococcus sp. strain Q15 (108 CFU/g of soil)
on mineralization of [1-14C]hexadecane at 5°C in
pristine and hydrocarbon-contaminated soil microcosms. Each point
represents the mean cumulative mineralization (percent CO2)
from triplicate soil microcosms, with the error bars representing
standard deviations of the means. Contam., contaminated.
|
|
| |
DISCUSSION |
The ability of a psychrotrophic Rhodococcus sp. to
assimilate aliphatic hydrocarbons was assessed and characterized at low temperatures. As demonstrated by the mineralization assays and by the
utilization of diesel fuel, this organism clearly utilized a wide
variety of hydrocarbons from 0 to 30°C, temperatures which parallel
the active microbial temperature growth range of many temperate and
cold environments. Psychrotrophic microorganisms may be better suited
for in situ bioremediation of contaminated sites from these
environments than either mesophiles, which have very low activities at
10°C, or psychrophiles, whose growth is inhibited at temperatures
of 
15 to 20°C (although in permanently cold habitats, psychrophiles
may possess greater activities than psychrotrophs).
The mineralization data suggested that Q15 degrades shorter-chain
alkanes (C12 and C16) more readily than the
longer-chain alkanes (C28 and C32), which is a
common feature of many other alkane-degradative microorganisms
(28). The mineralization of the longer-chain alkanes was
reduced to a greater extent than that of the shorter-chain alkanes,
particularly dodecane, as the temperature decreased. As dodecane is the
only one of the alkanes tested that remains a liquid at 0°C, while
octacosane and dotriacontane form relatively large crystals at 0 and
5°C, the decreased bioavailability of the longer-chain alkanes at
lower temperatures may be responsible for their increased
recalcitrance. The lack of growth of A. calcoaceticus S30 on
metabolic intermediates of octadecane (11) and of
Rhodococcus sp. strain S1 on anthracene crystals
(27) was attributed to their decreased bioavailabilities.
Enhanced long-chain alkane recalcitrance at low temperatures may have
important implications for in situ bioremediation attempts in cold
climates. For example, successful bioremediation strategies could
require the application of cold-active solubilizing agents to increase
the bioavailability of long-chain alkanes.
Bioaugmentation of contaminated sites at cold temperatures may become a
particularly viable in situ bioremediation strategy for such sites
because the short summer seasons do not permit long acclimatization
periods for hydrocarbon-degradative populations. In the present study,
bioaugmentation of a contaminated and a pristine soil with
Rhodococcus sp. strain Q15 not only decreased the lag time
before C16 mineralization occurred but increased the rate
and extent at which C16 mineralization occurred at 5°C, indicating that psychrotrophs (such as Q15) could eventually be used to
enhance the degradation of contaminated environments subjected to low
temperatures. However, bioaugmentation with this organism would
probably require a simultaneous nutrient supplement for optimal in situ
alkane-degradative activity, as demonstrated by the enhanced
degradation of diesel fuel at 5°C when supplemented with YE.
Components present in the YE, such as a growth factor(s) or vitamin(s),
may have increased the rate of alkane consumption by contributing to a
more rapid production of Q15 biomass. Bioaugmentation with a
psychrotrophic actinomycete only slightly enhanced biodegradation in
diesel-fuel-contaminated alpine soils at 10°C during the initial phases of treatment (15). Similarly, bioaugmentation with a psychrotrophic diesel-oil-degradative yeast, plus or minus
biostimulation with an inorganic fertilizer, did not enhance
degradation at 10°C in alpine soils to a significantly greater extent
than did biostimulation alone (16).
The detection of potential metabolic intermediates of C12
or C16 catabolism from both the terminal and the
subterminal pathways by SPME-GC-MS during the growth of Q15 on these
alkanes, and the ability of Q15 to grow on many of their potential
metabolic intermediates from both pathways, indicates that Q15 oxidizes
alkanes by both the terminal and the subterminal oxidation pathways.
Other rhodococci with multiple aliphatic catabolic pathways have been
reported (29). For example, Rhodococcus
rhodochrous PNKb1 possesses both the terminal and subterminal
pathways for C2 to C8 alkanes while Rhodococcus sp. strain BPM 1613 catabolizes pristane by the
terminal pathway and by terminal oxidation followed by oxidation.
On the other hand, R. erythropolis ATCC 4277 appears to
degrade C5 to C16 alkanes only by the
subterminal pathway (14) while Rhodococcus salmonicolor utilizes the terminal oxidation pathway
(29). Thus, it appears that different members of the genus
Rhodococcus, recently recognized for their metabolic
virtuosity in degrading many environmental contaminants, possess a
variety of alkane-catabolic pathways.
Plasmid analysis of Rhodococcus sp. strain Q15 demonstrated
that neither the smaller nor the larger plasmid found in Q15 is required for alkane mineralization by the organism, indicating that
alkane degradation by Q15 is not plasmid encoded, unlike the P. oleovorans alk system. The alkane-degradative systems found in
Acinetobacter spp. (8, 30) also appear to be
located on the chromosome. However, slower rates of mineralization on
alkanes and of growth on diesel fuel by the plasmidless strain, in
comparison with those by the parental strain and a Q15 strain
containing only the larger plasmid, indicate that the smaller Q15
plasmid may carry genes which have a positive impact on hydrocarbon
catabolism, perhaps by decreasing the toxicity of hydrocarbons,
increasing hydrocarbon bioavailability, and/or mediating uptake of
aliphatic hydrocarbons.
Rhodococcus sp. strain Q15 possessed a thcA gene
that was highly homologous to the thcA gene of R. erythropolis, which is located on the chromosome. Although
thcA is widespread in the rhodococci, including other
alkane-degradative actinomycetes analyzed in this study (data not
shown), its role in alkane metabolism remains to be confirmed. The
thcA gene was originally found to be induced in R. erythropolis NI86/21 during exposure to the herbicide thiocarbamate, where its gene product was most likely responsible for
transforming aliphatic aldehydes (generated by
N-dealkylation of thiocarbamate) to the corresponding
carboxylic acids (20). However, thcA is not part
of the operon encoding the P-450 cytochrome system genes that are
responsible for the initial oxidation of thiocarbamate (20).
The thcA gene is located within an unknown operon similar in
gene organization to the P. oleovorans alk operon because it
contains adjacent open reading frames, one of which most likely encodes
an alcohol dehydrogenase (20). These observations, and the
results of the present study, suggest that thcA may be part
of an alkane-degradative operon or pathway in the genus
Rhodococcus. The initial alkane oxidation may be mediated by
an alkane-oxidizing cytochrome P-450 system, since Q15 does not contain
an alkane monooxygenase similar to that of P. oleovorans. A
variety of cytochrome P-450 enzymes have been implicated in alkane
degradation, including octane degradation by R. rhodochrous
(26), long-chain alkane degradation in A. calcoaceticus (17) and perhaps in Bacillus megaterium (18, 19), and a variety of yeast
(25). We are currently exploring the exact role that
thcA, and possibly P-450, plays in alkane catabolism in
Rhodococcus sp. strain Q15.
| |
ACKNOWLEDGMENTS |
We thank Helen Bergeron, Chantale Beaulieu, Simen-Jan Slagman,
and Helene Legasse for their technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address:
NRC-Biotechnology Research Institute, 6100 Royalmount Ave., Montreal,
Quebec, Canada H4P 2R2. Phone: (514) 496-6316. Fax: (514) 496-6265. E-mail: Lyle.Whyte{at}nrc.ca.
| |
REFERENCES |
| 1.
|
Anderson, J. P. E.
1982.
Soil respiration, p. 836-841.
In
A. L. Page (ed.), Methods of soil analysis, part 2. Chemical and microbiological properties, 2nd ed. American Society of Agronomy, Madison, Wis.
|
| 2.
|
Arthur, C. L., and J. Pawliszyn.
1990.
Solid-phase microextraction.
Anal. Chem.
66:2145-2148.
|
| 3.
|
Atlas, R. M.
1981.
Microbial degradation of petroleum hydrocarbons: an environmental perspective.
Microbiol. Rev.
45:180-209[Free Full Text].
|
| 4.
|
Bossert, I., and R. Bartha.
1984.
The fate of petroleum in soil ecosystems, p. 435-474.
In
R. M. Atlas (ed.), Petroleum microbiology. Macmillan Publishing Co., New York, N.Y.
|
| 5.
|
Denis-Larose, C.,
D. Labbé,
H. Bergeron,
A. M. Jones,
C. W. Greer,
J. Al-Hawari,
M. J. Grossman,
B. M. Sankey, and P. C. K. Lau.
1997.
Conservation of plasmid-encoded dibenzothiophene desulfurization genes in several rhodococci.
Appl. Environ. Microbiol.
63:2915-2919[Abstract].
|
| 6.
|
Finnerty, W. R.
1977.
The biochemistry of microbial alkane oxidation: new insights and perspectives.
Trends Biochem. Sci.
2:73-75.
|
| 7.
|
Geerdink, M. J.,
M. C. M. van Loosdrecht, and K. C. A. M. Luyben.
1996.
Biodegradability of crude oil.
Biodegradation
7:73-81.
|
| 8.
|
Geissdorfer, W.,
S. C. Frosch,
G. Haspel,
S. Ehrt, and W. Hillen.
1995.
Two genes encoding proteins with similarities to rubredoxin and rubredoxin reductase are required for conversion of dodecane to lauric acid in Acinetobacter calcoaceticus ADP1.
Microbiology
141:1425-1432[Abstract/Free Full Text].
|
| 9.
|
Greer, C.,
L. Masson,
Y. Comeau,
R. Brousseau, and R. Samson.
1993.
Application of molecular biology techniques for isolating and monitoring pollutant-degrading bacteria.
Water Pollut. Res. J. Can.
28:275-287.
|
| 10.
|
Inniss, W. E., and C. I. Mayfield.
1978.
Growth rates of psychrotrophic sediment microorganisms.
Water Res.
12:231-236.
|
| 11.
|
Lai, B., and S. Khanna.
1996.
Mineralization of [14C]octacosane by Acinetobacter calcoaceticus S30.
Can. J. Microbiol.
42:1225-1231.
|
| 12.
|
Leahy, J. G., and R. R. Colwell.
1990.
Microbial degradation of hydrocarbons in the environment.
Microbiol. Rev.
54:305-315[Abstract/Free Full Text].
|
| 13.
|
Lechevalier, H. A.
1986.
Section 17: Nocardioforms, p. 1458-1506.
In
P. H. A. Sneath, N. S. Mair, M. E. Sharpe, and J. G. Holt (ed.), Bergey's manual of systematic bacteriology, vol. 2. The Williams and Wilkins Co., Baltimore, Md.
|
| 14.
|
Ludwig, B.,
A. Akundi, and K. Kendall.
1995.
A long-chain secondary alcohol dehydrogenase from Rhodococcus erythropolis ATCC 4277.
Appl. Environ. Microbiol.
61:3729-3733[Abstract].
|
| 15.
|
Margesin, R., and F. Schinner.
1997.
Bioremediation of diesel-oil-contaminated alpine soils at low temperatures.
Appl. Microbiol. Biotechnol.
47:462-468.
|
| 16.
|
Margesin, R., and F. Schinner.
1997.
Efficiency of indigenous and inoculated cold-adapted soil microorganisms for biodegradation of diesel oil in alpine soils.
Appl. Environ. Microbiol.
63:2660-2664[Abstract].
|
| 17.
|
Muller, R.,
O. Asperger, and H. P. Kleber.
1989.
Purification of cytochrome P-450 from n-hexadecane-grown Acinetobacter calcoaceticus.
Biomed. Biochim. Acta
48:243-254[Medline].
|
| 18.
|
Munroe, A. W., and J. G. Lindsay.
1996.
Bacterial cytochromes P-450.
Mol. Microbiol.
20:1115-1125[Medline].
|
| 19.
|
Munroe, A. W.,
J. G. Lindsay, and J. R. Coggins.
1993.
Alkane metabolism by cytochrome P-450 BM-3.
Biochem. Soc. Trans.
21:412S[Medline].
|
| 20.
|
Nagy, I.,
G. Schoofs,
F. Compernolle,
P. Proost,
J. Vanderleyden, and R. De Mot.
1995.
Degradation of the thiocarbamate herbicide EPTC (S-ethyl dipropylcarbamothioate) and biosafening by Rhodococcus sp. strain NI86/21 involve an inducible cytochrome P-450 system and aldehyde dehydrogenase.
J. Bacteriol.
177:676-687[Abstract/Free Full Text].
|
| 21.
|
Potter, D. W., and J. Pawliszyn.
1994.
Rapid determination of polyaromatic hydrocarbons and polychlorinated biphenyls in water using solid-phase microextraction and GC-MS.
Environ. Sci. Technol.
28:298-305.
|
| 22.
|
Rainey, F. A.,
J. Burghardt,
R. M. Kroppenstedt,
S. Klatte, and E. Stackebrandt.
1995.
Phylogenetic analysis of the genera Rhodococcus and Nocardia and evidence for the evolutionary origin of the genus Nocardia from within the radiation of Rhodococcus species.
Microbiology
141:523-528.
|
| 23.
|
Sakai, Y.,
J. H. Maeng,
S. Kubato,
A. Tani,
Y. Tani, and N. Kato.
1996.
A nonconventional dissimilation pathway for long chain n-alkanes in Acinetobacter sp. M-1 that starts with a dioxygenase reaction.
J. Ferment. Bioeng.
81:286-291.
|
| 24.
|
Sambrook, J.,
E. F. Fritsch, and T. Maniatis.
1989.
Molecular cloning: a laboratory manual, 2nd ed.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 25.
|
Sariaslani, F. S.
1991.
Microbial cytochromes P-450 and xenobiotic metabolism.
Adv. Appl. Microbiol.
36:133-178[Medline].
|
| 26.
|
Sariaslani, F. S., and C. A. Omer.
1992.
Actinomycete cytochromes P-450 involved in oxidative metabolism: biochemistry and molecular biology.
Crit. Rev. Plant Sci.
11:1-16.
|
| 27.
|
Tongpim, S., and M. A. Pickard.
1996.
Growth of Rhodococcus S1 on anthracene.
Can. J. Microbiol.
42:289-294[Medline].
|
| 28.
|
van Beilen, J. B.,
M. G. Wubbolts, and B. Witholt.
1994.
Genetics of alkane oxidation by Pseudomonas oleovorans.
Biodegradation
5:161-174[Medline].
|
| 29.
|
Warhurst, A. M., and C. A. Fewson.
1994.
Biotransformations catalyzed by the genus Rhodococcus.
Crit. Rev. Biotechnol.
14:29-73[Medline].
|
| 30.
|
Watkinson, R., and P. Morgan.
1990.
Physiology of aliphatic hydrocarbon-degrading microorganisms.
Biodegradation
1:79-92[Medline].
|
| 31.
|
Westlake, D. W. S.,
A. Jobson,
R. Phillippe, and F. D. Cook.
1974.
Biodegradability and crude oil composition.
Can. J. Microbiol.
20:915-928[Medline].
|
| 32.
|
Whyte, L. G.,
C. W. Greer, and W. E. Inniss.
1996.
Assessment of the biodegradation potential of psychrotrophic microorganisms.
Can. J. Microbiol.
42:99-106[Medline].
|
| 33.
|
Whyte, L. G.,
L. Bourbonnière, and C. W. Greer.
1997.
Biodegradation of petroleum hydrocarbons by psychrotrophic Pseudomonas strains possessing both alkane (alk) and naphthalene (nah) catabolic pathways.
Appl. Environ. Microbiol.
63:3719-3723[Abstract].
|
Appl Environ Microbiol, July 1998, p. 2578-2584, Vol. 64, No. 7
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Yergeau, E., Arbour, M., Brousseau, R., Juck, D., Lawrence, J. R., Masson, L., Whyte, L. G., Greer, C. W.
(2009). Microarray and Real-Time PCR Analyses of the Responses of High-Arctic Soil Bacteria to Hydrocarbon Pollution and Bioremediation Treatments. Appl. Environ. Microbiol.
75: 6258-6267
[Abstract]
[Full Text]
-
Alonso-Gutierrez, J., Figueras, A., Albaiges, J., Jimenez, N., Vinas, M., Solanas, A. M., Novoa, B.
(2009). Bacterial Communities from Shoreline Environments (Costa da Morte, Northwestern Spain) Affected by the Prestige Oil Spill. Appl. Environ. Microbiol.
75: 3407-3418
[Abstract]
[Full Text]
-
Greer, S., Wen, M., Bird, D., Wu, X., Samuels, L., Kunst, L., Jetter, R.
(2007). The Cytochrome P450 Enzyme CYP96A15 Is the Midchain Alkane Hydroxylase Responsible for Formation of Secondary Alcohols and Ketones in Stem Cuticular Wax of Arabidopsis. Plant Physiol.
145: 653-667
[Abstract]
[Full Text]
-
Kotani, T., Yurimoto, H., Kato, N., Sakai, Y.
(2007). Novel Acetone Metabolism in a Propane-Utilizing Bacterium, Gordonia sp. Strain TY-5. J. Bacteriol.
189: 886-893
[Abstract]
[Full Text]
-
Bradley, P. M., Richmond, S., Chapelle, F. H.
(2005). Chloroethene Biodegradation in Sediments at 4{degrees}C. Appl. Environ. Microbiol.
71: 6414-6417
[Abstract]
[Full Text]
-
Rapp, P., Gabriel-Jurgens, L. H. E.
(2003). Degradation of alkanes and highly chlorinated benzenes, and production of biosurfactants, by a psychrophilic Rhodococcus sp. and genetic characterization of its chlorobenzene dioxygenase. Microbiology
149: 2879-2890
[Abstract]
[Full Text]
-
Margesin, R., Labbe, D., Schinner, F., Greer, C. W., Whyte, L. G.
(2003). Characterization of Hydrocarbon-Degrading Microbial Populations in Contaminated and Pristine Alpine Soils. Appl. Environ. Microbiol.
69: 3085-3092
[Abstract]
[Full Text]
-
Mikolasch, A., Hammer, E., Schauer, F.
(2003). Synthesis of Imidazol-2-yl Amino Acids by Using Cells from Alkane-Oxidizing Bacteria. Appl. Environ. Microbiol.
69: 1670-1679
[Abstract]
[Full Text]
-
Eriksson, M., Sodersten, E., Yu, Z., Dalhammar, G., Mohn, W. W.
(2003). Degradation of Polycyclic Aromatic Hydrocarbons at Low Temperature under Aerobic and Nitrate-Reducing Conditions in Enrichment Cultures from Northern Soils. Appl. Environ. Microbiol.
69: 275-284
[Abstract]
[Full Text]
-
Whyte, L. G., Smits, T. H. M., Labbe, D., Witholt, B., Greer, C. W., van Beilen, J. B.
(2002). Gene Cloning and Characterization of Multiple Alkane Hydroxylase Systems in Rhodococcus Strains Q15 and NRRL B-16531. Appl. Environ. Microbiol.
68: 5933-5942
[Abstract]
[Full Text]
-
Iwabuchi, N., Sunairi, M., Urai, M., Itoh, C., Anzai, H., Nakajima, M., Harayama, S.
(2002). Extracellular Polysaccharides of Rhodococcus rhodochrous S-2 Stimulate the Degradation of Aromatic Components in Crude Oil by Indigenous Marine Bacteria. Appl. Environ. Microbiol.
68: 2337-2343
[Abstract]
[Full Text]
-
Alvarez, H. M., Luftmann, H., Silva, R. A., Cesari, A. C., Viale, A., Waltermann, M., Steinbuchel, A.
(2002). Identification of phenyldecanoic acid as a constituent of triacylglycerols and wax ester produced by Rhodococcus opacus PD630. Microbiology
148: 1407-1412
[Abstract]
[Full Text]
-
Margesin, R., Schinner, F.
(2001). Bioremediation (Natural Attenuation and Biostimulation) of Diesel-Oil-Contaminated Soil in an Alpine Glacier Skiing Area. Appl. Environ. Microbiol.
67: 3127-3133
[Abstract]
[Full Text]
-
Iwabuchi, N., Sunairi, M., Anzai, H., Nakajima, M., Harayama, S.
(2000). Relationships between Colony Morphotypes and Oil Tolerance in Rhodococcus rhodochrous. Appl. Environ. Microbiol.
66: 5073-5077
[Abstract]
[Full Text]
-
Colores, G. M., Macur, R. E., Ward, D. M., Inskeep, W. P.
(2000). Molecular Analysis of Surfactant-Driven Microbial Population Shifts in Hydrocarbon-Contaminated Soil. Appl. Environ. Microbiol.
66: 2959-2964
[Abstract]
[Full Text]
-
Solano-Serena, F., Marchal, R., Casarégola, S., Vasnier, C., Lebeault, J.-M., Vandecasteele, J.-P.
(2000). A Mycobacterium Strain with Extended Capacities for Degradation of Gasoline Hydrocarbons. Appl. Environ. Microbiol.
66: 2392-2399
[Abstract]
[Full Text]
-
Whyte, L. G., Slagman, S. J., Pietrantonio, F., Bourbonnière, L., Koval, S. F., Lawrence, J. R., Inniss, W. E., Greer, C. W.
(1999). Physiological Adaptations Involved in Alkane Assimilation at a Low Temperature by Rhodococcus sp. Strain Q15. Appl. Environ. Microbiol.
65: 2961-2968
[Abstract]
[Full Text]
Top
Abstract
Introduction
