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Previous Article | Next Article 
Applied and Environmental Microbiology, July 1999, p. 2961-2968, Vol. 65, No. 7
0099-2240/99/$04.00+0
Physiological Adaptations Involved in Alkane
Assimilation at a Low Temperature by Rhodococcus sp.
Strain Q15
L. G.
Whyte,1,*
S. J.
Slagman,1
F.
Pietrantonio,1
L.
Bourbonnière,1
S. F.
Koval,2
J. R.
Lawrence,3
W. E.
Inniss,4 and
C.
W.
Greer1
NRC-Biotechnology Research Institute,
Montreal, Quebec, Canada H4P 2R21;
University of Western Ontario, London, Ontario, Canada N6A
5C12; National Water Research Institute,
Environment Canada, Saskatoon, Saskatchewan, Canada S7N
3H5,3 and University of Waterloo,
Waterloo, Ontario, Canada N2L 3G14
Received 5 January 1999/Accepted 20 April 1999
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ABSTRACT |
We examined physiological adaptations which allow the psychrotroph
Rhodococcus sp. strain Q15 to assimilate alkanes at a low temperature (alkanes are contaminants which are generally insoluble and/or solid at low temperatures). During growth at 5°C on hexadecane or diesel fuel, strain Q15 produced a cell surface-associated biosurfactant(s) and, compared to glucose-acetate-grown cells, exhibited increased cell surface hydrophobicity. A transmission electron microscopy examination of strain Q15 grown at 5°C revealed the presence of intracellular electron-transparent
inclusions and flocs of cells connected by an extracellular polymeric
substance (EPS) when cells were grown on a hydrocarbon and
morphological differences between the EPS of glucose-acetate-grown
and diesel fuel-grown cells. A lectin binding analysis performed by
using confocal scanning laser microscopy (CSLM) showed that the EPS contained a complex mixture of glycoconjugates, depending on both the
growth temperature and the carbon source. Two glycoconjugates [
-D-Gal-(1-3)-D-GlcNAc and
-L-fucose] were detected only on the surfaces of cells
grown on diesel fuel at 5°C. Using scanning electron microscopy, we
observed strain Q15 cells on the surfaces of octacosane crystals, and
using CSLM, we observed strain Q15 cells covering the surfaces of
diesel fuel microdroplets; these findings indicate that this organism
assimilates both solid and liquid alkane substrates at a low
temperature by adhering to the alkane phase. Membrane fatty acid
analysis demonstrated that strain Q15 adapted to growth at a low
temperature by decreasing the degree of saturation of membrane lipid
fatty acids, but it did so to a lesser extent when it was grown on
hydrocarbons at 5°C; these findings suggest that strain Q15 modulates
membrane fluidity in response to the counteracting influences of low
temperature and hydrocarbon toxicity.
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INTRODUCTION |
A significant problem in
biodegradation of hydrocarbon contaminants is the very low solubility
of the compounds in the aqueous phase. This is especially true at lower
temperatures, at which longer-chain alkanes (>C10) are
generally more insoluble or exist as solids; this hinders the
biodegradative activity of psychrotrophic and psychrophilic bacteria.
The resulting decreased bioavailability is responsible for the
recalcitrance of the compounds commonly observed in temperate and
cold environments. Nevertheless, cold-adapted hydrocarbon-degrading microorganisms can degrade these substrates at
temperatures as low as 0°C (45-47) and, therefore, are
physiologically able to take up and assimilate the compounds at low temperatures.
Although the actual uptake of alkanes by bacteria is thought to be a
passive transport process, microorganisms possess a number of adaptive
mechanisms for accumulating and transporting hydrocarbons into the cell
for initial enzymatic catabolism (17, 36, 44). Bacteria
transport and assimilate soluble alkanes that are dissolved in the
aqueous phase. Indeed, it was initially thought that bacteria could
utilize only solubilized hydrocarbons (7). However,
alkanes are degraded at rates which exceed the rates of dissolution of hydrocarbons in the aqueous phase, indicating that other uptake mechanisms are also utilized by hydrocarbon-degrading
microorganisms (25, 41). Many bacteria are capable of
emulsifying hydrocarbons in solution by producing surface-active
agents, such as biosurfactants (10, 17, 29). These
amphiphatic compounds reduce surface tension by accumulating at the
interface of immiscible fluids or of a fluid and a solid and increasing
the surface areas of insoluble compounds, which leads to increased
bioavailability and subsequent biodegradation of the hydrocarbons
(25). Microorganisms may also take up insoluble hydrocarbons
by adhering to hydrocarbons at the water-hydrocarbon liquid or
solid interface (7, 17, 33, 42, 44). To facilitate adhesion
to hydrophobic substrates, hydrocarbon-degrading bacteria may
increase cell surface hydrophobicity by modifying cell surface
components (43). In addition, microbial cells may produce
extracellular polymeric substances (EPS) in the form of capsules or
mucoid secretions that may interact with hydrophobic substrates, such
as hydrocarbons (48, 49).
Bacteria are also known to adapt to changes in environmental
conditions, such as growth temperature or growth in the presence of
hydrocarbon substrates, by altering the lipid composition of the
cytoplasmic membrane in order to maintain or adjust membrane bilayer
fluidity (26, 36). Alterations to the fatty acid moieties of
membrane lipids are thought to be the most effective means of
maintaining the liquid crystalline state in membranes, which is
essential for optimal membrane function (16). During growth at low temperatures, bacteria can modulate the viscosity of membrane lipids to maintain or increase membrane fluidity by decreasing the
degree of saturation, by shortening the acyl chain length, by
increasing the cis/trans fatty acid ratio, and by increasing the relative amount of branched fatty acids (9, 16). The effects of adding hydrophobic growth substrates like hydrocarbons are
completely opposite the effects observed during low-temperature growth
and mimic changes observed during bacterial growth at high temperatures. In this case, an increased degree of saturation or
conversion of cis fatty acids to trans fatty
acids is commonly observed (14, 36). These changes act as
protective mechanisms against hydrocarbon-associated toxicity by
rendering the membrane less permeable to hydrocarbons (36).
In the present study, we examined physiological adaptations involved in
alkane assimilation at a low temperature by Rhodococcus sp.
strain Q15, a psychrotroph that is capable of mineralizing a variety of
alkanes and can grow on and emulsify diesel fuel and Bunker C crude oil
at both 5 and 24°C (47). The ability of strain Q15 to
produce biosurfactant and its ability to alter its cell membrane by
changing the fatty acid composition in response to both growth
temperature and carbon source were also examined. Possible structural
and morphological adaptations of strain Q15 cells grown at 5°C on
various alkanes were also examined by transmission electron
microscopy (TEM), scanning electron microscopy (SEM), and
confocal scanning laser microscopy (CSLM).
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
Rhodococcus
sp. strain Q15 was originally isolated from Bay of Quinte, Lake
Ontario, Canada (18), and was characterized by Whyte et al.
(47). Strain Q15 was grown on Trypticase soy agar at 24°C
and was maintained at 4°C. In growth experiments performed with
different carbon sources, strain Q15 was grown on a mineral salts
medium (MSM) (12) supplemented with 0.005% yeast extract
and 0.2% (wt/vol) hexadecane, 0.2% (wt/vol) diesel fuel, 0.2%
(wt/vol) octacosane, or 0.2% (wt/vol) glucose-acetate (1:1, wt/wt) as
the carbon and energy source.
Surface tension and hydrophobicity analyses of
Rhodococcus sp. strain Q15.
In order to detect the
formation of a biosurfactant(s) by Rhodococcus sp. strain
Q15, cells were grown in a water bath shaker (150 rpm) at 5 or 24°C
in 125-ml screw-cap flasks containing 50 ml of MSM supplemented with
hexadecane, diesel fuel, or glucose-acetate. Cellular growth was
monitored by determining the optical density at 600 nm
(OD600). Each culture was transferred to a Pyrex beaker (50 by 70 mm), and the surface tension was measured with a model 21 Surface
Tensiomat (Fisher Scientific, Toronto, Ontario, Canada). To determine
if strain Q15 biosurfactant was released into the medium or remained
associated with the cells, 25 ml of culture medium was centrifuged
(12,000 × g, 10 min, 4°C), and the cell-free supernatant was separated from the cell pellet. The latter was resuspended in 25 ml of fresh MSM, and the surface tensions of both
fractions were determined. All surface tension measurements were
performed in duplicate. The cell surface hydrophobicities of strain Q15
grown on various carbon sources at 5°C and collected by
centrifugation were determined by the microbial adhesion to hydrocarbon
(MATH) test essentially as previously described (32, 34) by
using dodecane as the test liquid hydrocarbon.
TEM and SEM analyses of Rhodococcus sp. strain Q15
cells.
To prepare thin sections for TEM, glucose-acetate-grown
cells were collected by centrifugation and fixed with 2% (vol/vol) glutaraldehyde in 0.1 M sodium cacodylate buffer (pH 7.3) containing 0.015% (wt/vol) ruthenium red. Cells were enrobed in agar and fixed
with 1% (wt/vol) osmium tetroxide and 1% (wt/vol) uranyl acetate,
both of which contained 0.015% (wt/vol) ruthenium red. Samples were
dehydrated by using an ethanol series and were embedded in LR White
resin. Cells grown on diesel fuel were first deposited on a thin layer
of Noble agar in a small glass petri dish and covered with another thin
layer of Noble agar. The glutaraldehyde-ruthenium red fixative was
added to the agar containing the cells. After fixation for 2 h,
the agar was cut into small blocks, and the specimens were processed as
described above. Some thin sections were poststained with uranyl
acetate and lead citrate. All specimens were examined with a Philips
model EM300 TEM operating at 60 kV.
For SEM, crystals of octacosane on which strain Q15 cells were grown
were transferred to 1 ml of 2% (vol/vol) glutaraldehyde in 0.1 M
sodium cacodylate buffer (pH 7.3). The cells were postfixed with 1%
(wt/vol) osmium tetroxide in buffer, dehydrated by using ethanol and
acetone, and then critical point dried. The crystals were taped onto
silicon chips, gold coated, and examined with a Hitachi model S-4500 SEM.
CSLM analysis of Rhodococcus sp. strain Q15.
A
Bio-Rad model MRC 1000 CSLM consisting of a krypton-argon laser system
mounted on a Nikon model Microphot-SA microscope was used to
nondestructively obtain images of strain Q15 cells grown at 5 or 24°C
on MSM containing either glucose-acetate, diesel fuel, or octacosane.
Cells grown at 5°C were kept at 5°C during staining and preparation
for observation and analysis, and all microscopy was performed by using
a microscope stage cooled at 5°C (Physitemp Instruments, Clifton,
N.J.). Observations of some diesel fuel- and glucose-acetate-grown
cells were carried out in 0.5-mm-deep well slides covered with no. 1 coverslips (Fisher Scientific, Montreal, Quebec, Canada), which allowed
imaging of undisturbed cell mass and diesel fuel microdroplets. The
microscope was equipped with a 60×, 1.4-numerical-aperture oil
immersion lens (Nikon Corporation, Chiyoda-ku, Tokyo). The CSLM was
operated as described previously (21). Optical thin sections
in the xy plane, as well as xz sagittal images, were obtained. In
addition, SYTO 9 (Molecular Probes, Eugene, Oreg.) was used as a
nucleic acid stain to positively stain strain Q15 cells
(24). Strain Q15 biofilm material was positively stained
with Nile Red (Eastman Kodak Co., Rochester, N.Y.), a hydrophobic
compound-specific benzophenoxazinone dye (20). A staining
solution containing 5 µg of Nile Red ml
1 (final
concentration) in 50% aqueous glycerol was prepared from a 1-mg
ml1 stock solution of Nile Red dissolved in acetone. A
panel of fluor-conjugated lectins, derived from Arachis
hypogaea, Canavalia ensiformis, Tetragonolobus
purpureas, Triticum vulgaris, and Ulex
europeaus (Sigma Chemical Co., St. Louis, Mo.), was used to detect
and assess the presence of EPS and to provide information on the
chemical nature of EPS. The methods used have been described in detail previously (22, 23, 49).
Analysis of cell membrane fatty acid composition in
Rhodococcus sp. strain Q15.
Three 100-ml
cultures of cells grown until the late exponential phase on MSM
containing either glucose-acetate, hexadecane, or diesel fuel were
centrifuged (10 min, 9,000 × g, 4°C) and washed twice with 0.1 M potassium phosphate buffer (pH 7.0). The free and
loosely bound lipids of pelleted cells were extracted basically as
previously described by Bligh and Dyer (6). Methyl esters of
fatty acids were prepared as previously described (27). The fatty acid methyl esters were analyzed by gas chromatography by using a model Sigma 2000 capillary chromatograph (Perkin-Elmer, Norwalk, Conn.) equipped with a type DB-225 column (J&W Scientific, Folsom, Calif.) and a flame ionization detector (Perkin-Elmer). Helium
was the carrier gas, and the flow rate was 2.5 ml/min. Samples
(approximately 1 ml) were injected via a split injection port with a
split ratio of 1:9. The initial temperature of the column was 180°C,
and the temperature was increased at a rate of 2°C/min to
220°C; then the temperature was increased at a rate of 5°C/min to
235°C and then kept constant for 7 min. The temperatures of both the
injection port and the detector were kept constant at 240°C.
Following the gas chromatography analysis, the mass percentage of each
fatty acid was calculated by comparing the area of each individual
fatty acid peak to the total area.
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RESULTS |
Surface tension and hydrophobicity analyses of
Rhodococcus sp. strain Q15.
The surface tensions of
culture media were measured during strain Q15 growth at 5 or 24°C on
various carbon sources. During growth at 5°C on glucose-acetate, the
surface tension of the culture medium remained ~70 mN/m (Fig.
1). The surface tension of the culture
medium decreased to ~40 mN/m during growth on diesel fuel at 5°C
(Fig. 1). Following separation of diesel fuel-grown cells from the
culture supernatant, the biosurfactant activity was present in cell
pellets resuspended in fresh MSM but not in the cell-free supernatant,
indicating that the biosurfactant remained associated with the cell
envelope and was not excreted into the medium. As in diesel fuel-grown
cells, biosurfactant activity was observed in cells grown on hexadecane
at 5°C; this activity also was present in the resuspended cell
pellet (data not shown). Similar results were obtained at 24°C, at
which the surface tension was ~36 mN/m in hexadecane- and
diesel fuel-grown cells but remained at 70 mN/m in
glucose-acetate-grown cells. Determining cellular growth by measuring
the OD600 proved to be difficult when strain Q15 was grown
with either hexadecane or diesel fuel as the carbon and energy source
due to the formation of large, adhesive cellular flocs with low buoyant
densities. However, in the case of diesel fuel-grown cells,
reproducible results could be obtained by covering the cuvette with
Parafilm, inverting the cuvette five times, and then immediately
determining the OD600.
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FIG. 1.
Growth of Rhodococcus sp. strain Q15 at 5°C
with glucose-acetate (A) or diesel fuel (B) as the carbon and energy
source and changes in the surface tensions in the cultures, the
supernatants, and the pellet fractions. The surface tension values are
means based on duplicate determinations. ST, surface tension; A600,
absorbance at 600 nm.
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The relative cell surface hydrophobicity of strain Q15 grown at 5°C,
as measured by the MATH test, was greater in pelleted cells following
growth on diesel fuel (41.1% ± 5.5% [mean ± standard deviation]) and hexadecane (20.8% ± 6.5%) than in cells grown on
glucose-acetate (9.3% ± 1.7%). Similar results were obtained for
cells grown at 24°C.
TEM and SEM analyses of Rhodococcus sp. strain
Q15.
Strain Q15 grew as freely suspended cells in glucose-acetate
medium. Cells fixed in the presence of ruthenium red were surrounded by
a delicate web of fibers (Fig. 2A). This
finely contrasted zone of capsular material was very extensive but did
not cause the cells to adhere to each other. Floc phase cells of strain Q15 grown on diesel fuel were also fixed in the presence of ruthenium red. Because the floc material was difficult to collect by
centrifugation, the flocs were gently deposited on a thin layer of
Noble agar in a small glass petri dish, covered with another thin layer
of agar, and then exposed to glutaraldehyde containing ruthenium red.
In thin sections, finely contrasted clusters of EPS were found
surrounding and connecting many cells which were clumped together
within the floc (Fig. 2B). Large, spherical, electron-transparent inclusions were present in the diesel fuel-grown cells (Fig. 2B) but not in glucose-acetate-grown cells. Some inclusions contained electron-dense material, as shown in Fig. 2B. The inclusions were not
membrane bound. The cell envelope profiles were the same in glucose-acetate- and diesel fuel-grown cells.
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FIG. 2.
TEM micrographs of Rhodococcus sp. strain Q15
cells obtained during growth on glucose-acetate or diesel fuel at
5°C. (A) Strain Q15 grown on glucose-acetate and fixed in the
presence of ruthenium red. The organism occurred as single cells which
were surrounded by EPS consisting of a delicate web of fibers
consistent with bacterial capsular material. (B) Floc phase cells of
strain Q15 grown on diesel fuel and fixed in the presence of ruthenium
red. In thin sections, finely contrasted clusters of EPS material
surrounded cells within the flocs. The arrow indicates an intracellular
inclusion. Bars = 500 nm.
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Strain Q15 cells grown on octacosane at 5°C were observed by SEM on
the surfaces of and adhering to octacosane crystals (Fig. 3). Similar observations of Q15 cells on
the surfaces of octacosane crystals were made by CSLM (data not shown).
EPS was visible by SEM as strands and fibers between cells and clumps
on the surfaces of the cells.
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FIG. 3.
SEM micrograph of Rhodococcus sp. strain Q15,
showing groups of cells colonizing the surface of an octacosane crystal
during growth at 5°C. Strands and fibers (fingerlike projections) of
EPS were observed on the cell surface between cells and between cells
and the surface of the octacosane crystal.
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CSLM analysis of Rhodococcus sp. strain Q15.
CSLM
allows direct in situ observation of fully hydrated, intact samples,
such as biofilms, which avoids the problems associated with dehydration
artifacts during TEM and SEM preparation and analysis. We observed that
5°C strain Q15 cells completely surrounded and adhered to the
surfaces of diesel fuel microdroplets which were ~10 to 16 µm in
diameter (Fig. 4A). xz optical sectioning through a diesel fuel microdroplet showed that strain Q15 cells were
not inside the diesel fuel microdroplets (Fig. 4B). At 24°C, diesel fuel microdroplets were not observed.
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FIG. 4.
CSLM of Rhodococcus sp. strain Q15 cells
grown on diesel fuel at 5°C. (A) Three-dimensional projections
presented as a stereo pair showing a z series through an SYTO 9-stained
strain Q15 biofilm grown on diesel fuel as the sole C source. Note the
basal layer of attached cells on the slide surface and the
microdroplets of diesel fuel surrounded by cells of strain Q15. (B)
Series of xz optical sections through the diesel fuel microdroplets
shown in panel A. The upper surface was a glass coverslip overlying a
well slide. The cells grown on diesel fuel were transferred to the well
slide and covered with a glass coverslip, and microdroplets were
observed after they rose to contact the upper glass surface. The cells
were maintained at 5°C, and no fixation or immobilization of the
droplets was performed.
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A CSLM analysis performed with fluor-conjugated lectins was used to
characterize the EPS present in biological matrices, such as biofilms
and cell surfaces (48). Lectins are plant- and
animal-derived proteins which bind to glycoconjugate residues
(glycolipids, glycoproteins, and polysaccharides) with high
levels of specificity, which allows characterization of
their chemical nature and physical distribution in biological
matrices. In the present study, CSLM image analysis revealed that the
five lectins used bound, to different extents to the exterior surfaces
of strain Q15 cells depending on both the growth temperature and the
carbon source (Table 1). For example, the
lectins from C. ensiformis and T. purpureas bound
to cells during growth on diesel fuel at 5°C (Fig.
5). At 5°C, the EPS surrounding
diesel fuel-grown cells contained a mixture of glycoconjugates that may
have included fucose, glucose, mannose, (GluNAc)2, and -D-Gal-(1-3)-D-GlcNAc, as well as perhaps
GlcNAc and NeuNAc (Table 1). These observations indicated that the
chemical composition of the EPS in the biofilm matrix was complex.
Interestingly, -D-Gal-(1-3)-D-GlcNAc, and
(to a lesser extent) fucose, appeared only on the surfaces of cells
grown on diesel fuel at 5°C, suggesting that formation of these
compounds may have been an adaptive response to low-temperature growth
on this substrate. In contrast to the results obtained after growth on
diesel fuel at 5°C, none of the five lectins bound to cells grown on
glucose-acetate (Table 1) at 5°C, although some of them did bind
strongly to Q15 EPS at 24°C. It was also apparent that there was
extensive production of EPS that was not bound to cells at 24°C,
particularly EPS binding the C. ensiformis lectin.
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TABLE 1.
Effects of carbon source (glucose-acetate or diesel fuel)
and temperature (5 or 24°C) on lectin binding to cells and
exopolymer of Rhodococcus sp. strain Q15
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FIG. 5.
CSLM xy images showing binding of the C. ensiformis (A) and T. purpureas (B) lectins to cells of
strain Q15 grown at 5°C with diesel fuel as the sole carbon source.
C. ensiformis lectin appeared to bind to the exterior
surfaces of the diesel fuel microdroplets in the biofilm, creating a
bright boundary region. There is also some evidence that there were
binding sites within the diesel fuel droplets. The T. purpureas lectin binding was extensive at the cell surface and
occurred between cells and within the microdroplets. In addition, there
is evidence that an emulsion was formed within the microdroplets and in
the vicinity of Q15 cells.
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Analysis of cell membrane fatty acid composition in
Rhodococcus sp. strain Q15.
Rhodococcus sp.
strain Q15 cells were grown on MSM supplemented with either
glucose-acetate, diesel fuel, or hexadecane at 5 or 24°C to determine
changes in the fatty acid composition of the readily extractable lipids
in response to both changes in temperature and different carbon
sources. Overall, the acyl chain lengths of the observed fatty acids
ranged from C14 to C18; C16 and
C18 fatty acids were generally the most prominent fatty
acids regardless of the temperature or carbon source. However, the
carbon source greatly influenced the overall composition of the fatty acid profile (Fig. 6). Compared with
glucose-acetate-grown cells, relatively small amounts of
C18 fatty acids were detected in hexadecane-grown cells and
the relative amounts of C16 and C14:0 fatty
acids were greater, especially at 24°C. The fatty acid profiles of
strain Q15 cells grown on diesel fuel contained the greatest variety of
fatty acid species, which perhaps reflected the relatively complex
chemical composition of the diesel fuel substrate.
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FIG. 6.
Comparison of fatty acid profiles of
Rhodococcus sp. strain Q15 cells grown on glucose-acetate,
hexadecane, or diesel fuel at 5 or 24°C. Unk, unknown, putative fatty
acid; c, cis, t, trans; cyc, cylcopropane; Me,
methyl. The values are means based on triplicate samples (standard
deviation, <10% of mean). Unknown fatty acids 3 and 4, which were
present in relatively large quantities in cells grown on hexadecane at
5°C, were tentatively identified by gas chromatography-mass
spectrometry as C16:1 and methyl-C15:0,
respectively.
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We also observed differences in specific fatty acids in response to
growth temperature. In glucose-grown cells, a decrease in the amount of
saturated C16:0 and increases in the amounts of
cis-9-C16:1 and
trans-9-C16:1 occurred at 5°C compared with 24°C. A similar shift was observed for C18 fatty acids.
In hexadecane-grown cells, a shift from saturated to unsaturated fatty
acids was observed for the C16 and C14 fatty
acids at 5°C. Relatively large quantities of putative fatty acids 3 and 4, which were tentatively identified by gas chromatography-mass
spectrometry analysis as C16:1 and methyl-C15:0, respectively, were present in cells grown on
hexadecane at 5°C, indicating that these compounds might be important
in maintaining optimal membrane fluidity at this low temperature. For
cells grown on diesel fuel, the amounts of the putative fatty acids
were relatively high as well. There was a large decrease in the amount
of C16:0 when cells grown on diesel fuel at 5°C were
compared with cells grown on diesel fuel at 24°C, but no subsequent
increase in the amount of C16:1 was apparent. For the C18 fatty acids, relative increases in the amounts of both
cis-9-C18:1 and 10-methyl-C18:0 were
apparent at 5°C. In both diesel fuel-and hexadecane-grown cells the
relative amounts of both C17:0-cyclopropane and
C19:0-cyclopropane, as well as the relative amount of
C17:0, increased at 5°C. Interestingly, the opposite
result was obtained with glucose-acetate-grown cells, in which
C17:0-cyclopropane was found only during growth at 24°C.
The exact physiological role(s) of cyclopropane fatty acids is
presently unknown, but formation of these fatty acids in bacterial
cellular membranes may be an adaptation to starvation or other forms of
growth stasis (13).
To elucidate global adaptation mechanisms of membrane fatty acids in
strain Q15 in response to growth at a low temperature on hydrocarbon
substrates, the degree of saturation (i.e., saturated/unsaturated ratio) of fatty acids, the ratio of saturation at 24 and 5°C, the
average acyl chain length, and the cis/trans ratio were
determined and compared (Table 2).
Patterns indicating specific adaptations of strain Q15 to growth on
hydrocarbons at a low temperature were not clearly delineated by
comparing average acyl chain lengths and cis/trans ratios. A
comparison of the degrees of saturation strongly indicated that the
fatty acids changed from relatively saturated fatty acids at 24°C to
relatively unsaturated fatty acids at 5°C, regardless of the growth
substrate. However, this shift was approximately two-fold less in
hydrocarbon-grown cells than in glucose-acetate-grown cells, as
measured by the 24°C/5°C ratio of saturation (Table 2).
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TABLE 2.
Degree of saturation (saturated/unsaturated ratio),
average acyl chain length (numbers of C atoms), and
cis/trans ratio of fatty acids in
Rhodococcus sp. strain Q15 cells grown on different
carbon sources at 24 or 5°C
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DISCUSSION |
Physiological adaptations for alkane uptake at a low
temperature by the alkane-degrading psychrotrophic organism
Rhodococcus sp. strain Q15 were characterized in
order to better understand how this bacterium utilizes insoluble
hydrocarbon substrates at low temperatures. This psychrotroph produced
biosurfactant which was associated with the cell envelope and was
capable of lowering the surface tension during growth on diesel fuel or
hexadecane at both 5 and 24°C. To the best of our knowledge, this is
the first report of biosurfactant activity at low temperatures.
Cold-active solubilizing agents like the strain Q15 biosurfactant(s)
could prove to be very beneficial for successful bioremediation of
hydrocarbon-contaminated sites at low ambient temperatures by
increasing the bioavailability of recalcitrant hydrocarbons like
long-chain alkanes.
As biosurfactant activity was observed only during growth on
hydrocarbons and not during growth on glucose-acetate and as biosurfactant activity was observed during the late lag and early exponential phases of growth, the production of biosurfactant(s) by strain Q15 was induced and may be a prerequisite for strain Q15 growth on hydrocarbons. Although the biosurfactant(s) produced by
strain Q15 was not characterized, Rhodococcus
erythropolis, which is phylogenetically closely related to
strain Q15 (47), produces cell-bound biosurfactants
(30) during growth on alkanes, and these
biosurfactants have been identified as trehalose mycolate lipids
(19, 30, 31). These compounds, as well as lipoglycan, lipoprotein, and phospholipids, other known surface-active agents (10, 29), are found on the outer asymmetric lipid
bilayer recently hypothesized for the rhodococcal cell envelope
(38).
Microscopic examination revealed morphological changes, including
electron-transparent cellular inclusions, in strain Q15 cells when they
were grown in the presence of hydrocarbon substrates. Inclusions are a
common feature in bacteria grown on hydrocarbons, and similar
structures have been observed in a variety of gram-negative and
gram-positive bacteria, including rhodococci and other actinomycetes (1, 35), and are believed to be hydrophobic storage
compounds (35, 37).
The presence of EPS in diesel fuel- and hexadecane-grown cells was
anticipated because the cells formed flocs during growth on these
hydrocarbons. Patches or clusters of finely contrasted EPS were
observed in cells of strain Q15 grown on diesel fuel. The cell envelope
and cytoplasm of strain Q15 were stained well by the ruthenium red
concentration used in our studies, but the method used resulted in low
contrast for the EPS. The presence of EPS was not anticipated in strain
Q15 cells grown on glucose-acetate because the cells did not aggregate
during growth. However, glucose is known to stimulate the production of
capsules in many bacteria, and encapsulated bacteria do not usually
aggregate. The delicate web of fibers surrounding strain Q15 cells
grown on glucose-acetate is consistent with images of capsules of other
bacteria stabilized only by ruthenium red (4, 26). The
morphological differences between the EPS of glucose-acetate- and
diesel fuel-grown cells may reflect a difference in the chemistry of
the exopolymers. This idea is supported by CSLM observations which
revealed that significant changes to or adaptations of the EPS of
strain Q15 had occurred during growth on diesel fuel at 5°C,
including the appearance of two specific glycoconjugates found in this
bacterium's EPS under these growth conditions.
The ability of strain Q15 to adhere to both solid (octacosane) and
liquid (diesel fuel) hydrocarbon substrates is especially intriguing
and may be the key mechanism by which this organism takes in and
assimilates alkane substrates at low temperatures. The adhesion
observed may be related to the increased cell surface hydrophobicity of
strain Q15 cells observed during growth on hydrocarbons, as determined
by the MATH test performed with pelleted cells. The observation that
strain Q15 cells completely surrounded hydrophobic diesel fuel
microdroplets strongly indicates that the strain Q15 cell surface is
hydrophobic rather than hydrophilic. In addition, CSLM images of strain
Q15 cells grown at 5°C on diesel fuel and stained with the
hydrophobic stain Nile Red appeared to bind to a greater extent to the
surfaces of diesel fuel-grown cells than to the surfaces of
glucose-acetate-grown cells, indicating that there was an increase in
cell surface hydrophobicity and/or lipid content in the diesel
fuel-grown cells (data not shown). The presence and chain lengths of
mycolic acids in the cell envelopes of a variety of coryneform
bacteria, including Rhodococcus strains, were related to the
increased cell surface hydrophobicities of these organisms (5,
29).
The adhesion process may also be related to changes in or adaptations
to the cell surface of strain Q15 when the organism is grown on
hydrocarbons at 5°C. The ability of an alkane-degrading Acinetobacter sp. to adhere to fuel oil droplets was
attributed to the production of EPS, which allowed the cells to anchor
themselves to the surface (3). Indeed, EPS is thought to
bridge the gap between the secondary minimum (reversible attachment)
and the primary minimum (irreversible attachment), as described by the DLVO theory (11); in this case this allows direct contact
between the surfaces (i.e., EPS) of strain Q15 cells and the
hydrocarbon substrate. With close contact between the strain Q15 cell
and hydrocarbon surfaces achieved, a cell surface-associated
biosurfactant(s) could then solubilize the alkane substrates,
facilitating cellular uptake. A cell surface-associated polysaccharide
in another Rhodococcus sp. possesses biosurfactant activity
and increases cell surface hydrophobicity (28). The EPS may
also play a role in floc formation in strain Q15, enabling the cells to
remain in close physical contact with hydrocarbons, in the same manner
described previously for R. erythropolis during growth on
pentadecane (40) and for alkane-degrading yeasts
(37).
Membrane fatty acid analysis indicated that the counteracting effects
of growth at a low temperature and growth on hydrocarbons resulted in a
balanced response by Rhodococcus sp. strain Q15. This
psychrotroph adapted to growth at a low temperature by decreasing the
degree of saturation of the membrane lipid fatty acids in order to
maintain optimal membrane fluidity, like Rhodococcus rhodochrous (39). However, the extent of this
adaptation was not as great when strain Q15 was grown on aliphatic
substrates, indicating that strain Q15 cells adapted or protected
themselves during growth on the aliphatic substrates. The relatively
greater degree of saturation (two- to fivefold) observed at 5°C when
strain Q15 was grown on aliphatic substrates than when it was grown on glucose-acetate was indicative of the counteractive effects of hydrocarbon substrates on cytoplasmic membrane fatty acid composition. As the greatest relative degree of fatty acid saturation was found in
strain Q15 cells at both 5 and 24°C when they were grown on diesel
fuel, which is a complex mixture of long- and short-chain alkanes,
cyclic hydrocarbons, and aromatic compounds, the relatively greater
saturation may be a protective mechanism required by strain Q15 to
limit the toxicity of the short-chain alkanes present in diesel fuel.
This protective mechanism may be especially important during
low-temperature growth because volatilization of short-chain alkanes (<C10) is impeded, which results in increased
solubility of these compounds in the aqueous phase and,
consequently, increased microbial toxicity (2, 25).
Conversion of cis fatty acids to their
trans forms, an additional protective mechanism to
reduce hydrocarbon toxicity observed in a number of
Pseudomonas spp. (8, 14, 15), does not seem to
occur in Rhodococcus sp. strain Q15 as trans
fatty acids were not detected or were present only at low levels in the
fatty acid profiles of cells grown under the conditions tested. It
should be noted that during extraction of the lipids from hexadecane-
and diesel fuel-grown cells, the contents of the inclusions which were
observed in these cells during TEM analysis might have been isolated as
well. Consequently, the fatty acid profiles obtained may not precisely
reflect the fatty acid profiles of the membrane lipids; rather, they
may reflect the fatty acid profiles of the whole cells.
In conclusion, we observed numerous and complex physiological
cellular responses and adaptations involved in alkane
assimilation at a low temperature by Rhodococcus sp. strain
Q15. These included (i) production of a cell-bound
biosurfactant(s), (ii) augmentation of cell surface hydrophobicity,
(iii) production of intracellular inclusions, (iv) modification of the
EPS, and (v) alteration of membrane fatty acid composition. We are
currently isolating and characterizing the EPS of strain Q15 in order
to better understand its role in hydrocarbon utilization at low temperatures.
| |
ACKNOWLEDGMENTS |
The SEM and TEM expertise of Dale Weber of the University of
Waterloo and Judy Sholdice of the University of Western Ontario was
greatly appreciated.
| |
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.
Publication 41842 of the National Research Council Canada.
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Abstract
Introduction
