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Applied and Environmental Microbiology, January 2004, p. 363-369, Vol. 70, No. 1
0099-2240/04/$08.00+0     DOI: 10.1128/AEM.70.1.363-369.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

Saturable, Energy-Dependent Uptake of Phenanthrene in Aqueous Phase by Mycobacterium sp. Strain RJGII-135

Institute for Environmental Sciences, University of Shizuoka, Shizuoka 422-8526, Japan,¹ Department of Biological Sciences, University of Alberta, Edmonton, Alberta, Canada T6G 2E9,² Department of Chemical and Materials Engineering, University of Alberta, Edmonton, Alberta, Canada T6G 2G6³

Received 8 July 2003/ Accepted 29 September 2003

	ABSTRACT

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The mechanism of uptake of phenanthrene by Mycobacterium sp. strain RJGII-135, a polycyclic hydrocarbon-degrading bacterium, was examined with cultures grown on phenanthrene (induced for phenanthrene metabolism) and acetate (uninduced). Washed cells were suspended in aqueous solutions of [9-¹⁴C]phenanthrene, and then the cells were collected by filtration. Low-level steady-state ¹⁴C concentrations in uninduced cells were achieved within the first 15 s of incubation. This immediate uptake did not show saturation kinetics and was not susceptible to inhibitors of active transport, cyanide and carbonyl cyanide m-chlorophenylhydrazone. These results indicated that phenanthrene enters rapidly into the cells by passive diffusion. However, induced cells showed cumulative uptake over several minutes. The initial uptake rates followed saturation kinetics, with an apparent affinity constant (K_t) of 26 ± 3 nM (mean ± standard deviation). Uptake of phenanthrene by induced cells was strongly inhibited by the inhibitors. Analysis of cell-associated ¹⁴C-labeled compounds revealed that the concurrent metabolism during uptake was rapid and was not saturated at the substrate concentrations tested, suggesting that the saturable uptake observed reflects membrane transport rather than intracellular metabolism. These results were consistent with the presence of a saturable, energy-dependent mechanism for transport of phenanthrene in induced cells. Moreover, the kinetic data for the cumulative uptake suggested that phenanthrene is specifically bound by induced cells, based on its saturation with an apparent dissociation constant (K_d) of 41 ± 21 nM (mean ± standard deviation). Given the low values of K_t and K_d, Mycobacterium sp. strain RJGII-135 may use a high-affinity transport system(s) to take up phenanthrene from the aqueous phase.

	INTRODUCTION

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Many polycyclic aromatic hydrocarbons (PAHs) such as naphthalene, phenanthrene, fluoranthene, anthracene, pyrene, benz[a]anthracene, and benzo[a]pyrene are known to be utilized as sole carbon and energy sources, or are degraded cometabolically, by a diverse group of bacteria (11, 22). Biodegradation is a significant tool for the removal of these contaminants from environments, but their low bioavailability, especially for high-molecular-weight PAHs, has often been observed in the environment and bioremediation systems (2, 22). Due to their extremely hydrophobic nature, PAHs partition readily into solid and liquid organic phases and exist in aqueous phase only at limited concentrations. This makes uptake of PAHs by bacterial cells difficult. In bacterial cultures where only the compounds dissolved in aqueous solution are utilized, mass transfer or the rate of desorption controls the rates of degradation and culture growth (2).

Nevertheless, several studies have reported that degradation kinetics for the PAHs vary among different bacteria and that some bacteria apparently show rapid degradation of such PAHs with concomitant growth (16, 18, 37). Thus, some bacteria seem to have adapted to the low availability of PAHs. Mechanisms of the adaptation include the direct contact with solid-phase PAHs (4, 13, 38, 41) and biosurfactant excretion to facilitate desorption (15). Wick et al. (40, 41) have reported that the suspended cells of Mycobacterium sp. strain LB501T do not produce biosurfactant but have a strong ability to degrade low concentrations of aqueous-phase anthracene. The specific affinity (calculated as maximum degradation rate [V_max]/Michaelis-Menten half-saturation constant [K_m]) of LB501T cells for aqueous anthracene was found to be higher than the specific affinities of other cultures reported elsewhere (41). A diverse range of K_m values for PAH degradation have been obtained with pure cultures (1, 12, 18, 27, 36) and mixed cultures (19). Wick et al. have proposed the presence of a high-affinity uptake system in LB501T (41), which would account for the facile degradation of aqueous-phase PAHs occurring at extremely low concentrations in the environment. To explain such differences in the specific affinities or K_m values between species of bacteria, it seems reasonable to consider the roles of cell surface binding and membrane transport for aqueous PAHs as well as the affinity of intracellular enzymes responsible for PAH metabolism (10).

Only limited research has been carried out on the cellular binding and transport of PAHs in aqueous phase by bacteria. Bateman et al. (5) conducted uptake experiments with Pseudomonas putida PpG1064 by filtration of cells from naphthalene solutions and flow dialysis. Naphthalene was immediately sorbed into the cells and subjected to the intracellular metabolism. This uptake process did not show substrate saturation kinetics and was not susceptible to inhibitors such as cyanide and carbonyl cyanide m-chlorophenylhydrazone (CCCP), consistent with the lack of an active transport system in PpG1064 cells. Bugg et al. (9) demonstrated that Pseudomonas fluorescens LP6a transports phenanthrene, fluoranthene, and anthracene out of the cell by an active efflux mechanism. On the other hand, the influx depended upon passive diffusion that yielded a linear correlation between the octanol-water partition coefficients and LP6a cell-water partition coefficients for the tested PAHs (9). The results of these studies (5, 9) were consistent with a general view that the interior of the cytoplasmic membrane acts as a reservoir of hydrophobic compounds with high octanol-water partition coefficients (35). In contrast, incorporation of naphthalene by a specific, energy-dependent transport system was proposed in P. fluorescens Uper-1, based on reduction of uptake by inhibitors and the naphthalene analogue -naphthol (39). The rates of naphthalene uptake were assessed mainly by monitoring substrate depletion in the supernatant of cell suspensions over 1 or 2 h. The Uper-1 cells degraded naphthalene extensively during incubation. Under these experimental conditions, the observed uptake may reflect metabolism and cell growth in addition to membrane transport. Thus, the conclusive evidence for the mechanism of bacterial PAH uptake has been confined to influx by passive diffusion. Given the diversity of PAH-utilizing bacteria and their different affinities for PAHs, however, the transport mechanism(s) described for a limited number of Pseudomonas strains may not be general.

Fast-growing Mycobacterium species, which belong to nocardioform actinomycetes, have often been isolated from contaminated soils and sediments by using high-molecular-weight PAHs as a carbon source (22). Because of their high ability to mineralize such PAHs, mycobacteria seem to play a role in the removal of PAHs from the environment. In this study, we examined the mechanism of uptake of aqueous-phase phenanthrene by Mycobacterium sp. strain RJGII-135, capable of degrading both low- and high-molecular-weight PAHs (17, 27, 33). The cell suspensions were prepared from cultures grown on either phenanthrene or acetate. The uptake experiments were conducted by incubation of suspended cells with [9-¹⁴C]phenanthrene over several minutes. Phenanthrene was added at initial concentrations below the aqueous solubility limit. The hydrocarbon-exposed cells were separated by filtration, and the cellular ¹⁴C accumulation was monitored and kinetically characterized. Concurrent metabolism during uptake was examined to elucidate the relative contributions of membrane transport and metabolism on the uptake of phenanthrene by Mycobacterium sp. strain RJGII-135.

	MATERIALS AND METHODS

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Chemicals.
[9-¹⁴C]phenanthrene (99% pure; 55 mCi mmol^-1) was obtained from American Radiolabeled Chemicals Inc. (St. Louis, Mo.). Nonlabeled phenanthrene (99% pure), naphthalene (99%), fluoranthene (97%), anthracene (98%), and pyrene (98%) were obtained from Wako Pure Chemical Industries (Osaka, Japan). These labeled and nonlabeled PAHs were dissolved in 99.5% ethanol for preparation of stock solutions. Another source of phenanthrene (95% pure; Wako Pure Chemical Industries) was used only for bacterial cultivation, not uptake studies. A mixture of phenanthrene cis-3,4- and cis-1,2-dihydrodiol isomers was produced in cultures of a transposon mutant (strain 11) of P. fluorescens LP6a, as previously described (14) and was isolated by thin-layer liquid chromatography (TLC) (34) using silica gel 60 F₂₅₄ (Merck). The phenanthrene dihydrodiols were used as one representative of bacterial PAH metabolites. Potassium cyanide (Wako Pure Chemical Industries) and CCCP (Sigma-Aldrich Co.) were used as inhibitors of transport activity.

Organism, culture conditions, and preparation of cell suspension.
Mycobacterium sp. strain RJGII-135 (17) was a generous gift from R. J. Grosser (U.S. Environmental Protection Agency, Cincinnati, Ohio) and maintained on Difco plate count agar at 8°C. MS medium (38) was modified and used as a basal medium: it contained (per liter) 0.8 g of KH₂PO₄, 1.2 g of K₂HPO₄, 0.5 g of NH₄Cl, 1.0 g of Na₂SO₄, 1.0 g of KNO₃, 0.2 g of MgSO₄ · 7H₂O, 4 mg of FeSO₄ · 7H₂O, and 1 ml of trace element solution (38), pH 7.0. To prepare complete medium, either sodium acetate (2 mmol) or solid phenanthrene (40 mg) was added to 100 ml of the liquid medium before autoclaving. Inoculum was grown on acetate for 4 days, and a portion (3 ml) was transferred into fresh medium containing solid phenanthrene or acetate, followed by incubation for 8 or 4 days, respectively. All incubations were conducted on a rotary shaker at 30°C. Both cultures were filtered through glass wool to remove solid phenanthrene and/or clumped cells. The optical densities at 600 nm (OD₆₀₀) of the filtrates containing suspended cells were approximately 0.15 and 0.5 when grown on phenanthrene and acetate, respectively. Cells were collected by centrifugation at 4,600 x g for 20 min and washed once with 0.1 M potassium phosphate buffer (pH 7.0) before the cells were resuspended at prescribed cell densities in the same buffer.

Phenanthrene degradation assay.
The assay for degradation of phenanthrene started with the addition of 0.2 ml of a cell suspension (OD₆₀₀ of 2.0) to glass test tubes containing a solution of nonlabeled phenanthrene dissolved at 5 µM in 2.0 ml of phosphate buffer (0.1 M, pH 7.0). Duplicate sets of incubations were conducted at room temperature with gentle shaking. Parallel cell-free controls were used for evaluation of abiotic loss of phenanthrene during the incubation and subsequent extraction. At timed intervals, 2.0 ml of n-hexane was added to the tubes capped with plastic closures having Teflon liners, and the contents were mixed by vortex for 1 min. Concentration of phenanthrene in the hexane extracts was monitored with a Shimadzu UV-1600 spectrophotometer at 252 nm (3). The hexane solution containing 5 µM phenanthrene gave an A₂₅₂ of 0.32. The UV absorption spectrum at 220 to 400 nm was also monitored to ensure no interference by phenanthrene metabolites of the absorbance readings at 252 nm.

Uptake experiments.
Uptake of phenanthrene by the RJGII-135 cells was assayed by the filtration method of Bateman et al. (5) but using Whatman GF/F glass fiber filters (pore size, 0.7 µm). Phenanthrene concentrations in assay mixtures were below the aqueous solubility limit (6.2 µM) (42). For uptake experiments, 20 µl of an ethanolic solution of [¹⁴C]phenanthrene (plus nonlabeled phenanthrene) was added to glass test tubes containing 2.0 ml of phosphate buffer (0.1 M, pH 7.0). The tubes were incubated at 30°C for up to 40 min to completely dissolve phenanthrene in phosphate buffer. During the incubations, no significant loss of radioactivity due to volatilization of phenanthrene was observed. The uptake experiment started when 200 µl of a cell suspension was added at an OD₆₀₀ of 0.01 or 0.1 to 0.2 (see below) to the test tubes at room temperature. At 15- or 30-s intervals over several minutes, 1.0 ml of sample was taken from each of the test tubes and applied to a GF/F filter under vacuum. The filters plus cells were washed once using 5 ml of phosphate buffer under vacuum for 30 s before being transferred into 10 ml of Scintisol EX-H (Dojin-do Laboratories, Kumamoto, Japan). The radioactivity was determined with an Aloka LSC-3100 liquid scintillation counter. The amount of phenanthrene adsorbed onto GF/F filter was determined by filtration of cell-free control assay mixtures. The ¹⁴C adsorbed onto the filter usually accounted for <10% of the counts compared to when cell suspensions were loaded, so that this value was routinely subtracted from test filters to determine the cellular ¹⁴C levels.

In some experiments, a stock solution of [¹⁴C]phenanthrene was supplemented with nonlabeled anthracene, fluoranthene, or pyrene as well as nonlabeled phenanthrene. The concentration of these second PAHs in assay mixtures was 0.3 µM, corresponding to 76, 23, and 50% of the aqueous solubilities of anthracene, fluoranthene, and pyrene, respectively (42). Naphthalene at concentrations of 0.3 and 3.0 µM was also used as a second PAH, but it was added to assay mixtures just before the cell suspension was added, to reduce potential volatility losses.

In uptake experiments, care was taken with the cell density in assay mixtures to minimize the effect of substrate depletion during incubation. Phenanthrene-grown cells were added at an OD₆₀₀ of 0.01 (2.4 µg of cell [dry weight] per ml), whereas acetate-grown cells were added at an OD₆₀₀ of 0.1 to 0.2 (32 to 64 µg of cell per ml). At these cell densities, depletion of aqueous-phase phenanthrene during the incubations was less than 15% of the initial concentrations.

Kinetic analysis.
The uptake of [¹⁴C]phenanthrene added at concentrations of 0.03, 0.06, 0.11, 0.21, 0.28, and 0.51 µM was measured at 15-s intervals over at least 45 s. After confirming that the cumulative uptake proceeded linearly, an initial uptake rate was calculated by extrapolation to time zero. The apparent affinity constant (K_t) and the maximum velocity (V_max) were estimated by nonlinear regression analysis, based on the fit of the data to the Michaelis-Menten equation. The calculation was carried out with a Prism 3.0 software package (GraphPad Software Inc., San Diego, Calif.).

To examine whether phenanthrene is specifically bound to the RJGII-135 cells, the amounts of bound phenanthrene were estimated and plotted versus the initial aqueous concentrations. The data points were fitted to models for specific binding, nonspecific binding, and their combined mode. Specific binding of substrate is a saturable process and is generally given by the following equation: b = B_max · [S]/(K_d + [S]), where b is the amount of specific binding, B_max is the maximum amount of specific binding, K_d is the equilibrium dissociation constant (substrate concentration yielding 1/2 B_max), and [S] is the initial substrate concentration. Since nonspecific binding of substrate (referring to linear partitioning) is directly proportional to [S], the combined mode of specific and nonspecific binding (b') is expressed as follows:

(1)

The kinetic parameters B_max, K_d, and N (a slope for nonspecific binding) were estimated by nonlinear regression analysis using the Prism 3.0 software package.

Analysis of concurrent metabolism.
For identification of the radiolabeled compounds in cells, the uptake experiment was conducted with a 10-fold volume of assay mixtures in 300-ml conical flasks. The cell suspension (2 ml) was added to 20 ml of phosphate buffer containing [¹⁴C]phenanthrene at a prescribed concentration. Samples (10 ml) were taken at 45 or 60 s and filtered through Whatman GF/F glass fiber filters, and the filters were washed once with 5 ml of phosphate buffer. The total uptake of phenanthrene was determined by counting the radioactivity associated with the filters. In parallel experiments, the washed filters were immediately immersed in 2 ml of ethyl acetate and left overnight at room temperature. The filters were then further extracted three times in 2 ml of ethyl acetate. The extracts were pooled, and 0.5 ml of deionized water was added to remove debris liberated from the glass filter and cells. The water phase was combined with the filter, and these were transferred together into scintillation vials for determination of nonextractable (cell-bound) ¹⁴C. The ethyl acetate phase was evaporated under a gentle stream of N₂ and redissolved in a small volume of acetone. The extracts in acetone were separated into two fractions of labeled compounds, phenanthrene and lipophilic metabolites, by TLC using silica gel 60 F₂₅₄. Benzene-hexane (1:1, vol/vol) was used as the developing solvent. In this solvent system, phenanthrene migrates toward the solvent front, and any metabolites remain around the origin on the plate (34). For detection of phenanthrene dihydrodiol, the extracts in acetone were also analyzed by TLC with the solvent benzene-ethanol (9:1, vol/vol) (34). Nonlabeled phenanthrene and cis-phenanthrene dihydrodiols were added to the radiolabel extracts and run simultaneously on TLC plates. The bands on the plate were visualized under UV light (254 nm), and radioactivity in the bands was counted in 10 ml of liquid scintillation fluid.

In separate experiments, the filters with cells were immersed in 2 ml of benzene-methanol-20% methanolic tetramethylammonium hydroxide (2:1:1, vol/vol/vol) and left overnight at 37°C, in order to disrupt the structure of mycobacterial cell envelope by alkaline methanolysis (28). The supernatant was collected, and the residue on the filter was washed three times in 2 ml of ethyl acetate. Deionized water (0.5 ml) was added to the combined supernatants to separate out hydrophilic compounds. The organic solvent phase was evaporated and the extracts were analyzed by TLC, as described above.

	RESULTS

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Degradation of phenanthrene by suspended cells.
Cell suspensions of RJGII-135 obtained from cultures grown on acetate and phenanthrene were incubated with 5 µM phenanthrene, and degradation of phenanthrene was monitored spectrophotometrically at 252 nm (Fig. 1). The hexane extracts from all the incubation mixtures showed a UV absorption spectrum equivalent to that of authentic phenanthrene in hexane (_max = 251, 274, 281, and 292 nm), indicating that the A₂₅₂ values represent only the concentrations of remaining phenanthrene. Figure 1 clearly shows that phenanthrene-grown cells are induced for phenanthrene metabolism, whereas acetate-grown cells are not.

View larger version (15K): [in this window] [in a new window]   FIG. 1. Degradation of phenanthrene by suspended cells of Mycobacterium sp. strain RJGII-135 grown on either phenanthrene or acetate. Concentrations of residual phenanthrene in cultures were determined spectrophotometrically. Data points are means of duplicate measurements, and the error bars (where visible) represent 1 SD.

View larger version (22K): [in this window] [in a new window]   FIG. 2. Uptake of [14C]phenanthrene by cells of Mycobacterium sp. strain RJGII-135 grown on acetate (A) or phenanthrene (B). Cells were incubated with 0.06 µM radiolabeled phenanthrene alone and with 0.06 µM radiolabeled phenanthrene plus 0.15, 0.5, or 5.5 µM nonlabeled phenanthrene. The error bars (where visible) represent 1 SD, based on three independent experiments.

View larger version (19K): [in this window] [in a new window]   FIG. 3. Relationship between phenanthrene concentrations in cells of Mycobacterium sp. strain RJGII-135 and initial phenanthrene concentrations in aqueous phase. For phenanthrene-grown cells, the intracellular concentrations at time zero in Fig. 2 were estimated (see the text). For acetate-grown cells, the cellular steady-state concentrations were used. The solid line shows the nonlinear regression of the data for phenanthrene-grown cells to equation 1 with kinetic parameters Kd = 41 ± 21 nM, Bmax = 1.1 ± 0.1 nmol mg of cell-1, and N = 1.50 ± 0.04. The dashed line shows the linear regression of the data for the acetate-grown cells, with a slope for nonspecific binding of N = 1.65 ± 0.04. The error bars (where visible) represent 1 SD.

Kinetics of phenanthrene uptake.
In Fig. 2B, the slope of linear lines drawn for ¹⁴C uptake between 15 and 60 s was regarded as the initial rate of phenanthrene uptake. Initial uptake rates were repeatedly measured with different phenanthrene concentrations, ranging from 0.03 to 0.51 µM. The rates followed Michaelis-Menten kinetics (24 data points; r² > 0.99) with an apparent K_t of 26 ± 3 nM and a V_max of 4.2 ± 0.1 nmol mg of cell^-1 min^-1 (means ± SD).

It should be noted that the linear slopes between 15 and 60 s (Fig. 2B) did not pass through a cellular phenanthrene concentration of zero when extrapolated to time zero. As shown for acetate-grown cells (Fig. 2A), such an immediate uptake achieved by 15 s would involve a partitioning process. However, the ¹⁴C level estimated by extrapolation to time zero (0.84 ± 0.05 nmol mg^-1) decreased to 0.29 ± 0.03, 0.19 ± 0.01, and 0.12 ± 0.01 nmol mg^-1 with the addition of nonlabeled phenanthrene at 0.15, 0.5, and 5.5 µM, respectively (Fig. 2B). Consequently, the immediate uptake also appeared to involve saturation kinetics. The estimated concentrations in the cells at time zero from repeated uptake experiments with different substrate concentrations are plotted in Fig. 3 versus the initial aqueous concentrations of phenanthrene. The total phenanthrene concentrations were calculated by multiplying the extrapolated ¹⁴C concentrations at time zero (from Fig. 2 and other data sets) by the ratio of total phenanthrene to labeled phenanthrene. A model that represents a combined mode of specific and nonspecific interactions between one ligand and receptor, as indicated in equation 1, was consistent with the data. The kinetic parameters were as follows, with a goodness of fit (30 data points; r² > 0.99): the apparent K_d and B_max were 41 ± 21 nM and 1.1 ± 0.1 nmol mg of cell^-1, respectively (means ± SD). The slope for nonspecific binding (N) was 1.50 ± 0.04. Figure 3 also shows a linear regression of the data obtained with acetate-grown cells; the plots represent the steady-state concentrations in cells. The N value was 1.65 ± 0.04 (15 data points; r² > 0.99).

Concurrent metabolism during phenanthrene uptake.
To study the concurrent metabolism of phenanthrene during uptake, the cellular ¹⁴C-labeled compounds were extracted with ethyl acetate and analyzed by TLC (Table 1). The validity of this method was confirmed with acetate-grown cells that were not induced for phenanthrene metabolism (Fig. 1). The uninduced cells incubated with 0.31 µM [¹⁴C]phenanthrene incorporated 0.38 nmol of ¹⁴C mg of cell^-1, of which nonextractable (cell mass-incorporated) compounds and lipophilic metabolites accounted only for <0.1 and 2%, respectively. This result clearly indicates that almost all the accumulated phenanthrene remained without being metabolized, consistent with the result of the degradation assay (Fig. 1). Due to its volatilization during evaporation of organic solvent, the recovery of phenanthrene after TLC analysis was somewhat lower (72%) than that expected from a material balance (98%) (Table 1).

Effect of inhibitors on phenanthrene uptake.
To study the energy-dependent uptake of phenanthrene, the effects of cyanide and CCCP (an uncoupler) on the cellular accumulation of ¹⁴C were examined. Figure 4 shows one representative result of the inhibition assays with phenanthrene-grown cells. Cumulative phenanthrene uptake was completely inhibited by addition of cyanide (10 mM) at the beginning of incubation. The immediate uptake process achieved within the first 15 s was not susceptible to the inhibitor, because the ¹⁴C concentration in unexposed cells at time zero (y intercept, 1.3 nmol mg of cell^-1) approximates the steady-state concentration observed for the cells initially exposed to cyanide (1.5 nmol mg^-1). CCCP (0.1 mM) showed equivalent effects, although the cumulative uptake proceeded slightly after the addition at the beginning of incubation. Addition of the two inhibitors at 45 s also strongly prevented the cumulative uptake but did not result in a further decrease in the cellular ¹⁴C. This result indicates the lack of exodus of the accumulated ¹⁴C. Neither cyanide nor CCCP affected phenanthrene uptake by acetate-grown cells (data not shown).

View larger version (16K): [in this window] [in a new window]   FIG. 4. Effect of inhibitors on uptake of phenanthrene by cells of Mycobacterium sp. strain RJGII-135 grown on phenanthrene. Cyanide (10 mM) or CCCP (0.1 mM) was added at time zero or at 45 s during incubation. The times when inhibitors were added are indicated with arrows.

	DISCUSSION

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However, the induced cells showed a cumulative uptake curve over a period of a few minutes when incubated with [¹⁴C]phenanthrene. Since phenanthrene enters immediately into uninduced cells by passive diffusion, the continued cumulative uptake in induced cells must also involve a constant role of partitioning. Kinetic analysis revealed that linear partitioning is not the only mechanism that explains the immediate uptake in induced cells and suggests that phenanthrene is specifically bound to induced cells, based on the saturation kinetics (apparent K_d = 41 ± 21 nM). The contribution of nonspecific binding, referred to as linear partitioning, had an N of 1.50 ± 0.04. The fair agreement between the two N values for induced and uninduced cells indicates that phenanthrene enters equivalently into both types of cells by passive diffusion. This suggests that induced cells accumulate additional phenanthrene by the phenomenon of specific binding. The kinetics described here for induced cells may be a conservative estimate of [¹⁴C]phenanthrene uptake, since the induced cells used in uptake experiments likely contained residual cell-associated phenanthrene from their growth on nonlabeled phenanthrene; due to its competitive effect, this would reduce the apparent extent of uptake for labeled phenanthrene.

The data presented here are also consistent with the presence of a saturable, energy-dependent system in the cumulative uptake observed in induced cells. The uptake rates showed saturation kinetics (apparent K_t = 26 ± 3 nM) and were largely reduced by the inhibitors. This K_t value is much smaller than that reported for the naphthalene uptake by P. fluorescens Uper-1 (11 µM) (39), suggesting the presence of a high-affinity uptake system in RJGII-135. Besides nonlabeled phenanthrene, the cumulative uptake of [¹⁴C]phenanthrene responded to nonlabeled naphthalene, anthracene, fluoranthene, and pyrene to different extents. Since three- and four-ring PAHs inhibited the ¹⁴C uptake more than two-ring PAH, the phenanthrene uptake system may have selectivity for larger PAHs.

The phenanthrene-grown RJGII-135 cells were induced for the phenanthrene metabolism. In such cells, the concurrent intracellular metabolism dissipates the equilibrium partitioning of a hydrophobic compound between cytoplasmic membrane and cytoplasm, so the metabolism rather than membrane transport might be a rate-determining step in the substrate influx. Also, since cyanide and CCCP may be potent inhibitors for the PAH-metabolic enzymes, they might inhibit the phenanthrene uptake by directly affecting the metabolic process. However, these assumptions were inconsistent with our data (Table 1). Analysis of the concurrent metabolism revealed that neither phenanthrene nor phenanthrene dihydrodiol(s) accumulated in cells that were incubated with 0.18 µM [¹⁴C]phenanthrene. This result indicates that the intracellular metabolism is fast enough to maintain a low intracellular concentration of free phenanthrene. Also, the occurrence of rapid metabolism is partly explained by the fact that no cellular ¹⁴C was excreted after addition of the inhibitors (Fig. 4). If phenanthrene was present in the cells without being metabolized, the inhibitor addition would result in the efflux of cellular [¹⁴C]phenanthrene that accumulated beyond the level due to passive diffusion. Thus, the concurrent metabolism is not saturated at the substrate concentrations below 0.18 µM, where the uptake rate reaches approximately 90% of V_max given its K_t value. This observation shows that the concurrent metabolism is not a rate-determining step for the cumulative uptake process in induced cells. The result suggests that the cumulative uptake reflects the membrane transport rather than intracellular metabolism, although the possibility of contribution of metabolism cannot be ruled out. While PAH transport systems in Pseudomonas spp. have been reported previously (5, 9, 39), this study presents the first indications for the presence of a saturable, energy-dependent system for PAH transport in mycobacteria as well as the first possible involvement of specific binding of PAH to bacterial cells. It is not clear whether these two processes act in concert for the uptake of phenanthrene by RJGII-135, although these characteristics coexisted in the induced cells but not in uninduced cells.

Our kinetic data suggest that both passive diffusion and saturable transport system(s) contribute to the utilization of phenanthrene by RJGII-135. The culture medium, as well as other media generally used for liquid cultures of PAH-degrading organisms, was supplemented with solid phenanthrene at a concentration (0.4 g liter^-1 in this study) far greater than the aqueous solubility limit. In such cases, mass transfer of phenanthrene to aqueous solution readily occurs until the maximum solubility. The results in Fig. 3 imply that at around the solubility limit, the mechanism of nonspecific binding dominates the immediate uptake in induced cells. The role of passive diffusion undoubtedly would be significant in the cultures of RJGII-135 with solid phenanthrene, as reported for two Pseudomonas strains (5, 9). Extensive research has demonstrated that heterologous expression of genes encoding PAH-metabolizing enzymes of various bacteria (e.g., species of Pseudomonas [26], Nocardioides [32], and Mycobacterium [24]) provides the host organisms such as Escherichia coli with the capability to degrade naphthalene, phenanthrene, or pyrene added in excess solid. Consequently, there is no requirement of an additional transport system for degradation of such PAHs by the host cells. In contrast, the results in Fig. 3 also imply that the contribution of specific (saturable) binding to the immediate uptake increases gradually with a decrease in the aqueous phenanthrene concentration. At a concentration of 0.06 µM, for example, the amount of phenanthrene specifically bound can be predicted to account for 88% of the total immediate uptake. Taken together with the K_t value for the subsequent cumulative uptake, the two saturable processes (i.e., binding and transport) in induced cells apparently respond to nanomolar levels of aqueous-phase phenanthrene. In this regard, their function(s) may be involved particularly in facilitated degradation of aqueous-phase phenanthrene occurring only at limited concentrations in environments, where hydrophobic compounds are partitioned into organic phases and the mass transfer or desorption proceeds only at limited rates (8, 16, 31). Recent studies have proposed the presence of facilitated or active transport systems for uptake of hydrophobic compounds: toluene (21) and m-xylene (23), alkanes such as n-hexadecane (6, 25, 30), and dibenzothiophene (29). Moreover, some long-chain fatty acids such as oleic acid are also known to be bound to bacterial cells and transported actively (7, 20). The roles of membrane transport and also specific binding in microbial degradation of PAHs with a limited bioavailability have been considered very little as yet, but the present study suggests that these mechanisms may contribute.

	ACKNOWLEDGMENTS

 
We thank R. J. Grosser for providing Mycobacterium sp. strain RJGII-135 and T. Bugg for assistance in part of the experimental work.

This work was supported by Grant-in-Aid for Young Scientist (B) (14780445) from the Japan Society for the Promotion of Science.

	FOOTNOTES

 
* Corresponding author. Mailing address: Institute for Environmental Sciences, University of Shizuoka, 52-1 Yada, Shizuoka 422-8526, Japan. Phone: 8154-264-5649. Fax: 8154-264-5594. E-mail: miyatan{at}smail.u-shizuoka-ken.ac.jp.

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