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Previous Article | Next Article 
Appl Environ Microbiol, June 1998, p. 2200-2206, Vol. 64, No. 6
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Characterization of Metabolites in the
Biotransformation of 2,4,6-Trinitrotoluene with Anaerobic Sludge: Role
of Triaminotoluene
Jalal
Hawari,1,*
A.
Halasz,1
L.
Paquet,1
E.
Zhou,1
B.
Spencer,1
G.
Ampleman,2 and
S.
Thiboutot2
Biotechnology Research Institute, National
Research Council, Montreal, PQ H4P 2R2,1 and
Defence Research Establishment Valcartier, National Defence,
Val Bélair, PQ G3J 1X5,2 Canada
Received 6 March 1998/Accepted 1 April 1998
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ABSTRACT |
The present study describes the biotransformation of
2,4,6-trinitrotoluene (TNT) (220 µM) by using anaerobic sludge (10%, vol/vol) supplemented with molasses (3.3 g/liter). Despite the disappearance of TNT in less than 15 h, roughly 0.1% of TNT was attributed to mineralization (14CO2). A
combination of solid-phase microextraction-gas chromatography-mass spectrometry and liquid chromatography-mass spectrometry identified two
distinctive cycles in the degradation of TNT. One cycle was responsible
for the stepwise reduction of TNT to eventually produce triaminotoluene
(TAT) in relatively high yield (160 µM). The other cycle involved TAT
and was responsible for the production of azo derivatives, e.g.,
2,2',4,4'-tetraamino-6,6'-azotoluene (2,2',4,4'-TA-6,6'-azoT) and
2,2',6,6'-tetraamino-4,4'-azotoluene (2,2',6,6'-TA-4,4'-azoT) at pH
7.2. These azo compounds were also detected when TAT was treated with
the anaerobic sludge but not with an autoclaved sludge, suggesting the
biotic nature of their formation. When the anaerobic conditions in the
TAT-containing culture medium were removed by aeration and/or
acidification (pH 3), the corresponding phenolic compounds, e.g.,
hydroxy-diaminotoluenes and dihydroxy-aminotoluenes, were observed at
room temperature. Trihydroxytoluene was detected only after heating TAT
in water at 100°C. When 13CH3-labeled TNT was
used as the N source in the above microcosms, we were unable to detect
13C-labeled p-cresol or
[13CH3]toluene, indicating the absence of
denitration or deamination in the biodegradation process. The formation
and disappearance of TAT were not accompanied by mineralization,
suggesting that TAT acted as a dead-end metabolite.
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INTRODUCTION |
Presently, contamination of soils by
highly energetic chemicals such as 2,4,6-trinitrotoluene (TNT),
generated as waste from the munitions and defense industries, is a
significant worldwide environmental problem. These compounds are
mutagenic and toxic and have the tendency to persist in the environment
(27, 30, 33). It is estimated that TNT alone is produced in
amounts close to 2 million pounds a year (11) and threatens
human life through the food chain (33). There have been
several attempts to degrade TNT, most preferably by biological means,
but thus far the compound has been found to undergo biotransformation
rather than mineralization (3, 5, 7, 9, 19, 28, 29). In
almost all studied cases the initial products from TNT degradation
are the reduced amino derivatives, such as
4-NH2-2,6-di-NO2-toluene (4-ADNT), 2-NH2-4,6-di-NO2-toluene (2-ADNT),
2,4-di-NH2-6-NO2-toluene (2,4-DANT), and
2,6-di-NH2-4-NO2-toluene (2,6-DANT)
(6, 13). Under strictly anaerobic conditions these amine
derivatives transform into 2,4,6-triaminotoluene (TAT) (8, 9, 17,
20, 25). Most literature reports that the exact role of TAT
during TNT biodegradation is not yet clear and warrants further
investigation (14, 17, 24).
One objective of the present study is to investigate all possible steps
involved in the biodegradation of TNT leading to the formation of TAT
under anaerobic conditions and to investigate the fate of TAT and its
implication on the mineralization process. This requires extensive
product analysis of all relevant intermediates, including short-lived
ones, directly in the culture medium and before they undergo further
transformations. The frequently applied traditional liquid-liquid
extraction followed by chromatography cleanup and analysis is not
always suitable for the detection of such transient metabolites.
Missing a metabolite in a biotransformation process may also lead to
the loss of a valuable piece of information on the metabolic pathway.
In the present study a combination of two powerful analytical
techniques, namely solid-phase microextraction (SPME)-gas
chromatography-mass spectrometry (SPME-GC-MS) and liquid
chromatography-mass spectrometry (LC-MS), will be applied to analyze
intermediates formed during TNT biodegradation with anaerobic sludge.
SPME uses a polymer-coated fiber for the adsorption of organic
compounds from the aqueous-phase sample followed by direct thermal
desorption of the analytes in the injection port of a GC. The technique
is known for its speed and sensitivity, which enables detection in the
micrograms/liter range (2, 22, 22a, 23). On the other hand,
LC-MS allows for the direct injection of the aqueous culture medium
into the MS detector for metabolite determination. The applicability of the two techniques to determine key metabolites in the biodegradation of TNT with anaerobic sludge will be evaluated. A time study of the
appearance and disappearance of the detected TNT metabolites will be
used to elucidate the biotransformation pathway of TNT and the reasons
behind its poor mineralization despite its unique reactivity.
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MATERIALS AND METHODS |
Reagents and solutions.
TNT was obtained from Defence
Research Establishment Valcartier (Quebec, Canada), and 2-ADNT, 4-ADNT,
2,4-DANT, and 2,6-DANT were purchased from AccuStandard Inc. (New
Haven, Conn.). Methylphloroglucinol (2,4,6-trihydroxytoluene) was
purchased from Spectrum Chemicals (New Brunswick, N.J.), and a
technical grade (about 95% pure) of 2,4,6-triaminotoluene · hydrochloride (TAT · 3HCl) was obtained from Chemservice
(Westchester, Pa.). Uniformly labeled [U-14C]TNT and
[13CH3]TNT were synthesized as described by
Ampleman et al. (1). The sludge was obtained from a food
factory located in the city of Cornwall, Ontario, Canada. BBL dry
anaerobic indicator (VWR; Canlab, Ontario, Canada) was used to detect
air leaks and to insure anaerobic conditions.
Microcosm description for the degradation of TNT.
In a
typical setup, a serum bottle (100 ml) was charged with deionized water
(34 ml), anaerobic sludge (5 ml), a mineral salt medium (1 ml) composed
of 2.0 g of KH2PO4 per liter, 3.0 g
of K2HPO4 per liter, 30 g of
NaHCO3 per liter, 35 g of KHCO3 per liter,
and 30 g of Na2SO4 per liter. Molasses
(3.3 g/liter) served as a carbon source and TNT (50 mg/liter) as the N
source for the degrading microorganisms. Some serum bottles
(microcosms) were supplemented with a uniformly labeled
[U-14C]TNT (100,000 dpm) and then fitted with a small
test tube containing 1.0 ml of 0.5 M KOH to trap liberated carbon
dioxide (14CO2) (10). The headspace
in each microcosm was flushed with nitrogen gas to maintain anaerobic
conditions and then sealed with butyl rubber septa and aluminum crimp
seals to prevent the loss of CO2 and other volatile
metabolites. The absence of air in these microcosms was monitored by
using special indicators called BBL dry anaerobic indicators (VWR;
Canlab). Two control microcosms were prepared: one contained the sludge
without TNT and the second contained TNT and an autoclaved sludge. Each
microcosm was wrapped with aluminum foil to protect the mixture against photolysis. Microcosms with [U-14C]TNT were routinely
sampled (daily or every 2 days) for the determination of
14CO2 in the KOH trap by using a Packard
Tri-Carb 4530 liquid scintillation counter (Model 2100 TR; Packard
Instrument Company, Meriden, Conn.). In some experiments,
13CH3-labeled TNT was used as the N source to
confirm the presence or absence of certain TNT biotransformed products
such as p-cresol and toluene. Microcosms that did not
receive 14C-labeled TNT were reserved for SPME-GC-MS,
high-pressure liquid chromatography (HPLC)-UV and LC-MS analysis of
residual TNT and its metabolites (see below). Each microcosm was
carried out in triplicate.
SPME-GC-MS monitoring of TNT biotransformation.
Briefly,
fused silica capillary fibers (1 cm) coated with either 85 µm of
polyacrylate or 100 µm of polymethylsiloxane fitted to an autosampler
assembly were used (Supelco, Bellfonte, Pa.). The fiber was conditioned
by placing it inside the injection port of a GC-MS at 300°C (ca.
2 h). Subsequently, aliquots (1 ml) from the TNT culture medium
were spiked with the recovery standard 4-ethyl-dibenzylthiopene
(4-Et-DBT; 250 ppb) and filtered through a Millex-HV
0.45-µm-pore-size filter to remove suspended material including
biomass. A 20-min adsorption time from the aqueous solution followed by
a 10-min desorption inside the GC injector were found appropriate for
reproducible analyses. A GC (Varian 3400) fitted with a DB-5 column (30 by 0.25 by 0.25 µm thick) by using He as a carrier gas was used. Oven
initial temperature was 90°C (2 min), increased to 165°C
(10°C/min), and then incremented to 250°C (5°C/min). Mass
analysis was carried out with a Varian Saturn II system in the El mode
(70 eV) by using a mass range of 15 to 300 amu, a background mass of 14 amu, and a mass scan rate equal to 0.5 s/scan. A time study to monitor
the formation and disappearance of metabolites was carried out at
t = 0 and at hourly intervals for the first 10 h
of the experiment, followed by 5 h of sampling events until 30 h and, finally, daily sampling until the end of the experiment.
HPLC analysis (EPA method 8330).
Aliquots (1 ml) from the
above treated culture medium were mixed with 1 ml of acetonitrile,
filtered, and analyzed by using a Waters HPLC system fitted with a
Waters pump (Waters Chromatography Division, Milford, Mass.) and
connected to a WISP auto injector (Model 710b; Millipore). Samples (50 µl) from the culture medium were injected into a Supelco
C8 column (25 cm by 4.6 mm; particle size, 5 µm) coupled
with a Temperature Control Module (model TCM; Millipore) by using a
mobile phase composed of a water-isopropanol mixture (82:18, vol/vol).
A programmable UV-VIS multiwavelength detector (Model 490; Millipore)
was used for quantification at 
254 nm. Quantification was done by
using external standards composed of known concentrations of TNT,
2-ADNT, 4-ADNT, 2,6-DANT, and 2,4-DANT. TAT was analyzed at 219 nm by
using ion pairing on a C18 column with octanesulfonic acid
as the ion-pairing agent. A time study, with the same profile described
for the SPME, was conducted for purposes of conformity and comparison.
LC-MS.
LC-MS to identify and verify TNT metabolites was
performed on a Micromass Platform II benchtop single quadrupole mass
detector fronted by a Hewlett Packard 1100 Series HPLC system. Analyte ionization was either done in the positive atmospheric pressure chemical ionization mode (APCI+) using a cone voltage of 30 V and a
source temperature of 150°C or by negative electron spray ionization
(ES
) at 30 V and 90°C. Chromatography was in an ion-pairing mode
with a C18 column (25 cm by 4.6 mm; 5-µm particles) and
octanesulfonic acid as the ion-pairing agent. The flow rate was 1 ml/min with a postcolumn split of 5:95. A cross-flow counter electrode
scheme was used to prevent salt components in the mobile phase from
entering the detector.
Analysis of nitrite and ammonium ions.
The aqueous layer was
analyzed for NO2
ions with an SP 8100 HPLC
with a 25- by 0.46-cm PRP-X 100 Hamilton column and a Waters 431 conductivity detector. Methanol (10%) buffered (pH 8.5) with a
solution of p-hydroxybenzoic acid was used as mobile phase
at a flow rate of 2 ml/min. Analytical-grade sodium nitrite was used as
the standard. Ammonium ions were analyzed by using the same system but
with a PRP-X 200 Hamilton column with 30% MeOH in 6 mM nitric acid
solution at a flow rate of 0.75 ml/min.
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RESULTS AND DISCUSSION |
Metabolite identification.
The SPME-GC-MS chromatogram shown
in Fig. 1 summarizes TNT
biotransformation after 12 h of incubation with the anaerobic
sludge. All intermediates in Fig. 1 were identified by comparison with their corresponding standards using retention times (rt), molecular mass ions (M/z), and base peak mass ions (bp). The parameters (rt
[minutes], M/z [amu], and bp [amu]) for the four detected intermediates were as follows: for 2-ADNT, 17.70, 197, and 180; for
4-ADNT, 16.98, 197, and 180; for 2,4-DANT, 16.66, 167, and 167; and for
2,6-DANT, 17.82, 167, and 167, respectively.
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FIG. 1.
SPME-GC-MS total ion chromatogram of TNT after 12 h of treatment with an anaerobic sludge taken from a baby food factory.
IS, internal standard.
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Another set of metabolites, with much shorter lifetimes than those
detected above, were observed after 6 to 8 h of incubation. Their
identities were confirmed by using ES at 30-V LC-MS. Two isomeric
metabolites with the same molecular ion of 213 amu were observed and
attributed as being 2-hydroxylamino-4,6-dinitrotoluene (2-HADNT)
and 4-hydroxylamino-2,6-dinitrotoluene (4-HADNT) by comparison with
reference materials. Both 2-HADNT and 4-HADNT are prerequisites for the
formation of the corresponding amine derivatives 2-ADNT and 4-ADNT,
respectively.
Due to its high polarity and solubility in water, TAT was not detected
by SPME-GC-MS, and furthermore, it eluted with the void volume in the
case of HPLC (method no. 8330). The presence of TAT was finally
confirmed by ion-pairing HPLC by using octanesulfonic acid as an
ion-pairing agent and a C18 column (Fig.
2). The triamine metabolite, TAT,
appearing after 12 h of TNT incubation, was identified by
comparison with a standard and by APCI+ and LC-MS (M+H; 138 amu) as shown in Fig. 3. TAT was detected
in very high concentrations (160 µM), accounting for 73% of the
initial concentration of TNT (220 µM). The pH inside the microcosms
under these conditions ranged from 6.5 to 7.2.
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FIG. 2.
HPLC chromatogram of the same culture medium used in
producing Fig. 1, but in this case, analysis was carried out by using a
C18 column with octanesulfonic acid as an ion-pairing
agent.
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FIG. 3.
The LC-MS spectrum of TAT obtained with a Micromass
Platform II mass detector by using APCI+ at 30 V. Injection was carried
out with an HP 1100 Series HPLC system by using a C18
column (25 cm by 4.6 mm; 5-µm particles) with octanesulfonic acid as
the ion-pairing agent.
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TAT was accumulated in the system for 6 days but gradually disappeared
and produced a new set of products including the azo derivatives
2,2',4,4'-tetraamino-6,6'-azotoluene (2,2',4,4'-TA-6,6'-azoT) and
2,2',6,6'-tetraamino-4,4'-azotoluene (2,2',6,6'-TA-4,4'-azoT). Figure
4a is the LC-MS ion chromatogram of the
anaerobic culture medium showing TAT together with its azo derivatives,
whereas Fig. 4b represents the mass chromatogram showing the molecular mass ion (M+H; 271 amu) for a detected isomeric azo isomer,
presumed to be 2,2',6,6'-TA-4,4'-azoT. When using TAT instead of TNT as
an N source (pH 7.2) for the degrading microorganisms in the sludge we
obtained the two isomeric azo derivatives with the same LC-MS molecular
mass ions (M+H; 271 amu). However, if the sludge was
autoclaved before use, no azo compounds were observed. These results
confirmed that the detected azo compounds were biotic products.
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FIG. 4.
(a) LC-MS total ion chromatogram of TAT and several of
its overlapped azo derivatives after 6 days of incubation under
anaerobic conditions. (b) A typical LC-MS spectrum of the suggested
para azo isomer of TAT as obtained by using APCI+ at 30 V. (c) A
typical LC-MS spectrum of the suggested 13C-para azo isomer
of TAT (2,2',6,6'-TA-4,4'-azoT) obtained using
13CH3-TNT as the N substrate and APCI+ at 30 V.
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Furthermore, with 13CH3-labeled TNT we obtained
LC-MS spectra whose molecular mass ions were 2 amu higher than those
obtained from the unlabeled TNT (Fig. 4c). Several other LC-MS peaks
with higher-molecular-mass ions, e.g., 537 amu identified as a TAT azo
tetramer, were also detected, suggesting that these azo compounds might
have been formed as intermediates during TAT polymerization to polyazo
compounds.
Interestingly, oxidized azo dimers are known to be recalcitrant under
aerobic conditions but with a tendency to cleave to form the
corresponding amines anaerobically (4, 16, 26). It is
possible that traces of some metal ions in the sludge might have
triggered the oxidation of TAT through an e-transfer process (16), justifying the formation of oxidized azo products
under anaerobic conditions. Earlier the microbial conversion of TAT by
sulfidegenic isolate to ammonium ion and unidentified products has been
reported to be catalyzed by Mn2+ under aerobic conditions
(25). No gas leak was suspected in the present experiments,
because the microcosms were sealed under a bed of nitrogen and
monitored with a dry anaerobic indicator. However, oxidation is an
electron transfer process that does not necessarily involve reaction
with oxygen. We speculate that an anonymous reduction in the bioprocess
might have triggered TAT oxidation to produce the azo derivatives.
No hydrolyzed phenolic products from TAT were observed while the
microcosms stayed strictly anaerobic and near neutral (pH 7.2). After
2 h of exposure to air, TAT disappeared gradually to produce two
products (Fig. 5a) that were tentatively
identified by LC-MS as the phenolic products hydroxy-diaminotoluenes
(HDAT) (M+H; 139 amu) and dihydroxy-aminotoluenes (DHAT)
(M+H; 140 amu) (Fig. 5b and c). No trihydroxytoluene (THT)
was observed under these conditions. The absence of hydrolyzed TAT
products under anaerobic conditions (pH 7.2) might indicate that TAT
biotransformation to the corresponding azo compounds was faster than
its rate of hydrolysis at this buffered pH. For example, we found that
TAT hydrolysis to THT occurred after heating the triamine in water at
100°C (32).
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FIG. 5.
(a) HPLC chromatogram of 2,4,6-TAT and its hydrolyzed
phenolic products HDAT and DHAT obtained by exposing the microcosms
treating TNT with anaerobic sludge to air at pH 2. X, unidentified
product. Analysis was carried out by using a C18 column
with octanesulfonic acid as an ion-pairing agent. (b) The mass spectrum
of TAT phenolic product HDAT as obtained by using APCI+ at 30 V, and
(c) the mass spectrum of TAT phenolic product DHAT as obtained using
positive APCI+ at 30 V.
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When air was allowed inside freshly prepared anaerobic microcosms with
TAT (40 ppm) rather than TNT as the N source, the triamine concentration diminished without producing the azo compounds. Instead,
the two phenolic products HDAT and DHAT were detected, whose rate of
formation increased under acidic conditions (pH 2 to 3). On the other
hand, when TAT (40 ppm) was treated with a buffered autoclaved sludge
(pH 7.0) under nitrogen, neither phenolic nor azo compounds were
observed for more than 2 days. In the presence of air, TAT started to
disappear without giving appreciable amounts of phenolic compounds for
more than 24 h. After acidification to pH 2 to 3, TAT disappeared
in less than 3 h, and both phenolic products HDAT and DHAT were
detected together with a trace amount of THT.
18O labeling confirmed that water rather than oxygen was
the source of the hydroxyl groups in these hydrolyzed TAT products, indicating that aeration was not directly involved in the conversion of
TAT to the phenolic derivatives. Instead, oxygen in suppressing the
anaerobic microbial activity inside the microcosm might have opened the
way for the slower TAT hydrolysis to take place at neutral conditions
(pH 7). As we mentioned earlier, TAT hydrolysis can be enhanced by
acidification (pH 2 to 3) and/or heating with water. Acidic conditions
(pH < 6) have been shown to enhance the decomposition of TAT,
although no products were identified (25). Eventually the
presence of oxygen led to the decomposition of TAT phenolic
intermediates to unidentified products, which is in line with the use
of phenols as antioxidants.
Naumova et al. (21) reported the formation of
2,4,6-trihydroxybenzene (THB), known as phloroglucinol, in a culture
medium treating TNT under anaerobic conditions. Funk et al.
(9), however, reported the observation of THT and suggested
that Naumova's metabolite was THT and not THB. They also suggested
that THT is a rearranged species of TAT and both are present in an
equilibrated fashion. Later, Lewis et al. (18) reported that
anaerobic treatment of TNT with Clostridium bifermentans
produced as end products TAT and the phenolic compounds of TAT
hydrolysis. In our case, no TAT phenolic products were detected in the
microcosms treating TNT under anaerobic conditions (pH 7.2). To say the
least, to be able to observe the disputed THT, the TAT metabolite must
be hydrolyzed either under severe acidic conditions (pH 2) or at an
elevated temperature (100°C).
No proof on the presence of either para-cresol or toluene as
metabolite was evident, since the sludge itself was found to contain
p-cresol (10 ppm) and traces of toluene. However,
preliminary data showed that when a
[13CH3]TNT was treated with the sludge
neither [13CH3]toluene nor
[p-13CH3]cresol was detected. For
example, the formation of such intermediates would necessitate the
elimination of a nitro group from TNT or an amine from its
corresponding amino intermediates, but neither ion was detected under
anaerobic conditions.
Both para-cresol (9) and toluene (3)
have been reported as metabolites during TNT biotransformation under
anaerobic conditions. In their study, Boopathy and Kupla (3)
found that when TNT is used as a sole N source for a sulfate-reducing
bacterium (Desulfovibrio sp.), it produces toluene after
transforming the substrate into TAT. The authors reported that 45 days
were needed to accumulate detectable amounts of the intermediate. In
the present study, neither denitrated nor deaminated toluenes were
detected after more than 60 days of incubation. There is a lot of
controversy surrounding the denitration of TNT. In a more recent
article, Vorbeck et al. (29) reported on the absence of TNT
reductive denitration by Rhodococcus erythropolis strain HL
PM-1, although monohydride and dihydride Meisenheimer complexes were
formed.
Reduced denitrated TNT intermediates have been reported earlier by
Duque et al. (7) by using a constructed
Pseudomonas hybrid strain and TNT as N and C sources.
Interestingly, it has been found that batches of TNT used in our study
contain traces of 2,4-dinitrotoluene (2,4-DNT) which upon reduction
could produce 2,4-DANT. The contamination of TNT with 2,4-DNT can thus
be easily misinterpreted as a denitrated or deaminated TNT metabolite.
Also, neither the o-dihydroxy nor the p-dihydroxy
toluene derivatives, both considered to be prerequisites to the
cleavage of the aromatic ring prior to mineralization (20),
were observed.
Mechanistic considerations: the role of TAT.
An SPME-GC-MS
time study for the disappearance of TNT and the appearance and
disappearance of its metabolites is shown in Fig.
6a. Whereas TNT disappeared rapidly, in
less than 15 h, its amine metabolites 4-ADNT, 2-ADNT, 2,4-DANT,
and 2,6-DANT formed in a stepwise and regioselective fashion favoring
reduction of the NO2 group at the para- position
over that at the ortho- one. For example, during the first
15 h of incubation the ratios of 4-ADNT/2-ADNT and
2,4-DANT/2,6-DANT were 2.0 and 6.0, respectively. After 20 h, both
2-ADNT and 4-ADNT disappeared, and the product ratio 2,4-DANT/2,6-DANT
increased from 6 to more than 10. Stepwise reduction of polynitro
aromatics under both biotic and abiotic conditions have been reported
earlier but with varying degrees of regioselectivities (12, 20,
21, 31). Preuß et al. (24) reported that the
reduction of 2,4-DANT is the rate-limiting step in the overall
reduction process of TNT.
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FIG. 6.
(a) A time study of 2,4,6-TNT biotransformation as
observed by SPME-GC-MS. (b) A time study of 2,4,6-TNT disappearance
together with the formation of 2,4,6-TAT as observed by HPLC with a
C18 column with octanesulfonic acid as an ion-pairing
agent.
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The disappearance of di-aminotoluenes 2,4-DANT and 2,6-DANT was
accompanied by the accumulation of TAT (160 µM). Figure 6b signifies
the relationship between the disappearance of TNT and the formation of
TAT as determined by the HPLC ion-pairing technique. After 6 days of
incubation under anaerobic conditions, TAT started to disappear,
producing the TAT azo derivatives, e.g., 2,2',4,4'-TA-6,6'-azoT and
2,2',6,6'-TA-4,4'-azoT. After 30 days, TAT and its azo-derivatives disappeared, leaving behind an unidentified precipitate, possibly a
polyazo compound, although the system was kept strictly anaerobic. As
mentioned earlier, no TAT hydrolysis products (phenolics) were detected
under anaerobic conditions. Only when the microcosms containing the TAT
metabolite were exposed to air were the phenolic products HDAT, DHAT,
and traces of THT formed. Eventually, TAT and its phenolic products
disappeared to an unidentified precipitate (polymer). TAT is known to
be a reactive molecule and would eventually react with itself if not
with other hydroxylated compounds such as phenolics and carboxylic
acids expected to be present in the sludge (8, 18, 25).
Carpenter et al. (5) demonstrated that the biotransformation
of 14C-labeled TNT in an activated sludge system leads to
the formation of polyamide precipitate due to a reaction involving
biotransformed TNT products with protein constituents of the microbial
flora. All these transformations were taking place without causing any increase in mineralization. In all, about 0.1% of all disappeared 14C-labeled TNT was accounted for as due to mineralization
(14CO2).
From the preceding discussion it seems that there were two distinctive
biotic cycles that were taking place during TNT biodegradation with the
anaerobic sludge. The first one was responsible for the transformation
of TNT to TAT, whereas the other one led to the conversion of TAT to
its azo derivatives, which apparently reacted further to produce azo
polymers. In the presence of air, TAT underwent slow hydrolysis to the
corresponding phenolics. The formation of these hydrolyzed products was
enhanced under acidic conditions (pH 2). Eventually these phenolic
products disappeared to produce unknown polymers, too.
The sequence of events deduced from the above detailed time study was
eventually translated into the transformation pathways depicted in Fig.
7a and 7b. Most elements shown in Fig. 7a
represent the biotic cycle of TNT biotransformation to TAT and have
been frequently observed (13, 18, 24). The new elements that were uncovered in the present study included the provision of exclusive
LC-MS analytical evidence on the subsequent biotransformation of TAT to
the corresponding azo derivatives, e.g., 2,2',4,4'-TA-6,6'-azoT and
2,2',6,6'-TA-4,4'-azoT (Fig. 7b). Removing the anaerobic conditions by
exposure to air or by acidification (pH 2), TAT was transformed into
the phenolic derivatives HDAT and DHAT (Fig. 7b), which eventually disappeared and gave an unidentified precipitate (polymer?). This is
not the first time that TAT was described as a killer metabolite that
misrouted TNT from mineralization under anaerobic conditions (27). However, to take advantage of the rapid rearrangement of TNT to TAT, Knackmuss (15) recommended that a joint
anaerobic-aerobic sequential process may be the best approach to
successfully mineralize TNT.
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FIG. 7.
(a) Constructed anaerobic cycle for the
biotransformation of 2,4,6-TNT to 2,4,6-TAT with anaerobic sludge. (b)
The subsequent transformations of 2,4,6-TAT to the corresponding azo
derivatives at pH 7.0 and to the corresponding phenolic compounds at pH
2 to 3. Dashed arrows indicate that THT was formed in trace amounts at
best, and its formation required heating in water at 100°C.
|
|
None of the transformation cycles explained in Fig. 7 were accompanied
by mineralization (14CO2). Also, as we
mentioned earlier, by using [13CH3]TNT as the
N substrate we showed that neither
[p-13CH3]cresol nor
[13CH3]toluene was observed in the present
study.
It is emphasized here that in establishing metabolic pathways, defined
strains of microorganisms are normally employed to act on the target
pollutant. In the present study, the sludge that was used is expected
to contain an undefined cocktail of microorganisms and a complicated
mixture of unidentified products.
One main conclusion from the present study is that TAT had no
significant contribution to TNT mineralization. In contrast, it
possibly acted as a dead-end product that misrouted TNT from mineralization. However, if the formation of TAT is still considered as
an intermediary path to mineralization, then one might suspect that the
rate must be very slow compared to its other side reactions, such as
hydrolysis, polymerization, and condensation with other -OH- and
-COOH-containing compounds. Obviously, more work is needed to exploit
the practical significance of TAT involvement as a major biotransformed
product during TNT biodegradation.
| |
ACKNOWLEDGMENTS |
We greatly appreciate the technical assistance of C. Beaulieu, S. Deschamps, and A. Corriveau. We also thank Peter Lau for bringing some
relevant references to our attention and S. Guiot and C. F. Shen
for providing us with the sludge.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Biotechnology
Research Institute, National Research Council, 6100 Royalmount Ave., Montreal, Quebec H4P 2R2, Canada. Phone: (514) 496-6267. Fax: (514)
496-6265. E-mail: jalal.hawari{at}nrc.ca.
This publication is issued as NRCC 41771.
| |
REFERENCES |
| 1.
|
Ampleman, G.,
S. Thiboutot,
J. Lavigne,
A. Marois,
J. Hawari,
A. J. Jones, and D. Rho.
1995.
Synthesis of 14C-labeled RDX, TNT, NC and GAP for use in assessing the biodegradation potential of these energetic chemicals.
J. Label. Compd. Radiopharm.
36(6):559-577.
|
| 2.
|
Arthur, C. L., and J. Pawliszyn.
1990.
Solid phase microextraction with thermal desorption using fused silica optical fibers.
Anal. Chem.
62:2145-2148.
|
| 3.
|
Boopathy, R., and C. F. Kupla.
1993.
Nitroaromatic compounds serve as nitrogen source for Desulfovibrio sp. (B. strain).
Can. J. Microbiol.
34:430-433.
|
| 4.
|
Brown, D., and B. Hamburger.
1987.
The degradation of dyestuffs: part III. Investigation of their ultimate degradability.
Chemosphere
16:1539-1553.
|
| 5.
|
Carpenter, D. F.,
N. G. McCormick,
J. H. Cornell, and A. M. Kaplan.
1978.
Microbial transformation of 14C-labeled 2,4,6-trinitrotoluene in an activated-sludge system.
Appl. Environ. Microbiol.
35:949-954[Abstract/Free Full Text].
|
| 6.
|
Crawford, R. L.
1995.
Biodegradation of nitrated munition compounds and herbicides by obligately anaerobic bacteria, p. 87-98.
In
J. C. Spain (ed.), Biodegradation of nitroaromatic compounds. Plenum Press, New York, N.Y.
|
| 7.
|
Duque, E.,
A. Haidour,
F. Godoy, and J. L. Ramos.
1993.
Construction of a Pseudomonas hybrid strain that mineralizes 2,4,6-trinitrotoluene.
J. Bacteriol.
175:2278-2283[Abstract/Free Full Text].
|
| 8.
|
Ederer, M. M.,
T. A. Lewis, and R. L. Crawford.
1997.
2,4,6-Trinitrotoluene (TNT) transformation by clostridia isolated from a munition-fed bioreactor: comparison with non-adapted bacteria.
J. Ind. Microbiol. Biotechnol.
18:82-88[Medline].
|
| 9.
|
Funk, S. B.,
D. J. Roberts,
D. L. Crawford, and R. L. Crawford.
1993.
Initial-phase optimization for bioremediation of munition compound-contaminated soils.
Appl. Environ. Microbiol.
59:2171-2177[Abstract/Free Full Text].
|
| 10.
|
Greer, C. W.,
L. Masson,
Y. Commeau,
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.
|
| 11.
|
Harter, D. R.
1985.
The importance of nitroaromatic chemicals in the chemical industry, p. 1-14.
In
D. E. Ricket (ed.), Toxicity of nitroaromatic chemicals. Chemical Industry Institute of Toxicology series. Hemisphere Publishing Corp., New York, N.Y.
|
| 12.
|
Kaplan, D. L.
1990.
Biotransformation pathways of hazardous energetic organonitro compounds, p. 155-182.
In
D. Kamely, A. Chhakrabarty, and G. S. Omenn (ed.), Advances in applied biotechnology, vol. 4. Biotechnology and biodegradation. Portfolio Publishing Co., Houston, Tex.
|
| 13.
|
Kaplan, D. L., and M. A. Kaplan.
1982.
Thermophilic biotransformation of 2,4,6-trinitrotoluene under simulated composting conditions.
Appl. Environ. Microbiol.
44:757-760[Abstract/Free Full Text].
|
| 14.
|
Khan, T., and R. B. Hughes.
1997.
Anaerobic transformation of 2,4,6-TNT and related nitroaromatic compounds by Clostridium acetobutylicum.
J. Ind. Microbiol. Biotechnol.
18:198-203.
|
| 15.
|
Knackmuss, H.-J.
1996.
Basic knowledge and perspectives of bioelimination of xenobiotic compounds.
J. Biotechnol.
51:287-295.
|
| 16.
|
Kumar, G. S.
1992.
In
Azo functional polymers: functional group approach in macromolecular design.
Technomic Publishing Co., Lancaster, Pa.
|
| 17.
|
Lewis, A.,
M. M. Ederer,
R. L. Crawford, and D. L. Crawford.
1997.
Microbial transformation of 2,4,6-trinitrotoluene J.
Ind. Microbiol. Biotechnol.
18:89-96.
|
| 18.
|
Lewis, T. A.,
S. Goszczynski,
R. L. Crawford,
R. A. Korus, and W. Admassu.
1996.
Products of anaerobic 2,4,6-trinitrotoluene (TNT) transformation by Clostridium bifermentans.
Appl. Environ. Microbiol.
62:4669-4674[Abstract].
|
| 19.
|
Manning, J. F., Jr.,
R. Boopathy, and C. F. Kupla.
1995.
In
A laboratory study in support of the pilot demonstration of a biological soil slurry reactor. Report SFIM-AEC-TS-CR-94038.
Bioremediation Group, Environmental Research Division, Argonne National Laboratory, Argonne, Ill.
|
| 20.
|
McCormick, N. G.,
E. F. Florence, and L. Hillel.
1976.
Microbial transformation of 2,4,6-trinitrotoluene and other nitroaromatic compounds.
J. Appl. Microbiol.
31:949-958.
|
| 21.
|
Naumova, R. P.,
N. N. Amerkhanova, and A. Shaikhutdinov.
1979.
Study of the first stage of the conversion of trinitrotoluene.
Prikl. Biokhim. Mikrobiol.
15:45-50.
|
| 22.
|
Pawliszyn, J.
1995.
New directions in sample preparation for analysis of organic compounds.
Trends Anal. Chem.
14:113-122.
|
| 22a.
|
Pawliszyn, J.
1997.
In
Solid phase microextraction: theory and practice, p. 229-241.
Wiley-VCH, Inc., New York, N.Y.
|
| 23.
|
Poerschmann, J.,
Z. Zhang,
F.-D. Kopinke, and J. Pawliszyn.
1997.
Solid phase microextraction for determining the distribution of chemicals in aqueous matrices.
Anal. Chem.
69:597-600.
|
| 24.
|
Preuß, A., and P.-G. Rieger.
1995.
Anaerobic transformation of 2,4,6-trinitrotoluene and other nitroaromatic compounds, p. 69-85.
In
J. C. Spain (ed.), Biodegradation of nitroaromatic compounds. Plenum Press, New York, N.Y.
|
| 25.
|
Preuss, A. J.,
J. Fimpel, and G. Diekert.
1993.
Anaerobic transformation of 2,4,6-trinitrotoluene.
Arch. Microbiol.
159:345-353[Medline].
|
| 26.
|
Razo-Flores, E.,
M. Luijten,
B. A. Donlon,
G. Lettinga, and J. A. Field.
1997.
Complete biodegradation of the azodisalicylate under anaerobic conditions.
Environ. Sci. Technol.
31:2098-2103.
|
| 27.
|
Rieger, P.-G., and H.-J. Knackmuss.
1995.
Basic knowledge and perspectives on biodegradation of 2,4,6-trinitrotoluene and related nitroaromatic compounds in contaminated soil, p. 1-18.
In
J. C. Spain (ed.), Biodegradation of nitroaromatic compounds. Plenum Press, New York, N.Y.
|
| 28.
|
Stahl, J. D., and S. D. Aust.
1995.
Biodegradation of 2,4,6-trinitrotoluene by white rot fungus Phanerochaete chrysosporium, p. 117-131.
In
J. C. Spain (ed.), Biodegradation of nitroaromatic compounds. Plenum Press, New York, N.Y.
|
| 29.
|
Vorbeck, C.,
H. Lenke,
P. Fischer,
J. C. Spain, and H.-J. Knackmuss.
1998.
Initial reductive reactions in aerobic microbial metabolism of 2,4,6-trinitrotoluene.
Appl. Environ. Microbiol.
64:246-252[Abstract/Free Full Text].
|
| 30.
|
Walker, J. E., and D. L. Kaplan.
1992.
Biological degradation of explosives and chemical agents.
Biodegradation
3:369-385.
|
| 31.
|
Weber, E. J.,
M. S. Elcovitz,
D. G. Truhlar,
J. C. Cramer, and S. E. Barrows.
1996.
Factors controlling regioselectivity in the reduction of polynitroaromatics in aqueous solution.
Environ. Sci. Technol.
30:3029-3038.
|
| 32.
|
Weidel, H.
1898.
Über das Methylphloroglucin.
Monatshefte Chem.
19:223-235.
|
| 33.
|
Won, W. D.,
L. H. Di Salvo, and J. Ng.
1976.
Toxicity and mutagenicity of 2,4,6-trinitrotoluene and its microbial metabolites.
Appl. Environ. Microbiol.
31:575-580.
|
Appl Environ Microbiol, June 1998, p. 2200-2206, Vol. 64, No. 6
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
