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Biodegradation products of a sulfonated azo dye in aerobic granular sludge sequencing batch reactors treating a simulated textile wastewater Rita Franca, M. Conceição Oliveira, Helena Maria Pinheiro, and Nídia Dana Lourenço ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/acssuschemeng.9b02635 • Publication Date (Web): 29 Jul 2019 Downloaded from pubs.acs.org on August 5, 2019
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Biodegradation products of a sulfonated azo dye in aerobic granular sludge sequencing batch reactors treating a simulated textile wastewater Rita D.G. Franca,*,† M. Conceição Oliveira,‡ Helena M. Pinheiro,† and Nídia D. Lourenço†,
†
iBB % Institute for Bioengineering and Biosciences, Department of Bioengineering,
Instituto Superior Técnico, Universidade de Lisboa, Av. Rovisco Pais, 1049-001 Lisboa,
Portugal
‡
Centro de Química Estrutural, Instituto Superior Técnico, Universidade de Lisboa, Av.
Rovisco Pais, 1049-001 Lisboa, Portugal
UCIBIO, REQUIMTE, Departamento de Química, Faculdade de Ciências e
Tecnologia, Universidade Nova de Lisboa, Campus de Caparica, 2829-516 Caparica,
Portugal 1 ACS Paragon Plus Environment
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*
KEYWORDS:
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Corresponding author. E-mail:
[email protected] Acid
Red
14;
aerobic
granular
sludge;
biodegradation;
liquid
chromatography-tandem mass spectrometry; sequencing batch reactors; sulfonated
aromatic amines.
ABSTRACT: This study focused on the biodegradation of an azo dye (Acid Red 14, AR14)
in two anaerobic-aerobic sequencing batch reactors (SBRs) treating a synthetic textile
wastewater, operated with aerobic granular sludge under different hydrodynamic
regimens. The aim was to investigate the fate of the anaerobic AR14 breakdown products
(aromatic amines) during the SBRs’ aerobic reaction phase. Specifically, liquid
chromatography coupled with electrospray ionization tandem mass spectrometry (LC-
ESI-MS/MS) was used for structural characterization of AR14 biodegradation
metabolites, their molecular formulae being confirmed by accurate mass measurements.
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Nineteen molecules potentially related to AR14 were detected in the SBRs and their
relative abundances were followed along the aerobic stage of treatment cycles. The two
SBRs shared most of the identified compounds, but with differences in their metabolite
profiles. Biodecolorization through AR14 anaerobic azo bond reduction was confirmed by
the identification of the aromatic amine 4-amino-naphthalene-1-sulfonic acid, which was
further aerobically biodegraded, involving deamination and hydroxylation of the aromatic
ring. The other aromatic amine (1-naphthol-2-amino-4-sulfonic acid) was not detected,
being suggested to undergo autoxidation reactions forming dimeric, stable products. A
different AR14 biodegradation pathway was observed when nitrate was added to the
feed, a new intermediate product being detected (naphthalene-1-sulfonate).
INTRODUCTION
Textile wastewater (TWW) represents one of the main sources of pollution worldwide,
carrying high organic loads and recalcitrant dyes, azo dyes being the main type used (representing 60-70% of all the dye groups).1,2 Acid dyes (including azo, triarylmethane and
anthraquinone dyes), used to color protein fibers (wool, silk, angora, mohair, cashmere),
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nylon and certain modified synthetic fibers, are one of the largest classes of anionic dyes.3
In 1990, acid dyes were the type of dyes most commonly used, with more than 2000 entries in the colour index,1 the global import and export market for acid dyes being more recently estimated as 680,000 tonnes.2 Together with reactive dyes, acid dyes are
considered the most problematic anionic dyes for being recalcitrant to conventional treatment systems.4 This represents a critical environmental concern, owing to the high
degree of acid dyes’ loss to the textile wastewater after dyeing of typical fibers (namely, 5-20% when applied to polyamide).1 The need for efficient and environmentally friendly
dye removal processes led to the study of biological wastewater treatment systems.
Generally, these involve mixed bacterial cultures and include an anaerobic treatment
stage for the reductive cleavage of the dye’s azo bond, followed by an aerobic stage for degradation of potentially toxic, colorless aromatic amine products.5 The use of flocculent activated sludge in anaerobic-aerobic SBR systems has been studied in recent years,6
with notable success in the anaerobic decolorization stage. Yet, the scarce information
on the fate of the breakdown aromatic amines during the aerobic stage revealed that most are not degraded, thus constituting a health hazard.5,6 4 ACS Paragon Plus Environment
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Sulfonated aromatic amines are resistant to biodegradation due to the hydrophilic nature of the sulfonate group.7 Biodegradation has mostly been demonstrated for relatively simple sulfonated amino-benzene/naphthalene compounds.6 This limitation has
generally been attributed to the lack of an adequate aerobic microbial population capable
of metabolizing such compounds. Yet, the operation of SBRs using the innovative aerobic granular sludge (AGS) technology8 was recently shown to be advantageous for azo dye degradation, as compared to conventional activated sludge (CAS).9 The excellent
biomass retention capacity of AGS systems can favor the establishment of a more diverse
microbial population, namely slow-growing bacteria, with the potential ability to
biodegrade recalcitrant aromatic amines, such as 4-amino-naphthalene-1-sulfonic acid (4A1NS) resulting from Acid Red 14 (AR14) bioreduction.9 Accordingly, 4A1NS
biodegradation was also accomplished in biofilm reactors, which allow high biomass retention.10 Moreover, the use of a plug-flow feeding regimen in AGS SBR systems was shown to play an important role in the selection of slow-growing bacteria.8,11
The aim of this study was to compare two anaerobic-aerobic AGS SBRs using different feeding regimens (static feed, anaerobic-aerobic reaction vs anaerobic plug-flow feed, 5 ACS Paragon Plus Environment
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anaerobic-aerobic reaction) regarding azo dye degradation performance, focusing on the
aerobic conversion of sulfonated aromatic amines resulting from azo bond anaerobic
reduction. The SBRs were fed with a synthetic TWW containing the azo dye AR14 with
changes in the feed solution along the experimental run, including an azo dye shock load
and nitrate supplementation. Based on preliminary HPLC analysis, cycles representative
of different 4A1NS profiles were further analyzed by liquid chromatography coupled with
electrospray ionization tandem mass spectrometry (LC-ESI-MS/MS) for the structural
characterization of AR14 reduction metabolites and subsequent degradation products
produced in the SBRs under different operational conditions. This allowed the study of
the fate of AR14 breakdown products regarding the effect of the hydrodynamic regimen
and also that of increasing the azo dye concentration and of the nitrate feed. A brief review
of the literature regarding mass spectrometry (MS) application to TWW sample analysis,
which served as a basis to select the analytical method and sample pre-treatment
procedures most suited to the objective of this work, is presented in Section 1 of the
Supporting Information.
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EXPERIMENTAL SECTION
SBR setup and operation
AGS, previously used in SBRs and subsequently stored at 4 ºC for 18 days, was used
to inoculate two 1.5-L SBRs (H/D=2.5). The SBRs were operated for 205 days using
different feeding regimens: statically fed (from top), anaerobic-aerobic SBR1 vs anaerobic plug-flow fed (from bottom), anaerobic-aerobic SBR2.12 They were operated in 6-h cycles:
30-min or 1-h feeding, followed by a 1.5-h or 1-h stirred anaerobic phase in SBR1 or
SBR2, respectively, 3.5-h aeration, 5-min settling, 1-min drain and idle. A synthetic textile wastewater12 containing a hydrolyzed starch-based sizing agent (Emsize E1), nutrients, pH buffering phosphates and 40 mg L-1 AR14 (Chromotrope FB, Sigma-Aldrich, 50% dye
content), was supplied to the SBRs at a 12-h hydraulic retention time and an organic loading rate, as chemical oxygen demand (COD), of 2.0 kg O2 m-3 d-1. Along the experimental run, changes were introduced in the feed composition of both SBRs: supplementation with 20 mg L-1 of silver nanoparticles (days 0-35); dye-shock load, with a three-fold increase in AR14 concentration to 120 mg L-1 (days 119-134); or
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supplementation with calcium nitrate to 60 and 120 mg NO3 L-1 (days 147-153 and 154205, respectively).
Sample selection
Samples were taken from the SBRs mixed liquor along selected treatment cycles,
centrifuged and the supernatant was stored at -20 ºC for subsequent examination. HPLC
analysis (as described in Section 3 of the Supporting Information) was performed to
assess the concentration-time profile of AR14 and of one of its reduction products
(4A1NS). Based on this preliminary analysis, three specific treatment cycles (I, II and III)
representative of different experimental periods and correspondent 4A1NS aerobic
profiles (Figure 1) were selected for further examination by MS. Specifically, cycle I (day
98) represents an operational period when the SBRs were under the base operational
conditions and 4A1NS was consistently converted in both reactors (Figure 1-I); cycle II
(day 134) represents the dye shock load period, when SBR1 consistently presented
incomplete 4A1NS conversion, while SBR2 sustained complete 4A1NS conversion
(Figure 1-II); cycle III (day 154) represents the period when the SBRs were supplemented
with nitrate and 4A1NS formation was not observed (Figure 1-III). For each selected cycle 8 ACS Paragon Plus Environment
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98), II (day 134) and III (day 154) from the sequencing batch reactors SBR1 (S) and SBR2
(T). Cycle I corresponds to the base operational conditions in feed composition (40 mg AR14 L-1), cycle II represents the dye shock load period (120 mg AR14 L-1), and cycle III represents the period of nitrate supplementation (120 mg NO3 L-1). The selected cycles cover the different 4A1NS aerobic fates observed: complete conversion (cycle I of both
SBRs and cycle II of SBR2), partial conversion (cycle II of SBR1) and not formed (cycle
III of both SBRs). The vertical lines in the charts represent the end of the anaerobic phase,
aeration onset. The arrows in the charts indicate the sampling times of the samples that
were further analyzed by mass spectrometry: A, AB and B correspond to the end of the
anaerobic phase, 1 hour of aeration and end of the aerobic phase, respectively. For a
detailed description of the different hydrodynamic regimens of SBR1 and SBR2 please
refer to section “SBR setup and operation”.
Sample pre-treatment
To achieve higher levels of separation and lower detection limits in LC-MS targeting
azo dye metabolites in complex matrices such as wastewater, several sample pre-
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treatment methods have been proposed (reviewed in Section 1 of the Supporting
Information). The detailed procedure and optimization of the sample pre-treatment,
including several liquid-liquid extraction (LLE) and solid-phase extraction (SPE) tests, are
provided in Section 2 of the Supporting Information. LLE, which was based on the method described by Chan et al. (2012),14 was discarded because no satisfactory results were
obtained, as opposed to SPE. After optimization, sample clean-up was performed by
SPE, using the generic Oasis HLB (Waters) method without the wash step. Briefly, the
SPE cartridge was initially conditioned with 1 mL methanol followed by 1 mL of MilliQ
water. Subsequently, 1 mL of the sample solution was loaded onto the cartridge at room
temperature, followed by elution with 1 mL of methanol, the eluted fraction being collected
for further analysis.
Liquid chromatography-mass spectrometry (LC-MS) analysis LC-MS2 and LC-high resolution MS/MS (LC-HRMS/MS) analyses were conducted on a
Dionex Ultimate 3000 HPLC system coupled inline to an LCQ Fleet ion trap mass
spectrometer equipped with an ESI source (Thermo Scientific), and on a UHPLC Elute
interfaced with a QqTOF Impact II mass spectrometer equipped with an ESI source 11 ACS Paragon Plus Environment
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(Bruker Daltoniks), respectively. The mass spectrometers were operated in the ESI
positive and negative modes. LC was performed on a CORTECS RP18 column (Waters)
using a gradient elution of 0.1% formic acid in water and acetonitrile. For details about LC-MS2 and LC-HRMS/MS settings see Sections 4 and 5 of the Supporting Information,
respectively.
RESULTS AND DISCUSSION
LC-MS analysis
Each SBR1 and SBR2 sample was analyzed by LC-MS in parallel with the
correspondent time sample from the dye-free control SBR in order to select the most
significant ions that were present in SBR1 or SBR2 samples but absent in the dye-free
SBR. The aim was to select uniquely the metabolites deriving from the azo dye AR14, as
opposed to other molecules resulting from the carbon source metabolism. In addition, an
AR14 solution was also analyzed by LC-MS in order to identify the impurities present in
the AR14 commercial product (section 6 of the Supporting Information). Analysis of the
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samples together with the controls resulted in the selection of 19 ions (Table 1) possibly
related to degradation products from AR14.
Table 1. Most significant ions detected in electrospray ionization (ESI) negative
(metabolites 1-16) and positive (metabolites 17-19) modes in each sequencing batch
reactor (SBR) sample from cycles I, II and III analyzed by LC-MS.
I
II
SBR1 A B
SBR2 A B
SBR1 A AB
B
SBR2 A AB
B
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Metabolite
RT (min)
m/z
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
15.9 10.0 3.7 12.7 6.7 12.3 11.9 12.8 13.7 15.6 10.1 10.7 17.3 12.7 14.7 19.5
189 207 222 228 239 252 268 377 379 391 393 394 419 457 592 689
X
17 18 19
7.3 12.6 13.7
173 174 189
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
III
X
X
X
SBR2 A B
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
SBR1 A B
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
RT: retention time; m/z: mass-to-charge ratio.
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Most of the selected ions were shared by different samples and SBRs. In addition, some
metabolites typically observed in cycles I and II were absent in cycle III (deprotonated molecules m/z 189, 222, 391, 393 and 394), and vice versa (deprotonated molecules m/z
228, 268, 379, 457, 592), suggesting that a change in the azo dye metabolism occurred upon nitrate supplementation of the SBRs. The deprotonated molecules m/z 222 and 457 (as well as 228, [M-2H]2-) detected in the ESI negative mode correspond to the
deprotonated aromatic amine 4A1NS and AR14, respectively, as confirmed by analysis
of the respective standards. The other aromatic amine resulting from AR14 azo bond
reduction, 1-naphthol-2-amino-4-sulfonic acid (1N2A4S) was not detected through LCMS (expected m/z 238, as deprotonated molecule), as expected from its unstable
character. The abundance of each selected ion (Table 1) in the analyzed samples is
graphically represented in Figures 2 and 3. Assuming that no significant variations
occurred during the analysis of all the samples in the low resolution MS (performed in a
single run to minimize variations), the results presented in Figures 2 and 3 can give an
indication of the changes in each ion abundance. Despite the relevant information that
can be extracted by analyzing each ion profile, it is important to note that relative 14 ACS Paragon Plus Environment
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abundance comparison between different ions is not appropriate owing to the fact that
ESI favors ionization of the most polar compounds.
According to Figures 2 and 3, the deprotonated molecules whose abundance was typically observed to decrease along the aerobic phase in both SBRs include m/z 207, 222, 377, 393 and 592. In contrast, deprotonated molecules corresponding to m/z 239,
252, 268, 379, 394 and 689 generally increased in abundance along the aerobic phase
in both SBRs, representing good candidates for transformation products of the former
ions. Specifically, taking into account their relatively symmetrical abundance variation along the aerobic phase (Figure 2), a correlation might exist between the ions m/z 207
and 252. In contrast, none of the ions whose abundance increased in the aerobic phase could be directly correlated with the disappearance of m/z 222, supporting the hypothesis
of complete mineralization of 4A1NS in cycle I in both SBRs and cycle II in SBR2.
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m/z 189
m/z 207 800 800
m/z 189
700 700
250 250
450 450
m/z 207
400 400
150 150
300 300
500 500
Intensity
Intensity
250 250
400 400
200 200
300 300
100 100 50 50
100 100
100 100
50 50
00
00
SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
I
II
150 150
200 200
I
III
m/z 228
70
II
300 300
m/z 228
m/z 239
50
30 30
Intensity
200 200 Intensity Intensity
Intensity
Intensity
50
40 40
150 150
100 100
20 20
50 50
10 10 00
00
SBR1 SBR2 SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
II
I
II
m/z 377
m/z 268
1400 1400
30 30
1
800 800
200 200
II
60 60 40 40 20 20 00
I
II
SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR2 SBR1
I
III
m/z 393
m/z 391
1200
m/z 391
300
450
m/z 393
400 400
1000
350 350
800
300 300
250
250 Intensity
800
200
200 150
150
m/z 394
250 250
600 600
200 200
150 150
400 400
100
III
450
1000
300
II m/z 394
1200
Intensity
350 350
80 80
SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
III
III
m/z 379
00
2
SBR1 SBR2 SBR1 SBR1 SBR2 SBR1 SBR2 SBR2
II
m/z 379
100 100
600 600
10 10
I
1 1
400 400
0
m/z 377
1000 1000
20 20
m/z 252
I
1200 1200 Intensity
Intensity
40 40
SBR1 SBR1 SBR2 SBR2
III
1 120 120
Intensity Intensity
m/z 268
50 50
0
II
SBR1 SBR2 SBR1 SBR2 SBR1 SBR2 SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
III
1600 1600
60 60
100 90 90 80 80 70 70 60 60 50 50 40 40 30 30 20 20 10 10 00
SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
III
70
70
SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR1 SBR2
100
250 250
60
I
SBR1 SBR1 SBR2 SBR2
I
III
m/z 239
70 60
00
SBR1 SBR2 SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR2 SBR1 SBR2 SBR1
Intensity
Intensity Intensity
600 600 200 200
m/z 222
350 350
Intensity
300 300
Intensity
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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100 100
50 50
200 200
00
00
SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
I
II
III
50 50 00 2 SBR1 SBR2 SBR1 SBR2 SBR1 SBR2
I
II
SBR1 SBR2 SBR2 SBR1 SBR2 SBR2 SBR1 SBR1 SBR2 SBR2 SBR1 SBR1
I
III
II
III
Figure 2. Abundance (intensity) of ions m/z 174 to 394 (ESI negative mode) in samples
harvested in cycles I, II and III from the sequencing batch reactors SBR1 and SBR2 at 2
2
the end of the anaerobic phase (darkest blue bars; sample B), after 1 hour of aeration
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2
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blue or orange bars; sample AB; only analyzed on cycle II), and at the end of the aerobic
phase (lightest blue or orange bars; sample B).
Although both SBRs shared most of the identified compounds in each experimental
period, specific differences were observed in their metabolites’ aerobic profiles. For
instance, some deprotonated molecules presented opposite variation trends in the two SBRs (Figures 2 and 3). Specifically, the abundance of ions with m/z 189, 391 and 419
increased along the aerobic phase in SBR1, while decreasing in SBR2. Regarding
protonated molecules, while the abundance of the majority was maintained along the aerobic phase in SBR1, the number of ions with m/z 174 and 189 decreased in SBR2, as opposed to m/z 173 and 346, the abundance of which increased in the latter. Overall, a
decrease in metabolite abundance along the aerobic phase was more often observed in
SBR2 than in SBR1, indicating a potential advantage in using a plug-flow feeding
regimen.
Comparing the abundance of the same ion between samples harvested in cycles I and II, it was possible to observe that the number of deprotonated molecules with m/z 189,
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239 and 391 (as well as 4A1NS, m/z 222) significantly increased in both SBRs upon the
three-fold increase in AR14 concentration (Figure 2). This result further supports a
possible direct (or indirect) relation of the respective compounds to AR14 or its reduction
products, 4A1NS and 1N2A4S. Furthermore, a comparison between cycles III and I
(same AR14 concentration in the SBRs feed), allowed the identification of compounds
whose presence possibly resulted from the supplementation of the SBRs with nitrate. Specifically, deprotonated molecules with m/z 207, 252, 268, 379 and 592 (besides AR14,
m/z 228 and 457) were only significantly observed in samples from cycle III. In contrast, deprotonated molecules with m/z 189, 391, 393 and 394 (besides 4A1NS, m/z 222), as well as protonated molecules with m/z 189 were absent in cycle III (Figures 2 and 3).
LC-HRMS/MS analysis
For each SBR1 and SBR2 sample, precursor ions were selected (Table 1) and collision-
induced dissociation was performed to obtain the respective product ions spectra. After analyzing all LC-MS2 data, the fragmentation pattern found for each of the 19 selected
ions was summarized in Table S5 of the Supplementary Information. In addition, LC-
HRMS/MS was conducted in ESI negative and positive modes for some of the samples, 19 ACS Paragon Plus Environment
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Page 20 of 37
covering the 19 precursor ions previously selected, the results being summarized in Table
2. Tandem MS experiments performed on a QqTOF mass spectrometer allowed to
propose fragmentation pathways for selected precursor ions with higher accuracy than in an ion trap, which was particularly relevant to distinguish ions with very similar m/z values,
as well as to confirm some of the neutral losses through their accurate mass values (Table
2).
Fragmentation patterns characteristic of compounds containing the sulfonate group
were repeatedly observed in the ESI negative mode, as neutral losses of 64 u and 80 u
typically correspond to the loss of SO2 and SO3, respectively (Table 2). This specific fragmentation pattern further indicates that most of the selected ions originated from the
azo dye AR14, since this was the only compound in the SBR feed that contained sulfonate
groups. In addition, other fragments possibly involved the loss of NH3 (17 u), CH4 (16 u), CHN (27 u), and CO (28 u), among others. Based on the RT, m/z and fragmentation
pattern of each precursor ion, it was possible to suggest some correlations between the metabolites (Table 2). Specifically, metabolites 6 (m/z 252) and 7 (m/z 268) probably
correspond to a similar molecule, metabolite 7 containing one extra oxygen atom. Owing 20 ACS Paragon Plus Environment
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to the similarities between their fragmentation patterns, metabolite 8 (m/z 377) probably corresponds to the AR14 molecule (metabolite 14, m/z 457) without one sulfonic acid group. In addition, metabolite 13 (m/z 419) is possibly an adduct of metabolite 8 (m/z 377) with C2H2O. Also, metabolites 8 (m/z 377) and 9 (m/z 379) likely have a similar structure, with the difference of the latter containing two extra protons. The same can be hypothesized for metabolites 10 (m/z 391) and 11 (m/z 393). Furthermore, metabolite 12 (m/z 394) possibly corresponds to metabolite 11 (m/z 393) but containing a nitrogen atom instead of an oxygen atom. The same can be inferred regarding metabolites 17 (m/z 173) and 18 (m/z 174). Based on the fragmentation patterns detailed in Table 2 and on these
assumptions, the tentative attribution of some of the ions previously selected as relevant
in the AR14-fed SBRs was performed, the proposed chemical structures being summarized in Figure 4 (cf. sections 8 and 9 of the Supporting Information for the
respective fragmentation pattern, MS and MS/MS spectra). Although it is not possible to
precisely determine the molecular structure of the metabolites with the available
information, Figure 4 gives an indication of the general structure. Confirmation of the
proposed structures would require further study, namely comparison with commercial 21 ACS Paragon Plus Environment
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standards, when available (confirmed for metabolites 3, 4 and 14), Nuclear Magnetic
Resonance (NMR) and further MS/MS analysis.
22 ACS Paragon Plus Environment
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Table 2. LC-HRMS/MS analysis results. Measured accurate mass of precursor ions,
respective product ions (the most relevant are highlighted in bold) and neutral loss is
indicated, along with attributable species.
1
m/z 189.0585 *
MS Precursor ion [M-H]-
RT (min) 12.3
2
207.0143
[M-H]-
8.1
3
222.0280
[M-H]-
1.7
4
228.0112
[M-2H]2-
10.8
5
239.0072
[M-H]-
4.7
Metabolite
6
252.0030
[M-H]-
10.3
7
267.9923
[M-H]-
9.9
8
377.0599
[M-H]-
10.9
9
379.0362
[M-H]-
12.0
10
391.0483
[M-H]-
13.5
11
393.0636
[M-H]-
10.0
12
394.0470
[M-H]-
8.9
13
419.0705
[M-H]-
15
14
457.0251
[M-H]-
10.7
m/z 173.0280 145.0329 143.0529 115.0606 158.0644 128.0555 221.0203 170.0291 220.9974 174.0352 159.0468 145.0323 129.0378 222.0039 206.0095 188.0397 250.9898 220.9915 192.9973 188.0364 170.0253 361.0407 313.0982 297.1035 281.0850 270.0927 313.1053 299.0787 271.0834 327.0847 310.0823 299.0894 329.0918 313.0989 314.0890 296.0779 286.0939 377.0604 355.1088 339.1143 324.0905 313.0986 297.1029 377.0649 297.1066
MS/MS Product ions [(M-H)-CH4][(M-H)-CH4-CO][(M-H)-SO2][(M-H)-C2H4][(M-H)-SO2][(M-H)-SO2-CH2O][(M-H)-C10H6NO4S•]•[(M-H)-C10H7O3S•-SO3]•[(M-H)-H2O][(M-H)-SO2H•]-• [(M-H)-SO3][(M-H)-SO2-CH2O][(M-H)-SO3-CH2O][(M-H)-CH2O][(M-H)-CH2O2][(M-H)-SO2][(M-H)-NH3][(M-H)-NH3-CH2O][(M-H)-NH3-CH2O-CO][(M-H)-SO3][(M-H)-SO3-H2O][(M-H)-CH4][(M-H)-SO2][(M-H)-SO3][(M-H)-SO3-CH4][(M-H)-SO3-CHN][(M-H)-SO2H2][(M-H)-SO3][(M-H)-SO3-CO][(M-H)-SO2][(M-H)-SO3H•]-• [(M-H)-SO2-CO][(M-H)-SO2][(M-H)-SO3][(M-H)-SO3][(M-H)-SO3-H2O][(M-H)-SO3-CO][(M-H)-C2H2O][(M-H)-SO2][(M-H)-SO3][(M-H)-SO2H•-CH2O][(M-H)-C2H2O-SO2][(M-H)-C2H2O-SO3][(M-H)-SO3][(M-H)-SO3-SO3]-
Neutral loss (u) 16.0305 44.0256 63.9614 91.9537 63.9636 93.9725 236.0099 287.0011 18.0098 64.9720 79.9605 93.9749 109.9694 29.9991 45.9935 63.9633 17.0025 47.0008 74.9950 79.9559 97.967 16.0192 63.9617 79.9564 95.9749 106.9672 65.9309 79.9575 107.9528 63.9636 80.9660 91.9589 63.9633 79.9562 79.9580 97.9691 107.9531 42.0101 63.9617 79.9562 94.9800 105.9719 121.9676 79.9602 159.9185
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15
592.0349
[M-H]-
12.7
16
689.1617
[M-H]-
15.8
17
173.0739
[M+H]+
5
18
174.0571
[M+H]+
11.1
19
189.0572
[M+H]+
12.3
Page 24 of 37
[(M-H)-C10H7NO3S••]••[(M-H)-C10H6NO4S•]•[(M-H)-SO3-SO3][(M-H)-SO2][(M-H)-SO2-SO2][(M-H)-NH3][(M-H)-SO3][(M+H)-CHN]+ [(M+H)-CHN-H2O]+ [(M+H)-CO]+ [(M+H)-CHN-H2O]+ [(M+H)-CO]+
236.0060 221.0180 170.0280 528.0725 464.1096 672.1355 609.2059 146.0621 128.0547 146.0629 129.0457 161.0619 146.0391 143.0521
221.0191 236.0071 286.9971 63.9624 127.9253 17.0262 79.9558 27.0118 45.0192 27.9942 45.0114 27.9953 43.0181 46.0051
[(M+H)-CO-CH3•]+• [(M+H)-CO-H2O]+
* Precursor ion absent in respective MS/MS spectra indicating total fragmentation; RT: retention time.
2
5
3
7
6
NH2
OH
NH
N OH
O
O
OH O
–
S
O O
–
S
O
O
–
S
O
O
–
OH
S
O O
O
O O
8
O
O
C10H8NO3S-
C10H7O3S-
C10H7O5S-
O O
S
O
–
O S
O
H OH
OH N
O
N
O
O
NH
S
O
S
11 O
H OH
C10H6NO6S-
C10H6NO5S-
10
–
O
–
N
N N –
O
C20H13N2O5S-
C20H11N2O5S-
13
12 O
O
O
C20H13N2O4S-
4 & 14
–
O
NH
–
O
OH H
O
O
S
N
N
O
O S
S
H OH
HO
O
N
N
O –
O
OH
C20H12NO6S-
C22H15N2O5S
O
18
17
+
NH + NH2
18’
+ NH2 NH
NH2 18’’ NH
O
C20H13N2O7S2
19
++
OH
S O
O H+ +
OH
O
CH3
C10H9N2O+
OH
OH
C10H8NO2+
OH
C11H9O3+
+ OH2 OH
24 ACS Paragon Plus Environment
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Figure 4. Summary of some of the plausible molecular formulas and chemical structures
proposed for metabolites detected in the electrospray ionization (ESI) negative and
positive modes (blue and orange squares, respectively).
The molecular formula of each proposed chemical structure (Figure 4) was assessed
on accurate mass measurements of the corresponding precursor taking into account the
accuracy and precision of the measurement parameters, such as error (ppm) and
mSigma (Table 3).The molecular formulas were validated through the fragmentation
patterns, supporting the respective proposed chemical structure (Figure 4). Although
future work is needed to confirm their chemical structure, correlations between the
identified metabolites are suggested (Figure 5), in light of the predicted degradation
pathway
for
AR14
(described
in
EAWAGBBD
Pathway
Prediction
System;
http://umbbd.ethz.ch/predict/) and the associations previously established based on the
LC-MS analysis. Table 3. Classification of the correspondence between the measured accurate m/z value
in the LC-HRMS analysis, and the proposed ion chemical formula (Score = 100%).
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Metabolite
Page 26 of 37
Measured m/z
Attribution
Ion Formula
Calculated m/z
> (ppm)
mSigma
2 3 4 5 6 7 8 10 11 12 13 14 17 18
207.0139 222.0280 228.0112 239.0072 251.9979 267.9956 377.0602 391.0483 393.0625 394.0449 419.0785 457.0251 173.0739 174.0566
[M-H][M-H][M-2H]2[M-H][M-H][M-H][M-H][M-H][M-H][M-H][M-H][M-H][M+H]+ [M+H]+
C10H7O3S C10H8NO3S C20H12N2O7S2 C10H7O5S C10H6NO5S C10H6NO6S C20H13N2O4S C20H11N2O5S C20H13N2O5S C20H12NO6S C22H15N2O5S C20H13N2O7S2 C10H9N2O C10H8NO2
207.0121 222.0230 228.0048 239.0020 251.9972 267.9921 377.0602 391.0394 393.0551 394.0391 419.0707 457.017 173.0709 174.0550
-8.5 -22.6 -28.1 -22 -2.6 -12.8 -0.2 -22.7 -18.9 -14.7 -18.7 -17.8 -16.9 -9.4
10.1 32.5 17.9 16.6 31.3 n.a. 19.1 9.9 8.2 48.3 36.8 24.0 n.a. 5.8
19
189.0561
[M+H]+
C11H9O3
189.0546
-7.8
n.a.
n.a.: not attributed. Identification of the sulfonated aromatic amine 4A1NS in both SBRs confirmed the
occurrence of AR14 reduction in the anaerobic stage. Accordingly, the first step of AR14
biodegradation (Figure 5) apparently corresponded to the anaerobic AR14 azo bond
reduction, at least in cycles I and II, when 4A1NS was detected. However, it is possible
that AR14 (corresponding to compounds 4 and 14) suffered other transformations before
the cleavage of its azo bond. Specifically, desulfonation of AR14 may have occurred
resulting in metabolite 11 and, subsequently, metabolite 8, in addition to the incomplete
cleavage of the AR14 azo bond (Figure 5). Since these metabolites were observed at the
end of the anaerobic phase (Figure 2), the hypothetical desulfonation of the aromatic ring
occurred under anaerobic conditions. 26 ACS Paragon Plus Environment
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ACS Sustainable Chemistry & Engineering
On the other hand, when the original AR14 molecule was completely reduced, two
aromatic amines were formed, as confirmed by the presence of 4A1NS (metabolite 3).
The complete disappearance of the recalcitrant 4A1NS from the SBR samples indicated
that it was further transformed during the aerobic stage (Figures 1 and 2), representing a progress relative to previous work.13 In accordance with the predicted AR14 degradation
pathway (EAWAGBBD Pathway Prediction System), 4A1NS probably underwent
deamination and aromatic ring hydroxylation forming metabolite 5, as previously suggested.14 Subsequently, metabolite 5 is expected to suffer aromatic ring cleavage
(Figure 5), with further oxidation eventually leading to the production of aliphatic carboxylic acids and ultimately mineralization.14,15 Based on the putative structures
proposed for metabolites 18’’ and 6, another aromatic ring opening pathway was
suggested (Figure 5), although the probability of these transformations must be further
addressed.
Upon SBRs supplementation with nitrate (cycle III), 4A1NS was no longer detected in
SBR1 and SBR2 (Figures 1 and 2). Instead, new metabolites emerged (Table 1),
suggesting that a different AR14 biodegradation pathway took place in the presence of 27 ACS Paragon Plus Environment
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Page 28 of 37
nitrate. In fact, in light of the proposed structure for metabolite 2, direct deamination of the
4A1NS was suggested to occur upon AR14 reduction under anaerobic conditions. This
observation is in accordance with a previous study reporting the degradation of some aromatic amines under denitrifying conditions.16 Spefically, this finding in supported by Seymour et al. (2002) who showed that nitrite, which is produced during the first step of
denitrification, reacts with aromatic amines, resulting in deamination, thus improving their biodegradation potential.17
In contrast to 4A1NS, the other aromatic amine derived from AR14 azo bond reduction
(1N2A4S) was not detected. In this sense, some transformations of 1N2A4S are
proposed, involving metabolite 18’ (Figure 5). In addition, similarly to 4A1NS, deamination
and aromatic ring hydroxylation can be proposed to generate metabolite 5. However, the presence of a hydroxyl group in the ortho-position relatively to the amino group in 1N2A4S provides an unstable character to this molecule,18 which explains why it was not detected
by LC-MS. Consequently, 1N2A4S is likely to undergo spontaneous autoxidation
reactions forming dimeric, stable products, which might be at the origin of complex
aromatic structures containing sulfonate groups, such as metabolites 10 and 12. 28 ACS Paragon Plus Environment
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Overall, these results represent a relevant contribution towards the elucidation of AR14
biodegradation pathways, involving mechanisms whose understanding may be crucial for
efficient TWW treatment.
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–
O
–
O S
H OH
13
H OH
8
O S
O
O N
O
N
N N
O
AR14
H HO
H HO O
O
H OH
H OH
4 & 14
OH
O
H NH
N
H NH
N
N
–
–
–
O
O
S
O
O
OH
n.d.
–
S
NH2
3
NH2
O
S
O
O
O
O
O
–
S
2
O
O
–
+
OH
OH
5
++ NH NH2
S
O
O
O
O
18’
H OH
n.d.
O
N
+ NH+2 NH
18’’
+
OH
O
OH
O S
S
S
11
O
–
S
OH
O
OH
O
O
12
–
O
NH
O
O S
10
–
O
NH
O
n.d.
S
O
6
O O
N
–
O OH
O
OH
N O
OH
O
S O O
–
O
O
–
S
O O
O
Figure 5. Proposed conversion relations between the putative structures proposed for the
different metabolites detected through LC-MS/MS, with a focus on the biodegradation of
Acid Red 14 (AR14) and the aromatic amines resulting from its reduction, namely 4-
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amino-naphthalene-1-sulfonic acid (4A1NS; metabolite 3), according to the EAWAGBBD
Pathway Prediction System. n.d.: not detected in LC-MS analysis.
ASSOCIATED CONTENT
Supporting Information:
The following files are available free of charge. The Supporting Information is
available free of charge on the ACS Publications website at DOI: XXX.
Review of liquid chromatography-mass spectrometry application to textile wastewater;
methodology and results regarding sample pre-treatment optimization (LLE and SPE); detailed experimental information (HPLC, LC-MS2 and LC-HRMS/MS); Summary of results obtained in LC-MS2; total ion chromatograms, MS spectra, MS/MS spectra, and
fragmentation patterns according to LC-HRMS/MS analysis. (PDF)
ACKNOWLEDGMENT
This work was financed by Fundação para a Ciência e a Tecnologia (FCT, Portugal),
projects PTDC/AAG-TEC/4501/2014 and UID/BIO/04565/2013. Funding from Programa
31 ACS Paragon Plus Environment
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Page 32 of 37
Operacional Regional de Lisboa 2020 (Projects N. 007317 and RNEM-Lisboa-01-0145-
Feder-402-022125) is also acknowledged. R.D.G. Franca and N.D. Lourenço
acknowledge
FCT
for
doctoral
(SFRH/BD/95415/2013)
and
post-doctoral
(SFRH/BPD/88095/2012) research grants, respectively. The authors thank Ms. Ana Dias
for running the low resolution MS data. This article was presented at the 13th International
Chemical and Biological Engineering Conference (CHEMPOR 2018). The authors
acknowledge the Scientific and Organizing Committees of the Conference for the
opportunity to present this work.
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reactions of different aromatic o-aminohydroxynaphthalenes that are formed during the 36 ACS Paragon Plus Environment
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