Response of microorganisms in biofilm to sulfadiazine and ciprofloxacin in drinking water distribution systems

Accepted Manuscript Response of microorganisms in biofilm to sulfadiazine and ciprofloxacin in drinking water distribution systems Haibo Wang, Chun Hu, Yi Shen, Baoyou Shi, Dan Zhao, Xueci Xing PII:

S0045-6535(18)32213-6

DOI:

https://doi.org/10.1016/j.chemosphere.2018.11.106

Reference:

CHEM 22590

To appear in:

ECSN

Received Date: 19 July 2018 Revised Date:

7 November 2018

Accepted Date: 15 November 2018

Please cite this article as: Wang, H., Hu, C., Shen, Y., Shi, B., Zhao, D., Xing, X., Response of microorganisms in biofilm to sulfadiazine and ciprofloxacin in drinking water distribution systems, Chemosphere (2018), doi: https://doi.org/10.1016/j.chemosphere.2018.11.106. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Graphical Abstract

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Response of microorganisms in biofilm to sulfadiazine and ciprofloxacin

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in drinking water distribution systems Haibo Wang,a

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Xueci Xingb

Chun Hu,a, b *

Yi Shen,c

Baoyou Shi,a, d

Dan Zhao,c **

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a

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Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China

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b

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Ministry of Education, Institute of Environmental Research at Greater Bay,

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Key Laboratory of Drinking Water Science and Technology, Research Center for

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Key Laboratory for Water Quality and Conservation of the Pearl River Delta,

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Guangzhou University, Guangzhou, 510006, China

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c

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and Technology, Suzhou, Jiangsu, 215009, China

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d

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School of Environmental Science and Engineering, Suzhou University of Science

University of Chinese Academy of Sciences, Beijing, 100049, China * Corresponding author Tel.: (+86)-10-62922155; Fax: (+86)-10-62843541

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E-mail address: [email protected] (Chun Hu), [email protected] (Dan Zhao)

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ABSTRACT

Effects of sulfadiazine and ciprofloxacin on microorganisms in biofilm of drinking

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water distribution systems (DWDSs) were studied. The results verified that the

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increases of 16S rRNA for total bacteria and bacterial genus Hyphomicrobium were

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related to the promotion of antibiotic resistance genes (ARGs) and class 1 integrons

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(int1) in DWDSs with sulfadiazine and ciprofloxacin. Moreover, the bacteria showed 1

ACCEPTED MANUSCRIPT higher enzymatic activities in DWDSs with sulfadiazine and ciprofloxacin, which

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resulted in more production of extracellular polymeric substances (EPS). The higher

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contents of EPS proteins and secondary structure β-sheet promoted bacterial

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aggregation and adsorption onto surface of pipelines to form biofilm. EPS can serve

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as a barrier for the microorganisms in biofilm. Therefore, the biofilm bacterial

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communities shifted and the 16S rRNA for total bacteria increased in DWDSs with

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antibiotics, which also drove the ARGs promotion. Furthermore, the two antibiotics

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exhibited stronger combined effects than that caused by sulfadiazine and

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ciprofloxacin alone.

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Keywords: sulfadiazine, ciprofloxacin, biofilm, antibiotic resistance genes,

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enzymatic activities, extracellular polymeric substances

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1. Introduction

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Supply of safe drinking water is very important for public health (Wang et al.,

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2013). Recently, antibiotic resistance bacteria (ARB) and antibiotic resistance genes

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(ARGs) have been extensively detected in drinking water and constitute a major

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public health issue (Bergeron et al., 2015; Binh et al., 2018). Disinfection removes the

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majority of microorganisms in source water, however, low level of microorganisms

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are still present in treated water before entering drinking water distribution systems

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(DWDSs) (Liu et al., 2016). Jia et al. (2015) have also found that bacterial community

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shift drives ARGs promotion during drinking water chlorination.

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ACCEPTED MANUSCRIPT When the drinking water goes into DWDSs, more than 90% of the total biomass

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exists as biofilm on the surface of pipelines, with only up to 5% of the biomass freely

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suspended in the bulk water (Liu et al., 2016; Lin et al., 2016). The detachment of

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biofilm in DWDSs will induce the deterioration of water quality at customers’ taps

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(Liu et al., 2017; Zhang et al., 2018). Biofilm formation in DWDSs is the result of

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bacterial attachment and multiplication of cells on the inner surface of pipelines (Xue

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et al., 2012; Fish et al., 2017). Biofilm formation in DWDSs is always affected by the

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water quality including natural organic matter (NOM), chlorine concentration,

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temperature and pH (Liu et al., 2016; Xue and Seo, 2013).

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Moreover, many antibiotics including sulfonamide and quinolone are detected in

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source water at level of µg L-1 or ng L-1 now (Johnson et al., 2015; Binh et al., 2018).

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Sulfadiazine and ciprofloxacin are the antibiotics of sulfonamide and quinolone

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usually found in source water, respectively (Gaffney et al., 2015; Binh et al., 2018).

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Trace level of these antibiotics, 1-4 ng L-1, has also been detected in drinking water

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due to ineffective removal through conventional processes (Ye and Weinberg, 2007;

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Gaffney et al., 2015; Jia et al., 2015). Antibiotics in the wastewater and drinking water

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can induce the change of microbial community and the promotion of ARGs (Tandukar

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et al., 2013; Jia et al., 2015; Harb et al., 2016; Wen et al., 2018). When trace level of

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antibiotics in the water go into DWDSs, antibiotics may also influence the biofilm

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composition and the changes of ARGs in biofilm. Jia et al. (2015) have found the

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linkages between bacterial community, ARGs and the concentration of antibiotics in

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drinking water, however, the effect mechanism of antibiotics on the change of

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bacterial community and ARGs in biofilm of DWDSs still remains unclear. In the presence of antibiotics, microbial stress responses may result in the changes

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in metabolism behaviors. Enzymes including dehydrogenase and protease are

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involved in the degradation of different organic matters (Han et al., 2016; Rai et al.,

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2017). Therefore, when the antibiotics are present in DWDSs, the antibiotics will

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affect enzymatic activities. Moreover, extracellular polymeric substances (EPS) are

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the bacterial metabolic products. Weathers et al. (2015) have found the increase of

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EPS production when bacteria were exposed to pollutants perfluoroalkyl acids with

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the concentration above 2 mg L-1. EPS can provide a protective barrier to the bacteria

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in biofilm, which increases the bacterial resistance to disinfectants. The mechanisms

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of EPS protection for bacteria include transport limitation of disinfectant through EPS

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matrix and sacrificial reaction of EPS with disinfectant (Xue et al., 2012). The

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composition and structure of EPS also play great roles on bacterial adsorption to form

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biofilm (Xue et al., 2012; Fish et al., 2016). The secondary structure of protein in EPS

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includes aggregated strands, β-sheet, random coil, α-helix, 3-turn helix and

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antiparallel β-sheet (Han et al., 2017). The effects of the secondary structure of

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protein in EPS on the biofilm formation in DWDSs are still unknown.

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Many studies have investigated the effects of antibiotics on bacterial community,

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and the effects of EPS on the aggregation ability of microorganisms and biofilm

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growth in wastewater and drinking water distribution systems (Jia et al., 2015; Hou et

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al., 2015; Liu et al., 2016; Jia et al., 2017). However, there are no reports about the

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relationship between the enzymatic activities, EPS production, the changes of 4

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bacterial community and ARGs, when the antibiotics are present in DWDSs.

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Therefore, the objectives of this study are (1) to investigate the 16S rRNA for total

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bacteria

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sulfadiazine/ciprofloxacin, and (2) to elucidate the effects mechanism of these

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antibiotics on biofilm by the analysis of enzymatic activity, EPS and ARGs.

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2. Materials and Methods

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2.1. Reagents and raw water

communities

in

biofilm

of

DWDSs

with

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bacterial

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Sulfadiazine and ciprofloxacin, high performance liquid chromatography grade,

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were purchased from Sigma-Aldrich Fluka (USA). Sodium hypochlorite solution,

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analytical grade, was obtained from Sinopharm Chemical Reagent Co., Ltd (China).

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The tested raw water was collected from a drinking water treatment plant in north

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of China, which was treated by coagulation using polyaluminium chloride,

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sedimentation, sand filtration, and biologically-activated carbon filtration (prior to

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entering the chlorine contact tanks). Every month, 250 L tested raw water was taken

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back to the laboratory from the drinking water treatment plant, and was stored at 4 °C

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before use during the experiments. Water quality parameters were measured according

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to standard methods (EPA of China, 2002), and the results were shown in Table S1.

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Differences of water quality were measured using analysis of variance (ANOVA) with

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a significance threshold of α=0.05. The sulfadiazine and ciprofloxacin were not

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detected

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Chromatography-Tandem Mass Spectrometer (UPLC-MS/MS, Quattro Premier XE,

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Waters, USA), therefore, the two antibiotics were added to the tested raw water

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in

the

tested

raw

water

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using

Ultra

Performance

Liquid

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during the experiments.

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2.2. Experiments set-up Ten cast iron coupons were immersed in covered 1.5 L glass fiber-reinforced plastic

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bottles to simulate the DWDSs. Before this study, twelve simulated DWDSs with the

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same format have been run at the same conditions for more than three years. During

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this period, the same tested raw water, which was chlorinated with 1 mg L-1 chlorine

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for 2 h, was added to the twelve simulated DWDSs, respectively. The water in each

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DWDS was displaced with chlorinated water at 48 h intervals and gently agitated by a

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magnetic rotor to mix the water, reflecting dead zones or worst case conditions in

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actual water distribution systems according to the reported methods (Liu et al., 2013;

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Wang et al., 2014).

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The stable corrosion scales and the biofilm in the corrosions scales have been

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formed on surface of cast iron coupons. The cast iron coupons (80 mm×15 mm×5 mm)

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were purchased from Guangyuan Keyou Technology & Trade Co., Ltd (Beijing,

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China), and the surface area of each coupon is 12 cm2. The composition (wt%) was C

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3.25%, O 1.63%, Si 2.23%, P 0.08%, S 0.10%, Fe 90.48%, Cu 0.76%, Mn 0.72%, and

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Zn 0.75%.

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Sulfadiazine and ciprofloxacin at the level of ng L-1 have been found in tap water in

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some cities of China (Han et al., 2010; Jia et al., 2015). Moreover, sulfonamides and

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fluoroquinolones at the level of µg L-1 are always found in source water of China

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(Zhang et al., 2015). Therefore, four kinds of waters, including raw water, raw water

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with addition of 2 µg L-1 sulfadiazine, raw water with addition of 2 µg L-1 6

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ciprofloxacin, were used in this study. In the drinking water treatment plant from

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which the tested raw water was collected, 1 mg L-1 chlorine was used during the

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disinfection process. Therefore, 1 mg L-1 chlorine (NaClO solution) was also used in

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this study. After 1 L test water was chlorinated for 2 h with 1 mg L-1 chlorine, the four

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kinds of waters were poured into the DWDSs, respectively. The total chlorine

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concentration was measured using HANNA HI93711 spectrophotometer (Italy).

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The water in each DWDS was displaced with chlorinated water at 48 h intervals

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and gently agitated by a magnetic rotor to mix the water. Each experiment was done

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in triplicate. According to other studies and our previous studies (Wang et al., 2014;

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Wang et al., 2017), biofilm in simulated DWDSs can reach a relative stable state after

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8 months. Therefore, after 8 months, biofilm in each DWDS were sampled for only

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once, and then the 16S rRNA, ARGs, EPS, enzymatic activity and bacterial

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community in biofilm were analyzed immediately.

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2.3. Concentration analysis of sulfadiazine and ciprofloxacin

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When the sulfadiazine and ciprofloxacin were added to the raw water, the

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antibiotics in raw water, influents (chlorinated water) and effluents of the DWDSs

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were concentrated by solid phase extraction (SPE) method consisting of an HLB

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cartridge (200 mg (6 mL)-1) (Waters Oasis). The samples were taken every two weeks

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during this experiment for eight months. After taking the samples, the exact

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concentration of the antibiotics was immediately tested by Ultra Performance Liquid

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Chromatography-Tandem Mass Spectrometer (UPLC-MS/MS, Quattro Premier XE,

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Waters, USA). The detailed operation methods were listed in Text S1. The optimal

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conditions for the analysis of the two antibiotics were shown in Table S2.

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2.4. Sample collection and DNA extraction After removing the loose deposits by flushing, biofilm samples were scraped from

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10 cast iron coupons in DWDSs using sterile spatulas. The biofilm samples were

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brushed into 40 mL sterile phosphate-buffered saline (PBS, pH 7.0) and filtered

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through a 47 mm diameter, 0.2 µm polycarbonate membrane (Fish et al., 2017). The

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biofilm samples were taken in triplicate, therefore, 3 biofilm samples were brushed

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from 3 simulated DWDSs with the same kind of water to perform the 3 corresponding

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analysis.

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The propidium monoazide (PMA)-bound DNA cannot be amplified in the ensuing

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polymerase chain reactions (PCR). This characteristic is often applied to quantify the

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DNA of live bacteria and characterize the changes in viable bacterial communities

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(Gensberger et al., 2014). The process of PMA treated samples was listed in Text S2.

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An optimum PMA concentration of 40 µM was determined after testing a range of

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concentrations to maximize removal of DNA from 70%-isopropanol-killed

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Escherichia coli cells, while minimizing DNA removal from live cells (Fig. S1). This

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optimum PMA concentration of 40 µM was validated on untreated and

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isopropanol-treated (70%) (30 min incubation) cells from biofilm of DWDSs with

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raw water (Fig. S2). After PMA treatment, samples were subjected to DNA extraction

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with FastDNA SPIN Kit (MP Biomedicals, Solon, OH, USA) following the

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manufacturer’s instructions. To determine the method recovery efficiency, E. coli was

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ACCEPTED MANUSCRIPT used as a representative microorganism according to our previous method (Wang et al.,

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2017). The recovery efficiency varied from 19.1% to 40.5% depending on the

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concentration of samples. Concentrations of DNA were measured with a Nanodrop

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spectrophotometer (ND-1000, NanoDrop, USA).

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2.5. Quantitative PCR and sequencing analysis

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The quantitative PCR (qPCR) experiments were carried out with ABI 7300 Fast

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Real-Time PCR System (Applied Biosystems, Singapore) using premix EX Taq or

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SYBR premix EX Taq (TaKaRa, Japan) in 20 µL reaction volume. The 16S rRNA for

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total bacteria (Wang et al., 2014), the efflux pump which encoding the membrane

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fusion mexA (Tandukar et al., 2013), class 1 integrons (int1) which strictly correlated

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to co-selection mechanism (Cesare et al., 2016), the sulfadiazine resistance genes

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(sul1, sul2, sul3) (Chen et al., 2015) and the ciprofloxacin resistance genes (qnrB and

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qnrS) (Wang et al., 2017) were quantified by qPCR. Primer sequences are presented

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in Table S3. Standard curves were generated with serial ten-fold dilution (109 to 102

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copies µL-1) of the plasmids. The analysis procedures and amplification efficiency

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were described in Text S3. The amplification efficiency values for quantification were

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from 96.5% to 98.8%. The limit of quantification (LOQ) for all qPCR assays ranged

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from 1 to 10 gene copies per reaction and was implemented as appropriate for each

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specific run.

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To determine the diversity and composition of biofilm bacterial communities in

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different DWDSs, PCR amplications were conducted in triplicate with 341f

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(5’-TTACCGCGGCTGCTGGCAC-3’) and 806r (5’-GGACTACNNGGGTATCTAAT 9

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2011). The PCR process was described in Text S4. After purification of PCR products

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and addition of index codes, sequencing libraries were generated. The library was

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sequenced on an Illumina HiSeq platform and 250 bp paired-end reads were generated

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at Novogene (Beijing, China). After sequencing, the sequences were analyzed,

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including operational taxonomic unit (OTU) clustering and taxonomic classification.

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The analysis process was listed in Text S5. Correlations analysis between the bacterial

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communities, 16S rRNA and ARGs was performed using SPSS (Inc., in Chicago,

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Illinois) version 19.0 for windows.

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2.6. Enzyme assays

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The biofilm samples were brushed into 40 mL sterile PBS (pH 7.0), and filtered

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through a 47 mm diameter, 0.2 µm polycarbonate membrane. Then, the enzymes in

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biofilm samples were determined. Dehydrogenase activity was assessed by a modified

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method in which 2-(p-iodophenyl)-3-(p-nitrophenyl)-5-phenyl tetrazolium chloride

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(INT) was used as a terminal hydrogen acceptor (Han et al., 2016). 2 mL of Tris-HCl

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buffer, 2 mL of Milli-Q water and 2 mL of 500 mg L-1 INT solution were added to the

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filters, sequentially. INT was changed to a red insoluble triphenyl formazan (TF)

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crystal by dehydrogenase. After incubation at 37 oC for 30 min, 0.1 mL H2SO4 (98%)

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was added into the tube to stop the reaction. Then, 5 mL acetone (99.5%) was added

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to the solution, and the supernatant was obtained by centrifugation (4000 rpm min-1,

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90 oC, 5 min) and measured at 485 nm using a spectrophotometer (Shimadzu

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UV-1800, Japan). The protease activity was assayed by a modified method using

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L-1 casein were added to the filters. The solutions were incubated at 40 oC for 10 min,

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and then added 2 mL of 0.4 M trichloroacetic acid. The content was centrifuged and

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the supernatant was analyzed using a spectrophotometer (Shimadzu UV-1800, Japan).

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The dehydrogenase and protease activity is expressed as µg of TF and tyrosine

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liberated h-1 cm-2 biofilm, respectively.

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2.7. EPS extraction and analysis

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A heat extraction method was modified to extract different EPS in biofilm of

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different DWDSs (Zhang et al., 2016). The biofilm samples were brushed into 50 mL

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centrifuge tubes with 40 mL sterile PBS (pH 7.0). The tubes were sonicated at 20

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KHz and 40 W for 30 s, followed by heating in water bath at 70 oC for 1 h, and then

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centrifuged at 8000 g for 20 min at 4 oC. The supernatant in the tubes were filtered

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through 0.45 µm polycarbonate filter to collect EPS. The proteins in EPS were

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determined with the Lowry procedure using bovine serum albumin (BSA) (Sigma) as

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standard. Fourier transform infrared spectroscopy (FTIR) (Bruker, Tensor 27) was

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used to determine EPS structures and the distributions of the functional groups. The

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amide I region in the EPS was further analyzed to extract information regarding

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protein secondary structures using Peakfit software (version 4.12, Seasolve Software

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Inc.).

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3. Results and Discussion

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3.1. Changes of sulfadiazine and ciprofloxacin concentration

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Four kinds of DWDSs with raw water, sulfadiazine, ciprofloxacin, and 11

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that the actual concentration of sulfadiazine and ciprofloxacin was (1.94±0.16) µg L-1

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and (2.02±0.15) µg L-1, when they were added to the raw water, respectively (Table

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S4). However, when the waters were chlorinated for 2 h by 1 mg L-1 chlorine, the

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concentration of sulfadiazine became (10.7±1.08) ng L-1, and ciprofloxacin

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disappeared. Moreover, both of sulfadiazine and ciprofloxacin were not detected in

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effluents of DWDSs. Similarly, when sulfadiazine and ciprofloxacin were added to

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the raw water simultaneously, the actual concentration was (1.03±0.08) µg L-1 and

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(0.99±0.07) µg L-1, respectively. After chlorination, only sulfadiazine was detected,

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and its concentration became (5.18±0.43) ng L-1 in the influents. Sulfadiazine and

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ciprofloxacin were also not detected in effluents of DWDSs.

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The results indicated that sulfadiazine and ciprofloxacin could react with chlorine,

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which induced the decrease of sulfadiazine concentration and the disappearance of

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ciprofloxacin in the influents of DWDSs. Moreover, the antibiotics and their

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chlorination byproducts may go through biotransformation by the bacteria in the

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DWDSs, resulting in the disappearance of these antibiotics in effluents of DWDSs

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(Wang et al., 2017). However, the total chlorine concentrations were 0.50 mg L-1 and

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0.05 mg L-1 in the influents and effluents of the four kinds of DWDSs, respectively.

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They did not take great changes when the antibiotic added to the raw water due to the

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low concentration of these antibiotics (p>0.05).

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3.2. The total bacteria and ARGs in biofilm of different DWDSs

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The antibiotics in DWDSs would affect the biofilm formation and the ARGs 12

ACCEPTED MANUSCRIPT transfer. The 16S rRNA for total bacteria, the sulfadiazine resistance genes (sul1, sul2,

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sul3), the ciprofloxacin resistance genes (qnrB and qnrS), efflux pump gene mexA,

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and class 1 integrons (int1) in biofilm of different DWDSs were quantified by qPCR

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(Fig. 1). The average gene copy numbers of 16S rRNA for total bacteria were

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(9.52±0.31), (10.9±0.33), (10.2±0.29), and (11.5±0.32) log (gene copies cm-2) in

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biofilm

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sulfadiazine-ciprofloxacin, respectively (Fig. 1a). The results indicated that trace level

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of sulfadiazine and ciprofloxacin induced the increase of total bacteria in biofilms of

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DWDSs, and the combined effects of sulfadiazine and ciprofloxacin was higher than

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that resulted from sulfadiazine or ciprofloxacin alone.

DWDSs

with

raw

water,

sulfadiazine,

ciprofloxacin

and

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The average gene copy numbers of sul1 were (3.99±0.06), (5.40±0.12), (4.38±0.12),

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and (4.73±0.13) log (gene copies cm-2) in biofilm of DWDSs with raw water,

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sulfadiazine, ciprofloxacin and sulfadiazine-ciprofloxacin, respectively (Fig. 1b). The

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gene copy number of sul1 was higher than that of sul2 and sul3, and the gene copy

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numbers of sul1, sul2 and sul3 correlated very well (r>0.98, p<0.05) (Table S5). In

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addition, the average gene copy numbers of qnrS were (1.55±0.03), (3.34±0.05),

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(3.88±0.04), and (3.64±0.05) log (gene copies cm-2) in biofilm of the four kinds of

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DWDSs. The gene copy number of qnrB showed the same changes with qnrS. The

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results indicated that the higher concentration of sulfadiazine and ciprofloxacin

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induced the higher increase of sulfadiazine and ciprofloxacin resistance genes,

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respectively, which suggested that the concentrations of these antibiotics were the

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main determinants of sul1, sul2, sul3, qnrB and qnrS promotion.

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ACCEPTED MANUSCRIPT Moreover, the average gene copy numbers of mexA were (4.76±0.12), (4.95±0.16),

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(5.41±0.15) and (5.61±0.18) log (gene copies cm-2) in biofilm of DWDSs with raw

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water, sulfadiazine, ciprofloxacin and sulfadiazine-ciprofloxacin, respectively.

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Ciprofloxacin induced higher increase of mexA than that caused by sulfadiazine. The

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multiple mex efflux genes can confer bacterial resistance to nearly all the antibiotics

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by pumping out the antibiotics (Jia et al., 2015; Tandukar et al., 2013). Therefore, the

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combined effect of sulfadiazine and ciprofloxacin resulted in the highest promotion of

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mexA. In addition, the gene copy number of int1 were (4.31±0.11), (4.61±0.15),

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(4.43±0.13) and (5.17±0.16) log (gene copies cm-2) in biofilm of the four kinds of

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DWDSs. An integron such as int1 is a typical gene capture and dissemination system,

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which is nearly ubiquitous in various DNA materials (Chen et al., 2015; Wu et al.,

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2016). Bacteria with int1 had a selective advantage compared to other bacteria, and

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int1 was strictly correlated to co-selection mechanisms (Cesare et al., 2016).

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Therefore, sulfadiazine and ciprofloxacin induced the increase of int1 obviously, and

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the combined effect of sulfadiazine and ciprofloxacin was stronger than that induced

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by sulfadiazine or ciprofloxacin alone.

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The gene copy numbers of 16S rRNA and int1 correlated very well (r>0.95, p<0.05)

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(Table S5). Integrons such as int1 play a great role in the horizontal gene transfer of

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ARGs between microbes (Gaze et al., 2011). Some studies also indicated that the shift

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of bacterial community due to the antibiotics could promote the bacterial resistance

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(Jia et al., 2015; Davids et al., 2017). Therefore, the promotion of the ARGs in biofilm

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of different DWDSs, which was induced by the addition of sulfadiazine and 14

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ciprofloxacin, may be related with the increase of the total bacteria and the bacterial

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community shift in biofilm.

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3.3. Bacterial community shift in biofilm of different DWDSs Based on the sequencing analysis of 16S rRNA genes, Proteobacteria phylum

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dominated in the biofilm bacterial communities of the four kinds of DWDSs, and its

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relative abundance in all the biofilm bacterial communities was more than 89.7% (Fig.

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S3a). At class level, Alphaproteobacteria was the main class in all the biofilm

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bacterial communities (Fig. S3b). Furthermore, the dominant bacteria were compared

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at genus level for different samples (Fig. 2). Hyphomicrobium, Sphingopyxis,

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Sphingomonas, Rhodobacter and Parvularcula were the predominant bacterial genera

319

in biofilm bacterial communities of DWDSs with raw water. The relative abundance

320

of Sphingopyxis and Parvularcula decreased in biofilm bacterial communities of

321

DWDSs with sulfadiazine, ciprofloxacin, and sulfadiazine-ciprofloxacin, which may

322

be due to the antibiotic activity of these antibiotics. The relative abundance of

323

Rhodobacter did not take great changes in DWDSs with the addition of sulfadiazine

324

and ciprofloxacin. However, compared with the DWDSs with raw water, the relative

325

abundance of Hyphomicrobium increased from 40.3% to 46.7%, 43.3% and 49.0% in

326

DWDSs with sulfadiazine, ciprofloxacin, and sulfadiazine-ciprofloxacin, respectively.

327

Moreover, the relative abundance of Bosea, Bdellovibrio and Sphingomonas also

328

increased in biofilm bacterial communities of DWDSs with these antibiotics.

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329

Compared with DWDSs with raw water, the 16S rRNA for total bacteria and the

330

relative abundance of Hyphomicrobium, Bosea, Bdellovibrio and Sphingomonas 15

ACCEPTED MANUSCRIPT increased in biofilm of DWDSs with antibiotics. The results suggested that the growth

332

of these bacterial genera was contributed to the increase of total bacteria in biofilm.

333

Moreover, the relative abundance of the main bacterial genus Hyphomicrobium

334

correlated very well with the gene copy numbers of 16S rRNA and int1 (r>0.95,

335

p<0.05) (Table S5). Therefore, the growth of bacterial genus Hyphomicrobium and the

336

increase of total bacteria were related with the antibiotic resistance genes in DWDSs

337

with sulfadiazine and ciprofloxacin. Moreover, the bacterial communities shift and the

338

total bacteria increase in biofilm induced the ARGs promotion, which was also

339

consistent with other studies indicating that bacterial community shift drove antibiotic

340

resistance promotion during drinking water chlorination (Jia et al., 2015).

341

3.4. Microbial metabolism behaviors

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The protease activity was (22.1±1.95), (29.3±2.05), (40.4±3.07) and (55.8±4.01) µg

343

tyrosine liberated h-1 cm-2 biofilm in DWDSs with raw water, sulfadiazine,

344

ciprofloxacin, and sulfadiazine-ciprofloxacin, respectively (Fig. 3). Moreover, the

345

dehydrogenase activity was (18.5±1.56), (36.0±3.08), (33.0±2.87) and (55.5±3.92) µg

346

TF liberated h-1 cm-2 biofilm in the four kinds of DWDSs, respectively. The results

347

indicated that trace level of sulfadiazine and ciprofloxacin increased the activity of

348

protease and dehydrogenase, and the combined effect of sulfadiazine and

349

ciprofloxacin induced the highest increase, compared with sulfadiazine or

350

ciprofloxacin alone.

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351

The degradation of complex polymeric organic matter by bacteria is related with

352

enzymatic activities (Lautenschlager et al., 2014; Han et al., 2016). Specific 16

ACCEPTED MANUSCRIPT hydrolytic enzymes (protease and dehydrogenase) are important for the growth of

354

microorganisms, when they were exposed to different organic matter including

355

antibiotics (Han et al., 2016; Rai et al., 2017). When antibiotics and their chlorination

356

products were present in DWDSs, they may affect the bacterial growth because of

357

their antibacterial activity. In this condition, metabolism behaviors of bacteria may

358

change due to the microbial stress responses. Therefore, protease and dehydrogenase

359

activities were affected sharply by the presence of antibiotics in our study.

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353

The dehydrogenase activity correlated very well with bacterial genus Bosea (r>0.97,

361

p<0.05) (Table S5). The dehydrogenase activity also showed the same tendency with

362

the main bacterial genus Hyphomicrobium. Moreover, the dehydrogenase activity

363

correlated very well with the gene copy numbers of 16S rRAN and int1 (r>0.95,

364

p<0.05). The protease activity also correlated very well with the gene copy number of

365

mexA (r>0.97, p<0.05) (Table S5). Therefore, the enzymatic activity of biofilm

366

bacterial communities might induce the increase of total bacteria in biofilm of

367

DWDSs with sulfadiazine and ciprofloxacin, and the increase of total bacteria also

368

induced the promotion of ARGs in biofilm. Moreover, EPS are involved in

369

extracellular electron transfer, and the presence of EPS can affect the enzymatic

370

activity (Han et al., 2017). Meanwhile, microbial metabolism behaviors may also

371

influence the EPS production. Therefore, the characterization of EPS in biofilm of

372

different DWDSs was also analyzed.

373

3.5. Roles of EPS on the biofilm formation

374

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Proteins were the main compositions of EPS, and the concentration of EPS proteins 17

ACCEPTED MANUSCRIPT were (194.7±7.36), (210.4±7.58), (198.4±7.14) and (244.0±7.18) µg cm-2 in biofilm

376

of DWDSs with raw water, sulfadiazine, ciprofloxacin, sulfadiazine-ciprofloxacin,

377

respectively (Fig. 4). The results indicated that the combined effects of sulfadiazine

378

and ciprofloxacin induced the highest increase of EPS proteins, followed by

379

sulfadiazine and ciprofloxacin alone.

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Several regions on the FTIR spectra provided information regarding major

381

functional moieties of EPS (Hessler et al., 2012). FTIR spectra showed that nine

382

peaks were present in EPS (Fig. 5a). The peaks at 1049 and 1076 cm-1 were related to

383

C-O stretching of polysaccharides (Adeleye and Keller, 2016). The peak at 1248 cm-1

384

was related to P=O stretching of phospholipids or nucleic acids (Adeleye and Keller,

385

2016). The bands at 1410 cm-1 and 1452 cm-1 corresponded to C–H bending and C–N

386

stretching vibrations of proteins, respectively, which may arise from the amide II (You

387

et al., 2015). The peak bands (1600-1500 cm-1) were due to N-H bending and C-N

388

stretching vibrations in proteins (amide II band), which was very weak in EPS

389

(Adeleye and Keller, 2016). The amide I band (1700-1600 cm-1) was attributable to

390

the C=C and C=O stretching in proteins (Hessler et al., 2012; Jia et al., 2017). The

391

peaks at 2897 and 2972 cm-1 were assigned to C-H antisym and sym stretching in

392

lipids (Adeleye and Keller, 2016). Moreover, for elucidating the changes of the

393

secondary structure of proteins, the curve fitting of original infrared spectra for amide

394

I region were performed (Fig. 5b and Fig. S4). The protein secondary structures

395

included aggregated strands, β-sheet, random coil, α-helix, 3-turn helix and

396

antiparallel β-sheet (Han et al., 2017). The relative contents of these secondary

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18

ACCEPTED MANUSCRIPT structures were shown in Table 1. Compared with EPS from biofilm of DWDSs with

398

raw water, the relative contents of β-sheet in EPS from biofilm increased from 20.3%

399

to 25.6%, 22.1% and 27.6% in DWDSs with sulfadiazine, ciprofloxacin and

400

sulfadiazine-ciprofloxacin, respectively. The changes of the relative contents of

401

β-sheet showed the same tendency with the proteins concentration in EPS. The

402

combined effects of sulfadiazine and ciprofloxacin induced the highest increase of

403

β-sheet, followed by sulfadiazine and ciprofloxacin alone.

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As we all known, EPS played great roles on the bacterial irreversible adherence

405

onto surface to form biofilm (Xue et al., 2012; Fish et al., 2016). In our study,

406

sulfadiazine and ciprofloxacin induced more production of EPS with higher contents

407

of proteins and β-sheet. The relative abundance of Hyphomicrobium and Bdellovibrio

408

correlated very well with β-sheet (r>0.95, p<0.05) (Table S5). Moreover, the gene

409

copy numbers of 16S rRNA and int1 correlated very well with the EPS proteins and

410

β-sheet, respectively (r>0.95, p<0.05) (Table S5). The gene copy numbers of 16S

411

rRNA and int1 also showed good relationship with the enzymatic activities (r>0.95,

412

p<0.05) (Table S5). Therefore, the total bacteria exhibited the highest enzymatic

413

activities in DWDSs with sulfadiazine-ciprofloxacin and induced the highest EPS

414

production. The higher contents of proteins increased the hydrophobicity of cell

415

surfaces (Jia et al., 2017). Due to the twisted and pleated sheet structure of β-sheet,

416

large amounts of inner hydrophobic groups of amino acids were more easily to be

417

exposed and express the hydrophobic property of the bacteria (Hou et al., 2015). The

418

increased hydrophobicity of bacterial surfaces due to the higher contents of proteins

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ACCEPTED MANUSCRIPT and β-sheet promoted the bacterial aggregation and adsorption onto the surface of

420

pipelines to form biofilm. The results were consistent with other studies which

421

indicated that the secondary structure of protein in EPS such as β-sheet played

422

important roles in bioflocculation and adhesion (Yin et al., 2015; Jia et al., 2017).

423

Moreover, EPS can serve as a barrier to mitigate the disinfectant and antibiotics

424

intrusion into the bacteria (Han et al., 2017). Therefore, the bacterial communities

425

changed and the relative abundance of Hyphomicrobium enhanced, meanwhile, the

426

gene copy number of 16S rRNA for total bacteria also increased in biofilm of DWDSs

427

with sulfadiazine and ciprofloxacin, which induced the ARGs promotion. The

428

combined effect of sulfadiazine and ciprofloxacin was stronger than that resulted from

429

sulfadiazine and ciprofloxacin alone.

430

4. Conclusions

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Compared with DWDSs with raw water, the gene copy numbers of 16S rRNA for

432

total bacteria and the ARGs and class 1 integrons (int1) increased in DWDSs with

433

sulfadiazine and ciprofloxacin. The relative abundance of bacterial genus

434

Hyphomicrobium also enhanced. The increase of total bacteria was related to the

435

ARGs promotion. Moreover, the bacteria exhibited higher enzymatic activities and

436

produced more EPS in DWDSs with sulfadiazine and ciprofloxacin. The higher

437

contents of EPS proteins and secondary structure β-sheet promoted bacterial

438

adsorption onto surface of pipelines to form biofilm. Therefore, the total bacteria

439

increased in DWDSs with antibiotics, which also drove ARGs promotion.

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Acknowledgments This work was funded by the National Natural Science Foundation of China (Nos. 51878654,

444

(QYZDY-SSW-DQC004) and the Federal Department of Chinese Water Control and

445

Treatment (Nos. 2017ZX07108, 2017ZX07501002).

446

Declaration of interest

449

project

of

None

Chinese

Academy

of

Sciences

SC

448

the

Appendix A. Supplementary data

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51838005),

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Supplementary material related to this article can be found in the online version.

450

Reference

452

Adeleye, A.S., Keller, A.A., 2016. Interactions between algal extracellular polymeric

453

substances and commercial TiO2 nanoparticles in aqueous media. Environ. Sci.

454

Technol. 50, 12258-12265.

TE D

451

Bartram, A.K., Lynch, M.D.J., Stearns, J.C., Moreno-Hagelsieb, G., Neufeld, J.D.,

456

2011. Generation of multimillion-sequence 16S rRNA gene libraries from complex

458

AC C

457

EP

455

microbialcommunities by assembling paired-end Illumina reads. Appl. Environ. Microb. 77, 3846-3852.

459

Bergeron, S., Boopathy, R., Nathaniel, R., Corbin, A., LaFleur, G., 2015. Presence of

460

antibiotic resistant bacteria and antibiotic resistance genes in raw source water and

461

treated drinking water. Int. Biodeterior. Biodegr. 102, 370-374.

462

Binh, V.N., Dang, N., Anh, N.T.K., Ky, L.X., Thai, P.K., 2018. Antibiotics in the 21

ACCEPTED MANUSCRIPT 463

aquatic environment of Vietnam: sources, concentrations, risk and control strategy.

464

Chemosphere, 197, 438-450. Cesare, A.D., Eckert, E.M., D’Urso, S., Bertoni, R., Gillan, D.C., Wattiez, R., Corno,

466

G., 2016. Co-occurrence of integrase 1, antibiotic and heavy metal resistance genes

467

in municipal wastewater treatment plants. Water Res. 94, 208-214.

RI PT

465

Chen, B., Liang, X., Nie, X., Huang, X., Zou, S., Li, X., 2015. The roles of class 1

469

integrons in the dissemination of sulfonamide resistance genes in the Pearl River

470

and Pearl River estuary, South China. J. Hazard. Mater. 282, 61-67.

M AN U

SC

468

471

Davids, M., Gudra, D., Radovica-Spalvina, I., Fridmanis, D., Bartkevics, V., Muter,

472

O., 2017. The effects of ibuprofen on activated sludge: shift in bacterial community

473

structure and resistance to ciprofloxacin. J. Hazard. Mater. 340, 291-299.

475

EPA of China, 2002. Analysis Method for Water and Waste Water, 4th edition. Press

TE D

474

of Chinese Environmental Science, Beijing. Fish, K.E., Osborn, A.M., Boxall, J., 2016. Characterising and understanding the

477

impact of microbial biofilms and the extracellular polymeric substance (EPS)

478

matrix in drinking water distribution systems. Environ. Sci.: Water Res. Technol. 2,

AC C

479

EP

476

614-630.

480

Fish, K.E., Osborn, A.M., Boxall, J.B., 2017. Biofilm structures (EPS and bacterial

481

communities) in drinking water distribution systems are conditioned by hydraulics

482

and influence discolouration. Sci. Total Environ. 593-594, 571-580.

483

Gaffney, V.J., Almeida, C.M.M., Rodrigues, A., Ferreira, E., Benoliel, M.J., Cardoso,

484

V.V., 2015. Occurrence of pharmaceuticals in a water supply system and related 22

ACCEPTED MANUSCRIPT 485

human health risk assessment. Water Res. 72, 199-208.

486

Gaze, W.H., Zhang, L.H., Abdouslam, N.A., Hawkey, P.M., Calvo-Bado, L., Royle, J.,

487

Brown, H., Davis, S., Kay, P., Boxall, A.B.A., Wellington, E.M.H., 2011. Impacts

488

of

489

integron-associated genes in the environment. ISME J. 5, 1253-1261.

activity

on

the

ecology

of

class

1

integrons

and

RI PT

anthropogenic

Gensberger, E.T., Polt, M., Konrad-Koszler, M., Kinner, P., Sessitsch, A., Kostic, T.,

491

2014. Evaluation of quantitative PCR combined with PMA treatment for molecular

492

assessment of microbial water quality. Water Res. 67, 367-376.

M AN U

SC

490

493

Han, Y.R., Wang, Q.J., Mo, C.H., Li, Y.W., Gao, P., Tai, Y.P., Zhang, Y., Ruan, Z.L.,

494

Xu, J.W., 2010. Determination of four fluoroquinolone antibiotics in tap water in

495

Guangzhou and Macao. Environ. Pollut. 158, 2350-2358.

Han, X., Wang, Z., Wang, X., Zheng, X., Ma, J., Wu, Z., 2016. Microbial responses to

497

membrane cleaning using sodium hypochlorite in membrane bioreactors: cell

498

integrity, key enzymes and intracellular reactive oxygen species. Water Res. 88,

499

293-300.

501 502 503

EP

Han, X., Wang, Z., Chen, M., Zhang, X., Tang, C.Y., Wu, Z., 2017. Acute responses of

AC C

500

TE D

496

microorganisms from membrane bioreactors in the presence of NaOCl: protective mechanisms of extracellular polymeric substances. Environ. Sci. Technol. 51, 3233-3241.

504

Harb, M., Wei, C.H., Wang, N., Amy, G., Hong, P.Y., 2016. Organic micropollutants

505

in aerobic and anaerobic membrane bioreactors: changes in microbial communities

506

and gene expression. Bioresource Technol. 218, 882-891. 23

ACCEPTED MANUSCRIPT 507

Hessler, C.M., Wu, M.Y., Xue, Z., Choi, H., Seo, Y., 2012. The influence of capsular

508

extracellular polymeric substances on the interaction between TiO2 nanoparticles

509

and planktonic bacteria. Water Res. 46, 4687-4696. Hou, X., Liu, S., Zhang, Z., 2015. Role of extracellular polymeric substance in

511

determining the high aggregation ability of anammox sludge. Water Res. 75, 51-62.

512

Jia, F., Yang, Q., Liu, X., Li, X., Li, B., Zhang, L., Peng, Y., 2017. Stratification of

513

extracellular polymeric substances (EPS) for aggregated anammox microorganisms.

514

Environ. Sci. Technol. 51, 3260-3268.

M AN U

SC

RI PT

510

515

Jia, S., Shi, P., Hu, Q., Li, B., Zhang, T., Zhang, X.X., 2015. Bacterial community

516

shift drives antibiotic resistance promotion during drinking water chlorination.

517

Eviron. Sci. Technol. 49, 12271-12279.

Johnson, A.C., Keller, V., Dumont, E., Sumpter, J.P., 2015. Assessing the concentration

520

sulfamethoxazole, trimethoprim and erythromycin in European rivers. Sci. Total

521

Environ. 511, 747-755.

524 525

of toxicity from

the antibiotics

ciprofloxacin,

Lautenschlager, K., Hwang, C., Ling, F., Liu, W.T., Boon, N., Koster, O., Egli, T.,

AC C

523

risks

EP

519

522

and

TE D

518

Hammes, F., 2014. Abundance and composition of indigenous bacterial communities in a multi-step biofiltration-based drinking water treatment plant. Water Res. 62, 40-52.

526

Lin, W., Li, S., Zhang, S., Yu, X., 2016. Reduction in horizontal transfer of

527

conjugative plasmid by UV irradiation and low-level chlorination. Water Res. 91,

528

331-338. 24

ACCEPTED MANUSCRIPT Liu, G., Tao, Y., Zhang, Y., Lut, M., Knibbe, W.J., van der Wielen, P., Liu, W.,

530

Medema, G., van der Meer, W., 2017. Hotspots for selected metal elements and

531

microbes accumulation and the corresponding water quality deterioration potential

532

in an unchlorinated drinking water distribution system. Water Res. 124, 435-445.

533

Liu, H., Schonberger, K.D., Peng, C.Y., Ferquson, J.F., Desormeaux, E., Meyerhofer,

534

P., Luckenbach, H., Korshin, G.V., 2013. Effects of blending of desalinated and

535

conventionally treated surface water on iron corrosion and its release from

536

corroding surfaces and pre-existing scales. Water Res. 47, 3817-3826.

M AN U

SC

RI PT

529

537

Liu, S., Gunawan, C., Barraud, N., Rice, S.A., Harry, E.J., Amal, R., 2016.

538

Understanding, monitoring, and controlling biofilm growth in drinking water

539

distribution systems. Eviron. Sci. Technol. 50, 8954-8976.

Rai, A.K., Sanjukta, S., Chourasia, R., Bhat, I., Bhardwaj, P.K., Sahoo, D., 2017.

541

Production of bioactive hydrolysate using protease, β-glucosidase and α–amylase

542

of Bacillus spp., isolated from Kinema. Bioresource Technol. 235, 358-365.

TE D

540

Tandukar, M., Oh, S., Tezel, U., Konstantinidis, K.T., Pavlostathis, S.G., 2013.

544

Long-term exposure to benzalkonium chloride disinfectants results in change of

546

AC C

545

EP

543

microbial community structure and increased antimicrobial resistance. Environ. Sci. Technol. 47, 9730-9738.

547

Wang, H., Edwards, M.A., Falkinham, III, J.O., Pruden, A., 2013. Probiotic approach

548

to pathogen control in premise plumbing systems? A review. Environ. Sci. Technol.

549

47, 10117-10128.

550

Wang, H., Masters, S., Edwards, M.A., Falkinham III, J.O., Pruden, A., 2014. Effect 25

ACCEPTED MANUSCRIPT 551

of disinfectant, water age, and pipe materials on bacterial and eukaryotic

552

community structure in drinking water biofilm. Environ. Sci. Technol. 48,

553

1426-1435. Wang, H.B., Hu, C., Liu, L.Z., Xing, X.C., 2017. Interaction of ciprofloxacin

555

chlorination products with bacteria in drinking water distribution systems. J.

556

Hazard. Mater. 339, 174-181.

RI PT

554

Weathers, T.S., Higgins, C.P., Sharp, J.O., 2015. Enhanced biofilm production by a

558

toluene-degrading Rhodococcus observed after exposure to perfluoroalkyl acids.

559

Environ. Sci. Technol. 49, 5458-5466.

M AN U

SC

557

Wen, Q., Yang, L., Zhao, Y., Huang, L., Chen, Z., 2018. Insight into effects of

561

antibiotics on reactor performance and evolutions of antibiotic resistance genes and

562

microbial community in a membrane reactor. Chemosphere, 197, 420-429.

TE D

560

Wu, Y., Cui, E., Zuo, Y., Cheng, W., Rensing, C., Chen, H., 2016. Influence of

564

two-phase anaerobic digestion on fate of selected antibiotic resistance genes and

565

class I integrons in municipal wastewater sludge. Bioresource Technol. 211,

566

414-421.

AC C

EP

563

567

Xue, Z., Sendamangalam, V.R., Gruden, C.L., Seo, Y., 2012. Multiple roles of

568

extracellular polymeric substances on resistance of biofilm and detached clusters.

569 570 571 572

Environ. Sci. Technol. 46, 13212-13219.

Xue, Z., Seo, Y., 2013. Impact of chlorine disinfection on redistribution of cell clusters from biofilms. Eviron. Sci. Technol. 47, 1365-1376. Ye, Z., Weinberg, H.S., 2007. Trace analysis of trimethoprim and sulfonamide, 26

ACCEPTED MANUSCRIPT 573

macrolide, quinolone, and tetracycline antibiotics in chlorinated drinking water

574

using liquid chromatography electrospray tandem mass spectrometry. Anal. Chem.

575

79, 1135-1144. Yin, C., Meng, F., Chen, G.H., 2015. Spectroscopic characterization of extracellular

577

polymeric substances from a mixed culture dominated by ammonia-oxidizing

578

bacteria. Water Res. 68, 740-749.

RI PT

576

You, G., Hou, J., Xu, Y., Wang, C., Wang, P., Miao, L., Ao, Y., Li, Y., Lv, B., 2015.

580

Effects of CeO2 nanoparticles on production and physicochemical characteristics of

581

extracellular polymeric substances in biofilms in sequencing batch biofilm reactor.

582

Bioresource Technol. 194, 91-98.

M AN U

SC

579

Zhang, W., Cao, B., Wang, D., Ma, T., Xia, H., Yu, D., 2016. Influence of wastewater

584

sludge treatment using combined peroxyacetic acid oxidation and inorganic

585

coagulants re-flocculation on characteristics of extracellular polymeric substances

586

(EPS). Water Res. 88, 728-739.

TE D

583

Zhang, J., Li, W., Chen, J., Qi, W., Wang, F., Zhou, Y., 2018. Impact of biofilm

588

formation and detachment on the transmission of bacteriral antibiotic resistance in

AC C

589

EP

587

drinking water distribution systems. Chemosphere, 203, 368-380.

590

Zhang, Q.Q., Ying, G.G., Pan, C.G., Liu, Y.S., Zhao, J.L., 2015. Comprehensive

591

evaluation of antibiotics emission and fate in the river basins of China: source

592

analysis, multimedia modeling, and linkage to bacterial resistance. Environ. Sci.

593

Technol. 49, 6772-6782.

594

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Table Captions

3

Table 1. The relative content of each secondary structure in amide I region of EPS

4

proteins from biofilm bacterial communities in different drinking water distribution

5

systems (%).

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2

6

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1

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11

Table 1. The relative content of each secondary structure in amide I region of EPS

13

proteins from biofilm bacterial communities in different drinking water distribution

14

systems (%). protein secondary

SC

12

Raw

Two

Sulfadiazine Ciprofloxacin water

aggregated strands

7.28

9.64

8.16

5.72

β-sheet

20.3

25.6

22.1

27.6

random coil

26.7

21.5

16.6

23.6

α-helix

29.1

26.9

35.5

27.7

3-turn helix

10.8

12.4

12.8

9.13

5.74

4.03

4.87

6.22

17 18 19 20

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16

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antiparallel β-sheet 15

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2

antibiotics

ACCEPTED MANUSCRIPT 1

Figure Captions

3

Fig. 1. The gene copy numbers of 16S rRNA for total bacteria (a) and the antibiotic

4

resistance genes (b) in biofilm of different drinking water distribution systems. Error

5

bars represent the standard deviation from the average of three replications.

6

Fig. 2. The relative abundance of main bacterial genera in biofilm of different

7

drinking water distribution systems. Other bacterial genera, relative abundance of

8

which was lower than 1% in all the samples, were not shown.

9

Fig. 3. The enzymatic activities of protease and dehydrogenase in biofilm of different

10

drinking water distribution systems. Error bars represent the standard deviation from

11

the average of three replications.

12

Fig. 4. The proteins concentration in EPS from biofilm bacterial community of

13

different drinking water distribution systems. Error bars represent the standard

14

deviation from the average of three replications.

15

Fig. 5. The FTIR spectra of EPS from biofilm bacterial community in different

16

drinking water distribution systems (a), and the secondary structures and curve-fitted

17

amide I region (1700-1600 cm-1) of EPS in biofilm of DWDSs with raw water (b).

SC

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18

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2

1

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12

(a)

10

6 4 2 0

e cin iotics water diazin floxa antib Raw Sulfa Cipro Two

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8

5 4

2 1

mexA int1

sul1

sul2

sul3 qnrB qnrS

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0

Raw water Sulfadiazine Ciprofloxacin Two antibiotics

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3

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(b)

6

-2

Log (gene copies cm biofilm)

20

21

16S rRNA

SC

log (gene copies cm-2 biofilm)

19

22

Fig. 1. The gene copy numbers of 16S rRNA for total bacteria (a) and the antibiotic

23

resistance genes (b) in biofilm of different drinking water distribution systems. Error

24

bars represent the standard deviation from the average of three replications.

25

2

ACCEPTED MANUSCRIPT 26 27 28

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29 30

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31

60

Rhizobacter Parvularcula Rhodobacter Sphingomonas Bdellovibrio Bosea Methylobacterium Sphingopyxis Hyphomicrobium

50

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Relative abundance (%)

70

40 30 20 10 0

32

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water azine xacin iotics Raw SulfadiCiproflTowo antib

Fig. 2. The relative abundance of main bacterial genera in biofilm of different

34

drinking water distribution systems. Other bacterial genera, relative abundance of

35

which was lower than 1% in all the samples, were not shown.

AC C

36

EP

33

3

ACCEPTED MANUSCRIPT 37 38 39

RI PT

40 41

-1

30 20 10 0

Protease

Dehydrogenase

TE D

43

40

SC

50

M AN U

Raw water Sulfadiazine Ciprofloxacin Two antibiotics

60

-2

Enzymatic activity (µg h cm biofilm)

42

Fig. 3. The enzymatic activities of protease and dehydrogenase in biofilm of different

45

drinking water distribution systems. Error bars represent the standard deviation from

46

the average of three replications.

AC C

47

EP

44

4

ACCEPTED MANUSCRIPT 48 49 50

RI PT

51 52

150 100 50

e cin iotics water diazin floxa antib Raw Sulfa Cipro Two

TE D

0

53

SC

200

M AN U

-2

Proteins (µg cm biofilm)

250

Fig. 4. The proteins concentration in EPS from biofilm bacterial community of

55

different drinking water distribution systems. Error bars represent the standard

56

deviation from the average of three replications.

AC C

57

EP

54

5

ACCEPTED MANUSCRIPT 58 59

(a) 1049

2972

1628 1410 1248 1452 1654

1076

RI PT

2897

Absorbance

Two antibiotics Sulfadiazine Ciprofloxacin

1000

1500

2000

2500

60

0.030

(b)

0.015 0.010 0.005

TE D

Absorbance

0.025 0.020

3000

M AN U

Wavenumber (cm-1)

SC

Raw water

raw data aggregated strands β-sheet random coil α-helix 3-turn helix antiparallel β-sheet

EP

0.000

1600 1620 1640 1660 1680 1700 1720 -1

61

AC C

Wavenumber (cm )

62

Fig. 5. The FTIR spectra of EPS from biofilm bacterial community in different

63

drinking water distribution systems (a), and the secondary structures and curve-fitted

64

amide I region (1700-1600 cm-1) of EPS in biofilm of DWDSs with raw water (b).

65

6

ACCEPTED MANUSCRIPT Highlights
Response of biofilm to sulfadiazine and ciprofloxacin in DWDSs was studied.
Bacterial community shift and total bacteria increase related to ARGs promotion.

RI PT


The bacteria exhibited higher enzymatic activity and produced more EPS.
The higher contents of proteins and β-sheet in EPS promoted biofilm formation.

AC C

EP

TE D

M AN U

SC


Sulfadiazine and ciprofloxacin exhibited stronger combined effects on biofilm.