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Sludge as a potential important source of antibiotic resistance genes in both the bacterial and bacteriophage fractions William Calero-Caceres, Anna Melgarejo, Claudia Stoll, Marta Colomer Lluch, Francisco Lucena Gutierrez, Juan Jofre , and Maite Muniesa Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/es501851s • Publication Date (Web): 29 May 2014 Downloaded from http://pubs.acs.org on June 6, 2014
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Sludge as a potential important source of
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antibiotic resistance genes in both the
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bacterial and bacteriophage fractions
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William Calero-Cáceres,† Ana Melgarejo,† Marta Colomer-Lluch,† Claudia Stoll,
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Francisco Lucena,† Juan Jofre,† and Maite Muniesa, †,*
‡
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†
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E-08028 Barcelona. Spain
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‡
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Department of Microbiology. University of Barcelona. Diagonal 643. Annex. Floor 0.
DVGW-Technologiezentrum Wasser (TZW), Karlsruher Street 84, D-76139 Karlsruhe,
Germany.
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*corresponding author
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Maite Muniesa
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Phone: +34934039386
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Fax: +34934039047
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e-mail:
[email protected] 17 18
Keywords: sludges, antibiotic resistance, bacteriophages, beta-lactamase, sulfonamides
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Author Contributions
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The manuscript was written through contributions of all authors. All authors have given
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approval to the final version of the manuscript.
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ABSTRACT
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The emergence and prevalence of antibiotic resistance genes (ARGs) in the
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environment is a serious global health concern. ARGs found in bacteria can become
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mobilized in bacteriophage particles in the environment. Sludge derived from secondary
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treatment in wastewater treatment plants (WWTPs) constitutes a concentrated pool of
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bacteria and phages that are removed during the treatment process. This study evaluates
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the prevalence of ARGs in the bacterial and phage fractions of anaerobic digested
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sludge; five ARGs (blaTEM, blaCTX-M, qnrA, qnrS and sul1) are quantified by qPCR.
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Comparison between the wastewater and sludge revealed a shift in the prevalence of
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ARGs (blaTEM and sul1 became more prevalent in sludge), suggesting there is a change
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in the bacterial and phage populations from wastewater to those selected during the
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secondary treatment and the later anaerobic mesophilic digestion of the sludge. ARGs
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densities were higher in the bacterial than in the phage fraction, with high densities in
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both fractions; particularly for blaTEM and sul1 (5 and 8 log10 gene copies (GC)/g
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respectively in bacterial DNA; 5.5 and 4.4 log10 GC/g respectively in phage DNA).
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These results question the potential agricultural uses of treated sludge, as it could
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contribute to the spread of ARGs in the environment and have an impact on the
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bacterial communities of the receiving ecosystem.
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INTRODUCTION
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Microorganisms that cause infections are becoming resistant to the most common
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antibiotic treatments. Thus, antibiotic resistance has become a serious and growing
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problem in contemporary medicine and has emerged as one of the primary public health
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concerns of the 21st century.1,2 An estimated 25,000 people die every year in Europe
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directly from antibiotic-resistant bacterial infections, while many more die from other
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conditions that are complicated by an antibiotic-resistant infection.3
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Antibiotic resistance occurs as a natural phenomenon but can be enhanced by human
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activities; in medicine, the major causes of such enhancement are incorrect diagnosis,
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and inappropriate prescription of antibiotics or their improper use by patients. The
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spread of antibiotic resistance can also be attributed to certain practices in the
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pharmaceutical industry or to the non-therapeutic use of antibiotics in animals intended
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for human consumption.
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Despite the urgent need for a global system to monitor antibiotic resistance and the
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health and economic burden it causes, information concerning the expansion of
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resistance in the environment is still remarkably limited. Different environments (bodies
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of water or soils) are suitable locations for the emergence of new bacterial resistance,
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including those that can cause infection in both humans and animals.4,5 Several studies
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suggest that antibiotic resistance occurs in nature and has an ancient origin which is not
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always linked to the use of antibiotics. However, the presence of antibiotics in the
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environment, even at subinhibitory concentrations, could have favoured the selection of
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some types of resistance,6 as well as the dissemination of resistant clones.
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In addition, aquatic environments (including surface water and groundwater) provide
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ideal settings for the horizontal exchange of mobile genetic elements (MGEs) that
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encode antibiotic resistance.7-9 The elements that mobilize antibiotic resistance genes
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(ARGs) can be insertion sequences, transposons, intragenic chromosomal elements,
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plasmids, pathogenicity islands, chromosome cassettes or, as recently reported,
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bacteriophage particles.10-12
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The horizontal transfer occurring anywhere at random and the assembly of genetically
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mobile platforms is more likely to occur in environments where there is a selective
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pressure, such as human and animal biomes or wastewater,13,14 where phages and
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bacteria are abundant but there is antibiotic exposure. Wastewater treatment plants
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(WWTPs) are therefore a plentiful source of ARGs from which they spread into the
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environment.11,15-17 Activated sludge derived from secondary treatment at WWTPs
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represents a concentrated pool of bacteria, and phages that infect these bacteria, which
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have been removed during the treatment process. A common treatment of activated
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sludge includes anaerobic digestion; this further transforms organic matter into biogas,
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reduces the final amount of sludge solids for disposal and destroys most of the
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pathogens present in the sludge.18,19 The mechanisms by which biological processes in
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WWTPs influence the development/selection of resistant bacteria and ARGs transfer are
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still poorly understood. The potential agricultural use of WWTP sludge may result not
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only in the transfer of resistant bacteria into the environment, but also in the
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dissemination of ARGs.
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To gain insight into these questions, the present study evaluates the abundance of five
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ARGs in the bacterial and bacteriophage DNA fractions of sludge obtained following
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anaerobic digestion in an urban WWTP.
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MATERIALS AND METHODS
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Samples.- Thirty raw urban wastewater samples were collected weekly between autumn
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2012 and spring 2013 from the influent of a WWTP in the Barcelona metropolitan area
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which serves approximately 500,000 people. The same plant was the source of 30
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wastewater sludge samples collected from the digestor. Sludge samples comprised a
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mixture of raw primary sludge (about two-thirds) and secondary sludge (about one-
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third) that was thickened and subjected to anaerobic mesophilic (35°C) digestion for 20-
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25 days. Dry weight of sludges was 25 % in average.
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All the samples were collected in sterile containers, transported to the laboratory at
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5ºC±2ºC within two hours of collection and processed immediately for bacterial counts
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and further experiments.
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Bacterial strains and media.- Escherichia coli strain C600 containing the pGEM
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vector with the blaTEM gene was used as a control for blaTEM. E. coli strains isolated
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from the urban wastewater during this study were used as controls for blaCTX-M genes
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carrying types CTX-M. The clinical E. coli strain 266 was used as a control for qnrA,
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the environmental Enterobacter cloacae strain 565 was used as a control for qnrS and
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E. coli J53 R38820 was used as a control for sul1. E. coli WG5 (ATCC 700078) was
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used as a host for the evaluation of somatic coliphages.21 5 Calero-Cáceres et al., 2014
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Luria-Bertani (LB) agar or broth were used for routine bacterial propagation to prepare
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the standards for qPCR assays. For the detection of heterotrophic bacteria, Tryptic Soy
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Agar (TSA) media or Chromocult® Coliform Agar (Merck, Darmstadt, Germany) were
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used. Media were supplemented with: 32 mg/L of ampicillin (AMP); 25 mg/L of
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nalidixic acid (NAL); or 350 mg/L of sulfamethoxazole (SUL), all from Sigma-Aldrich
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(Steinheim, Germany). These antibiotic concentrations were chosen based on previous
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studies that analyse environmental resistant bacteria.22,23
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Microbiological parameters.- The extent of faecal contamination in the wastewater
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and sludge samples was established by counting total heterotrophic bacteria and E. coli
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as bacterial indicators and somatic coliphages as viral indicators. The latter were
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included to indicate the levels of virulent bacteriophages in the samples.21 This method
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allows detection of many virulent infectious phages from a faecal sample with a single
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host strain (E. coli WG5) through the double agar layer plaque assay.
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For bacterial assays, serial decimal dilutions (1/100, 1/1000 and 1/10000) of the
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wastewater samples were filtered through 0.45-µm-pore-diameter membrane filters (47
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mm, white gridded, EZ-Pak® Membrane Filters, Millipore, Bedford, MA). The
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membranes were placed upside up on TSA for heterotrophic bacteria and Chromocult®
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Coliform Agar for E. coli, and incubated at 37ºC for 18 h. To evaluate somatic
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coliphages, serial decimal dilutions of the wastewater samples were filtered through low
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protein-binding 0.22-µm-pore-size membrane filters (Millex-GP, Millipore, Bedford,
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MA) and assayed by the double agar method, as described in the standard ISO
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methods.21 Samples were analysed in triplicate.
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For the analysis of microbiological parameters in sludge, 5 g of sludge sample was
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homogenized 1/10 (w:v) with sterile phosphate saline buffer (PBS) and suspended by
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magnetic stirring at room temperature for 30 min. This suspension was used to prepare
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10-fold dilutions as described in the US EPA standard procedures.24
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To evaluate the presence of bacteria resistant to antibiotics, samples were processed as
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described above and incubated in TSA or Chromocult® coliform agar for 2 hours at
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37ºC. The membranes were then transferred to TSA or Chromocult® coliform agar
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containing the respective antibiotics and incubated at 37ºC for a further 18 h.
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PCR procedures
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Standard PCR procedures.- Conventional PCRs were performed for ARGs (Table 1).
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All the PCRs were performed with a GeneAmp PCR system 2700 (Applied Biosystems,
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Barcelona, Spain). Five µL of each PCR product was analysed by agarose (0.8%) gel
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electrophoresis and bands were viewed using ethidium bromide staining. When the
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amplicons were used for cloning, PCR products were purified using a PCR Purification
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Kit (Qiagen Inc., Valencia, CA).
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qPCR procedures.- For the quantification of each ARG in phage DNA, TaqMan qPCR
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assays were performed using standards prepared as described in the next section.
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Conditions for each qPCR assay were as described previously.11,25 Limits of detection
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were calculated by performing 8-10 replicates of each dilution of the standard for each
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gene, in three independent qPCR reactions and by triplicate. We considered as limit of
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detection the higher threshold cycle (Ct) that showed positive amplification in all
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replicates. Calculating the gene copies (GC) for each Ct value, the limit of detection of
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each qPCR assay was 7.6 GC/µL for blaTEM, 8.4 gene copies GC/µL for blaCTX-M-1, 3.1
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GC/µL for qnrA and 8.3 gene copies GC/µL for qnrS.
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A new real-time qPCR assay for sul1 was developed to detect the most common
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sulphonamide resistance gene in the DNA of the bacterial and bacteriophage fractions
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of the samples.
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sul1 primers and a probe set were designed using the Primer Express 3.0 software
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(Applied Biosystems); primers and probes were selected to be used in a standardized
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TaqMan amplification protocol. Their specificity was determined via sequence
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alignments using 21 sequences of sul1 available in NCBI nucleotide database. A FAM-
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labelled fluorogenic probe was commercially synthesized by Applied Biosystems. The
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sul1 probe was minor-groove binding (MGB) with an FAM reporter (FAM: 6-
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carboxyfluorescein) and an NFQ quencher (non-fluorescent quencher). The sul1 qPCR
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assay showed a limit of detection of 5.9 GC/µL (a threshold cycle of 35).
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Preparation of standard curves.- For the generation of standards for all qPCR assays, a
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plasmid construct was used containing the insert of each ARG amplified by
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conventional PCR (Table 1). Each fragment was purified using Pure LINK Quick Gel
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Extraction and a PCR Purification Combo Kit (Invitrogen Carlsbad, CA) and was 8 Calero-Cáceres et al., 2014
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cloned in a pGEM-T Easy vector following the manufacturer’s instructions (pGEM®-T-
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Easy Vector, Promega, Barcelona, Spain). The construct was transformed by
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electroporation into E. coli DH5α electrocompetent cells. The cells were electroporated
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at 2.5 kV, 25 F capacitance and 200 Ω resistance in a BTX ECM 600 Electroporation
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System (Harvard Apparatus, Inc. Holliston, MA). Colonies containing the vector were
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screened by conventional PCR to evaluate the presence of the insert in the vector and its
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orientation, and the amplimers were sequenced. For sul1, plasmid R388 obtained from
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E. coli J53 was used. The vector containing the insert was purified from the positive
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colonies using the Qiagen Plasmid Midi purification kit (Qiagen Inc., Valencia, CA)
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and its concentration was quantified using a NanoDrop ND-1000 spectrophotometer
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(NanoDrop Technologies. Thermo Scientific. Wilmington. DE). The reaction product
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was linearized by digestion with XmnI restriction endonuclease (Promega Co., Madison,
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USA). The restricted product was purified and quantified for use in the qPCR assays.
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The GC/µL of the stock prepared for each gene was calculated and the standard curve
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for qPCR was calculated as described previously.11 Three replicates of each dilution
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were added to each qPCR reaction.
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All the qPCR assays were performed under standard conditions, as indicated by the
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manufacturer, in a Step One Real-Time PCR System (Applied Biosystems). The assays
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were tested for cross-reactions with the respective susceptible strains. They were
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amplified in a 20 µL reaction mixture with the TaqMan Environmental Real-Time PCR
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Master Mix 2.0 (Applied Biosystems). The reaction contained 9 µL of the DNA sample
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or quantified plasmid DNA. All the samples were assayed in duplicate, as were the 9 Calero-Cáceres et al., 2014
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standards, and positive and negative controls (described below). The GC was defined as
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the average of the duplicate data obtained.
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To screen for PCR inhibition, dilutions of the standard were spiked with environmental
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DNA and the experimental difference was compared to the true copies of the target
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genes in the standards. No inhibition of PCR by environmental DNA extracts was
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detected.
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Extraction of bacterial DNA
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To extract bacterial DNA from the wastewater samples, 50 mL of each sample was
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filtered through 0.45-µm-pore-diameter membrane filters (47 mm, white gridded, EZ-
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Pak® Membrane Filters (Millipore, Bedford, MA). The bacterial content of the
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membranes was suspended in Luria Bertani broth (LB). The samples were centrifuged
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at a 3000xg for 10 minutes. The pellet was suspended in 200 µL of LB and bacterial
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DNA was obtained using the QIAamp® DNA blood Mini Kit (Qiagen Inc., Valencia,
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CA) following the manufacturer’s instructions.
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For DNA extraction from sludge, 0.25 g of sample was processed using the PowerSoil®
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DNA isolation kit (MO BIO® Laboratories, Inc. Carlsbad, CA) following the
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manufacturer’s instructions.
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Purification of phage particles
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To purify the bacteriophage fraction of the water samples, a previous described method
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was used with minor modifications.11 Briefly, 50 mL of each sample was centrifuged at
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3000xg for 10 min, passed through low protein-binding 0.22-µm-pore-size membrane
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filters (Millex-GP, Millipore, Bedford, MA) and then 100-fold concentrated at 3000xg
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by means of protein concentrators (100 kDa Amicon Ultra centrifugal filter units,
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Millipore, Bedford, MA), following the manufacturer’s instructions.
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To purify the bacteriophage fractions from the sludge, the following two protocols were
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assayed.
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Organic flocculation based on the protocol proposed by the US EPA for elution of
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enteroviruses.24 Briefly, liquid raw sludge was conditioned by the addition of AlCl3 to a
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final concentration of 0.0005 mol/L, and thoroughly mixed by shaking and
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centrifugation. From this point on, the pellet was eluted with 10% beef extract and
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viruses were concentrated by organic flocculation according to Katzenelson et al. 26
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Homogenization, as described previously by Lasobras et al.,27 was performed here with
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minor modifications. The samples were mixed in a 1:10 (w/v) ratio with PBS pH=7.4
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and homogenized by magnetic stirring for 30 min at room temperature. The suspension
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was then centrifuged at 10,000xg for 30 min at 4°C. The supernatant was subsequently
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filtered through low protein-binding 0.22-µm-pore-size membrane filters (Millex-GP,
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Millipore, Bedford, MA) and then 100-fold concentrated at 3000xg by means of protein
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concentrators as described above.
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The concentrated phage fraction from wastewater and sludge samples was recovered
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and treated with chloroform to rule out the presence of possible vesicles containing
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DNA. DNase treatment (100 units/mL of the phage lysate) was performed to eliminate
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any free DNA that might be present in the samples outside the phage particles. After
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that, DNase was heat inactivated at 80ºC for 10 minutes.
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Controls
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Negative controls included controls of the DNA extraction with sterile water. In
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addition, to exclude non-packaged DNA, the protocol for DNA extraction from the
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phage fraction of the samples was always accompanied by several controls. To rule out
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the possibility of contamination with free DNA, an aliquot of the sample taken after
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DNase treatment and before desencapsidation was processed. At this stage, the samples
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were used as a template for conventional PCR of eubacterial 16S rDNA and for the
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qPCR assay of each ARG. Both amplifications should be negative to confirm that
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DNase has removed all non-packaged DNA from the samples.
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To verify the DNase treatment, the samples were spiked with serial decimal dilutions of
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the standards (DNA concentrations from 222-2.2x10-2 ng/µl, containing from 109-105
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GC/µl) and then treated with DNase followed by the heat inactivation of the enzyme
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and amplified.
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To confirm that the DNase was correctly inactivated by the heat treatment and that no
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degradation of the qPCR primers or probe occurred, the samples were spiked with serial
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decimal dilutions of the standard after the DNase heat inactivation and then amplified.
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Extraction of DNA from phage particles
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Phage DNA was extracted from the purified phage particles as previously described.11
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The concentration and purity of the extracted phage DNA were determined using the 12 Calero-Cáceres et al., 2014
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NanoDrop ND-1000 spectrophotometer (NanoDrop Technologies, Thermo Scientifics,
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Wilmington, DE).
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Sequencing.- The ARGs amplified from the strains used as controls and the amplimers
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used to prepare the qPCR standards were sequenced with an ABI PRISM Big Dye 3.1
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Terminator Cycle Sequencing Ready Reaction Kit (Applied Biosystems), following the
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manufacturer’s instructions and with the primers shown in Table 1. All sequences were
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performed at least in duplicate.
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Statistical analysis.- Data were compiled and statistical tests performed using the
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Statistical Package for Social Science software (SPSS). One-way analysis of variance
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(ANOVA) was used to evaluate the differences between the two methods used to
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extract phages from sludge and to compare the occurrence of ARGs detected in DNA
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from the bacterial and phage fractions. Evaluations were based on a 5% significance
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level in both cases: a P value of
