Antimicrobial Resistance in Wastewater Treatment Processes E-Book

Antimicrobial Resistance in Wastewater Treatment Processes

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Library of Congress Cataloguing‐in‐Publication Data

Names: Keen, Patricia L., editor. | Fugère, Raphaël, editor.Title: Antimicrobial resistance in wastewater treatment processes / [edited] by Patricia L. Keen, Raphaël Fugère.Other titles: Complemented by (work): Antimicrobial resistance in the environment.Description: Hoboken, NJ : Wiley, 2018. | Designed as a companion volume to Antimicrobial resistance in the environment / edited by Patricia L. Keen, Mark H.M.M. Montforts. c2012. | Includes bibliographical references and index. |Identifiers: LCCN 2017030445 (print) | LCCN 2017034382 (ebook) | ISBN 9781119192442 (pdf) | ISBN 9781119192459 (epub) | ISBN 9781119192435 (cloth)Subjects: | MESH: Drug Resistance, Microbial | Water Purification | Anti‐Bacterial Agents–analysis | Water Pollutants | Water MicrobiologyClassification: LCC TD196.D78 (ebook) | LCC TD196.D78 (print) | NLM QW 45 | DDC 572.8/44–dc23LC record available at https://lccn.loc.gov/2017030445

Cover design: WileyCover image: ‘Quick Sands’ 2014 © Philippe Raphanel

The editors dedicate this book to the memory of Fred Koch.

List of Contributors

Diana S. AgaDepartment of ChemistryUniversity at Buffalo, State University of New YorkBuffaloUSA

Denisse ArchundiaUniversity Grenoble Alpes, IRD, CNRSIGE, Grenoble, France;Consejo Nacional de Ciencia y Tecnologia (CONACYT)México, D.F., Mexico;ERNO, Instituto de GeologiaHermosillo, SonMexico

Fernando BaqueroDepartamento de MicrobiologíaHospital Universitario Ramón y CajalInstituto Ramón y Cajal de Investigación Sanitaria (IRYCIS)MadridSpain

Thomas U. BerendonkInstitute for HydrobiologyTechnische Universität DresdenDresden, Germany

Melanie BroszatDivision of Infectious DiseasesUniversity Medical Centre FreiburgFreiburgGermany

Irene BuenoCollege of Veterinary MedicineUniversity of MinnesotaSt. PaulUSA

Simon D. CostanzoUniversity of MarylandCenter for Environmental ScienceCambridgeUSA

Eddie CytrynInstitute of Soil, Water, and Environmental SciencesAgricultural Research Organization, Volcani CenterRishon LezionIsrael

Julian DaviesDepartment of Microbiology and ImmunologyUniversity of British ColumbiaVancouverCanada

Thi Thuy DoAntimicrobial Resistance and Microbiome Research GroupDepartment of BiologyNational University of Ireland MaynoothCounty KildareIreland

Erica DonnerFuture Industries InstituteUniversity of South AustraliaMawson LakesAustralia

Lisa M. DursoAgroecosystem Management Research UnitAgricultural Research ServiceU.S. Department of AgricultureLincoln, NebraskaUSA

Celine DuwigUniversity Grenoble AlpesIRD, CNRS, IGEGrenobleFrance

Despo Fatta‐KassinosDepartment of Civil and Environmental Engineering andNireas International Water Research CentreSchool of EngineeringUniversity of CyprusNicosiaCyprus

Gabriela FloresUniversity Grenoble Alpes, IRD, CNRS, IGE, Grenoble, France;MMAyA, Ministerio de Medio Ambiente y Agua (Ministry of Water and Environment of Bolivia)La PazBolivia

Raphaël FugèreRaphaël Fugère and AssociatesLévis, QuébecCanada

Charles P. GerbaUniversity of ArizonaDepartment of Soil, Water, and Environmental ScienceTucsonUSA

Elisabeth GrohmannDivision of Infectious DiseasesUniversity Medical Centre FreiburgFreiburgGermany

Judith Isaac‐RentonUniversity of British ColumbiaVancouverCanada

Popi KaraoliaDepartment of Civil and Environmental Engineering andNireas International Water Research CentreSchool of EngineeringUniversity of CyprusNicosiaCyprus

Antti KarkmanUniversity of GothenburgGöteborgSweden

Patricia L. KeenDepartment of Civil EngineeringUniversity of British ColumbiaVancouverNew York Institute of TechnologyVancouverCanada

Frederic LehembreUniversity Grenoble Alpes, IRD, CNRS, IGEGrenobleFrance

Agnes V. MacDonaldDepartment of SociologySimon Fraser UniversityBurnaby, British ColumbiaCanada

Roberto B. M. MaranoInstitute of Soil, Water, and Environmental SciencesAgricultural Research Organization, Volcani CenterRishon Lezion, IsraelDepartment of Agroecology and Plant HealthRobert H. Smith Faculty of Agriculture, Food, and EnvironmentThe Hebrew University of JerusalemRehovotIsrael

Jose Luis MartinezDepartamento de Biotecnología MicrobianaCentro Nacional de BiotecnologíaConsejo Superior de Investigaciones CientíficasMadridSpain

Jean M.F. MartinsUniversity Grenoble AlpesIRD, CNRS, IGEGrenobleFrance

Jean E. McLainUniversity of ArizonaWater Resources Research CenterDepartment of Soil, Water, and Environmental ScienceTucsonUSA

Stella MichaelDepartment of Civil and Environmental Engineering andNireas International Water Research CentreSchool of EngineeringUniversity of CyprusNicosiaCyprus

Mehrnoush MohammadaliDepartment of Civil EngineeringUniversity of British ColumbiaVancouverCanada

Marie‐Christine MorelUniversity Grenoble Alpes, IRD,CNRS, IGE, Grenoble, France;CNAM, Laboratoire d’analyses chimiques et bio analysesParisFrance

Rachel A. MullenDepartment of ChemistryUniversity at Buffalo, State University of New YorkBuffaloUSA

Sinéad MurphyAntimicrobial Resistance and Microbiome Research GroupDepartment of BiologyNational University of Ireland MaynoothCounty KildareIreland

Johanna MuurinenUniversity of HelsinkiHelsinkiFinland

David M. PatrickSchool of Population and Public HealthUniversity of British ColumbiaVancouverCanada

Marilyn C. RobertsDepartment of Environmental and Occupational Health SciencesSchool of Public HealthUniversity of WashingtonSeattleUSA

Channah M. RockUniversity of ArizonaDepartment of Soil, Water, and Environmental ScienceTucsonUSA

Amy Millmier SchmidtBiological Systems Engineering and Animal ScienceUniversity of NebraskaLincolnUSA

Randall S. SingerCollege of Veterinary MedicineUniversity of MinnesotaSt. PaulUSA

Randolph R. SinghDepartment of ChemistryUniversity at Buffalo, State University of New YorkBuffaloUSA

Sotirios VasileiadisFuture Industries InstituteUniversity of South AustraliaMawson LakesAustralia

Marko VirtaUniversity of HelsinkiHelsinkiFinland

Veiko VoolaidInstitute for HydrobiologyTechnische Universität DresdenDresdenGermany

Fiona WalshAntimicrobial Resistance and Microbiome Research GroupDepartment of BiologyNational University of Ireland MaynoothCounty KildareIreland

Andrew J. WatkinsonUniversity of QueenslandSt. LuciaAustralia

Jessica Williams‐NguyenDepartment of EpidemiologySchool of Public HealthUniversity of WashingtonSeattleUSA

Ying YangGuangdong Provincial Key Laboratory of Marine Resources and Coastal EngineeringSchool of Marine SciencesSun Yat‐sen UniversityGuangzhouChina

Tong ZhangEnvironmental Biotechnology LaboratoryDepartment of Civil EngineeringUniversity of Hong KongHong KongChina

Preface

Antimicrobial resistance is arguably the greatest threat to worldwide human health. This book evaluates the roles of human water use, treatment, and conservation in the development and spread of antimicrobial resistance.

The collection of wastewater dates back to the Roman Empire when sewage, surface runoff, and drainage water were received in the Cloaca Maxima and flushed into the Tiber River by water transported from a vast network of aqueducts. By the Middle Ages, several major urban centers developed throughout Europe that included systems of open ditches and wooden, lead, or clay pipes designed for the disposal of sewage. Rapid increases in population densities in major European cities since that time demanded considerable improvements in water distribution systems and wastewater management in order to protect the public health of citizens. However, it was not until the mid‐nineteenth century that many of these improvements were, in fact, realized. Canals dedicated to the transport of wastewater for direct discharge into rivers were constructed, although frequently, drinking water pumps were installed in close proximity to the wastewater removal systems. In essentially all situations, wastewater was ultimately returned to the environment in an untreated form.

Since 1850, the increased frequency of disease outbreaks, such as cholera and typhus, has required dedicated engineering efforts for the treatment of wastewater. Early examples of sewage treatment were simply the application of lime to cesspools, intended to reduce foul odors. During the same period, infectious disease epidemics were still believed to be transmitted through the human population by exposure to filth and foul smells and via person‐to‐person contact. While major advancements in the disciplines of sanitary engineering and health sciences were being made, it became increasingly clear that water played a critical role in the spread of infectious disease among the human population and that the safety of drinking water was compromised by any possibility of exposure to sewage. Water flushed waste through vast networks of ditches and underground sewers, then discharged in major rivers such as the Thames, the Seine, and the Danube. This rapid growth of urban centers was associated with persistent objectionable smells emanating from water courses that bisected large cities. This, in turn, reinforced political will to improve environmental conditions and led to pioneering technologies in sanitary engineering.

The engineering of technologies specific to the treatment of wastewater experienced a period of unprecedented growth beginning in the mid‐nineteenth century. Coincidentally, regulations intended to protect the environment from the impacts of discharge of sewage into receiving waters began to appear more frequently in many major urban centers throughout Europe (Cooper, 2001). The goal of wastewater treatment was to ensure that effluent was sufficiently free of disease‐causing entities that it could be released without impacting the safety of drinking water that was being employed for the human population. The secondary objective for improvement in wastewater treatment was driven by the economic incentive linked to the production of artificial guano (Cooper, 2001). Fertility of agricultural lands was declining to such an extent that crop yields were diminishing while the human population in urban centers was constantly growing. To counter this threat to food security, bird droppings were being imported from South America to the United Kingdom for use as agricultural fertilizer. Although land application of domestic waste had been practiced since Roman times, large areas of land adjacent to major urban centers were purchased and designated as “sewage farms.” These farms for the land treatment of sewage needed increasing allotments of valuable land. They were subject to a number of weather‐related complications and failed to achieve adequate hygiene standards that would ensure the protection of the health of farm workers and citizens at large. In this way, the intimate link between engineered systems for wastewater treatment, agricultural food production, and public health was firmly rooted throughout history.

Antimicrobial resistance in pathogenic organisms is a health risk that has been increasing for the last half century. Domestic sewage contains microbes originating from microbiomes of the human population resident in any community. Wastewater treatment plants receive influent composed largely by domestic sewage and therefore concentrate a vast and diverse collection of microbes in one location. Discharge of effluent from wastewater treatment plants represents the most important source of environmental contaminants, including those that are associated with development of antimicrobial resistance in bacteria.

For some time, antibiotic compounds have been identified as emerging contaminants and included in the category of pharmaceuticals and personal care products. Antibiotics can retain their activity after excretion from human patients such that bacterial communities in biological wastewater treatment systems are impacted by exposure to such contaminants and this antibiotic activity could potentially persist if their removal is incomplete following wastewater treatment. Improvements in instrumentation and tools for the analyses of genes in complex environmental samples have enhanced the ability to track mobile genetic elements of antimicrobial resistance through the wastewater treatment process. Increasing evidence is being gathered to suggest that the dynamic chemical, biological, and ecological conditions of operations in wastewater treatment processes influence the abundance of antimicrobial resistance genes in the effluents discharged to the environment after treatment. Because wastewater treatment plants receive sewage composed of contributions from gut flora of healthy and sick individuals, bacteria that are highly resistant to antibiotic therapy are increasingly detected in wastewater treatment systems.

More than 50% of the world’s populations live in cities. Developing nations are witnessing a trend of accelerated urbanization that, in some cases, is accompanied by increased health risks. Clean water, in terms of availability and safe quality, remains a key concern in urban centers. Urban water cycles are now recognized as subsystems where patterns of water use, wastewater treatment, and water reuse play major roles in protection of public health.

Designed as a companion volume to Antimicrobial Resistance in the Environment (Wiley‐Blackwell, 2012), this book is a multidisciplinary synthesis of topics related to antimicrobial resistance and wastewater treatment processes. Building on the increasing understanding of the central role of the environment in the development and spread of antimicrobial resistance, the book begins with five chapters that describe key issues from a more general perspective before focusing specifically on issues related to wastewater treatment processes. Detailed discussions concerning chemical analyses of antibiotics are included as well as comprehensive examinations of the features of experimental design that are particularly important in studies related to antimicrobial resistance. Advanced treatment strategies for mitigating the effects of factors that influence development and dissemination of antimicrobial resistance in the receiving environment are examined in detail. Several chapters discuss the ever‐growing improvements in metagenomics, molecular methods, culture‐based analyses, and gene sequencing capabilities, which are becoming popular for the examination of antimicrobial resistance in environmental samples, including those derived from wastewater.

We thank our fantastic team of contributing authors whom we are extremely pleased to regard as both our professional colleagues and our friends. Each chapter of this book has been crafted by some of the world’s leading authorities on the topic, in many cases together with early career researchers who continue to explore unanswered questions about risks linked to the development and spread of antimicrobial resistance. We thank the team at Wiley‐Blackwell led by Mindy Okura‐Marszycki and Kshitija Iyer for guiding us through the entire process of assembling this book from concept to completion. We extend our sincere gratitude to Philippe Raphanel for the use of the image from his wonderful painting on the cover of this book.

Patricia offers her thanks to colleagues from the Department of Civil Engineering at the University of British Columbia and also to her colleagues at the New York Institute of Technology, especially those individuals in the Energy Management Program at the Vancouver Campus, for their roles in making the development of this book a fun and rewarding experience. As well, she would like to express her sincere appreciation to Steve Clark for kindness, patience, and technical support throughout the book preparation process. Raphaël offers his thanks to René Fugère for his encouragement and support throughout all the phases that have led to the completion of this book. This book owes its existence to the inspiration of Julian Davies’ letter in Nature published in 2012. Patricia and Raphaël are deeply grateful to Julian for his willingness to share his inspiration, knowledge, friendship, and scholarly guidance, which have enabled us to complete this work.

Reference

Cooper PF (2001). Historical aspects of wastewater treatment. In:

Decentralised Sanitation and Reuse: Concepts, Systems and Implementation

, P Lens, G Zeeman, and G Lettinga (eds). IWA Publishing.

Préface

La résistance aux antibiotiques est probablement la plus grande menace à la santé humaine. Le présent livre traitera essentiellement des rôles que jouent le traitement, l'utilisation, et la conservation de l'eau dans le développement et la propagation de la résistance aux antibiotiques.

Le premier exemples documenté de collecte des eaux usées daterait de l'empire Romain, où les eaux usées et les eaux pluviales étaient dirigées vers le Cloaca Maxima (“Grand égout collecteur”) et rejetées dans le Tibre par un vaste réseau de conduites d'égout. Dès le Moyen Âge, l'Europe vit plusieurs centres urbains se développer, et ces derniers incluaient des systèmes de fossés, ainsi que des conduites de bois, plomb, ou argile, afin d'évacuer les eaux usées. La densification rapide des centres urbains européens à cette époque demanda des avancées majeures afin de protéger la santé publique. Malgré cela, ce n'est pas avant la mi‐19ème siècle que la plupart de ces avancées significatives furent réalisées. Des conduites dédiées à la canalisation des eaux usées vers les rivières environnantes furent mises en place, quoique des pompes d'eau potable furent installées à proximité immédiate des points de rejet. La stratégie universelle de gestion des eaux usées et pluviales demeurait le rejet direct au milieu naturel.

Depuis 1850, la fréquence accrue d'épidémies telles que le choléra et le typhus ont requis une ingénierie de systèmes de traitement des eaux usées. Ces mesures techniques étaient à l'origine assez sommaires, tel que le chaulage des fosses septiques afin d'atténuer les odeurs infectes qui s'en dégageaient. Au cours de la même période, la croyance populaire voulait que les épidémies étaient transmises via l'exposition à la “saleté”, les mauvaises odeurs et les contacts physiques entre individus. Avec les avancées majeures dans les domaines du génie sanitaire et médical, il devint clair que l'eau jouait un rôle critique dans la propagation des maladies infectieuses au sein des populations humaines, et que l'eau potable était corrompue par tout contact avec des eaux usées. À cette époque, les eaux usées étaient quand même acheminées vers des rivières ou fleuves d'importance tels que la Tamise, la Seine, ou le Danube. Les cours d'eau traversant les grandes villes devinrent synonymes d'odeurs nauséabondes. Ceci eut pour effet de mener à une amélioration des conditions environnementales et le développement de technologies de pointes en génie sanitaire.

Le domaine du génie sanitaire a connu une période de croissance sans précédent vers la mi‐19ème siècle. Conséquemment, la réglementation visant à protéger l'environnement de l'impact des rejets d'eaux usées dans les cours d'eau fit son apparition et se répandit à de nombreuses capitales européennes (Cooper, 2001). Le but visé par le traitement des eaux usées était de s'assurer que l'effluent était suffisamment exempt d'entités causant des maladies pour être rejeté sans impacter directement l'eau potable utilisée par la population. Le but secondaire du perfectionnement du traitement des eaux usées était essentiellement économique et relié à la production de guano artificiel (Cooper, 2001). À cette période, la fertilité des sols était en telle décroissance que les rendements agricoles étaient en forte baisse, alors que la population urbaine croissait sans cesse. Afin de combattre cette menace à la sécurité alimentaire, des excréments d'oiseau étaient importés d'Amérique du Sud vers la Grande‐Bretagne et étaient utilisés comme fertilisants agricoles. Malgré le fait que l'épandage d'eaux usées domestiques ait été pratiquée depuis l'époque romaine, de grandes superficies de terrain adjacentes aux centres urbains majeurs furent acquis et désignés comme “fermes de traitement des eaux usées”. Ces fermes visant à traiter les eaux usées vinrent à requérir de plus en plus de surface de terrain, ce qui mit leur opération en péril. De plus, elles étaient sujet à un grand nombre de complications reliées à la météo et n'atteignirent jamais des standards d'hygiène suffisants pour permettre la protection des travailleurs agricoles ou des citoyens. C'est ainsi que le lien intime entre les systèmes de traitement des eaux usées, la production agricole et la santé publiques se souda.

La résistance aux antibiotiques des organismes pathogènes est un risque sanitaire qui ne fait que croitre depuis un demi‐siècle. Les eaux usées domestiques contiennent des bactéries provenant des microbiomes de la population composant toute communauté urbaine. Les usines d'épuration des eaux usées reçoivent un affluent composé essentiellement d'eaux usées domestiques et se trouvent donc à concentrer une population microbienne vaste et diversifiée en un seul endroit. Les rejets des usines de traitement des eaux usées représentent donc une des plus importantes sources de contaminants environnementaux, incluant ceux qui sont associés avec le développement de la résistance aux antibiotiques chez les bactéries.

Il y a quelques années, les composés antibiotiques ont été identifiés comme contaminants émergents et incorporés à la catégorie des produits de soins personnels et pharmaceutiques. Même après excrétion par des patients, les antibiotiques peuvent préserver leur potentiel biochimique à un point tel qu'ils peuvent avoir un impact significatif sur la diversité microbienne des systèmes de traitement des eaux usées. Cette activité pourrait même persister dans l'environnement advenant une dégradation incomplète dans le système de traitement des eaux usées. Des avancées récentes au niveau de l'instrumentation et des outils d'analyse génétique dans des échantillons environnementaux complexes ont permis de retracer les marqueurs génétiques de la résistance aux antibiotiques tout au long de la chaîne de traitement des eaux usées. Il devient de plus en plus clair que les conditions chimiques, biologiques et écologiques d'opération des procédés de traitement des eaux usées affectent directement la quantité de gènes de résistance aux antibiotiques rejetés à l'environnement après traitement. Étant donné que les usines de traitement des eaux usées recueillent des eaux usées dont une partie provient autant de la flore intestinale de personnes malades que de la flore intestinale de personnes en santé, les bactéries résistantes aux antibiotiques sont de plus en plus détectées à l'affluent de systèmes de traitement des eaux usées.

Plus de cinquante pourcent de la population mondiale vit maintenant en zone urbaine. Les pays en voie de développement voient se développer une tendance d'urbanisation galopante, assortie de risques accrus à la santé publique. L'eau potable ‐ tant en quantité qu'en qualité ‐ demeure une préoccupation de premier plan au sein des centres urbains. Le cycle urbain de l'eau est maintenant reconnu comme tel, et il devient clair que l'utilisation de l'eau, le traitement des eaux usées et la réutilisation de l'eau jouent des rôles cruciaux dans la protection de la santé publique.

Conçu comme un complément au volume Antimicrobial Resistance in the Environment (Wiley‐Blackwell, 2012), ce livre est une synthèse multidisciplinaire de sujets touchant à la résistance aux antibiotiques et aux procédés de traitement des eaux usées. Se basant sur la compréhension grandissante du rôle central de l'environnement dans le développement et la propagation de la résistance aux antibiotiques, le livre débute avec cinq chapitres qui décrivent les points saillants d'un point de vue généraliste avant de se concentrer sur les enjeux ayant trait aux procédés de traitement des eaux usées. Des discussions détaillées des analyses chimiques sont présentées, tout comme l'examen en profondeur des particularités des protocoles expérimentaux qui sont particulièrement cruciaux dans le domaine de la résistance aux antibiotiques. Plusieurs procédés de traitement avancé visant à réduire le développement et la dispersion de la résistance aux antibiotiques dans l'environnement sont examinés en détail. Plusieurs chapitres discutent des améliorations dans les domaines de la métagénomique, des méthodes moléculaires, des analyses basées sur les cultures bactériennes et des méthodes de séquençage génétique qui deviennent de plus en plus populaires pour la détermination de la résistance aux antibiotiques dans des échantillons environnementaux, incluant des échantillons d'eaux usées.

Nous remercions notre incroyable équipe d'auteurs‐contributeurs que nous considérons comme des collègues professionnels et des amis. Chaque chapitre de ce livre a été rédigé par plusieurs références internationales sur le sujet, en collaboration avec des chercheurs en début de carrière, qui continuent à explorer les questions encore sans réponse des risques reliés au développement et à la propagation de la résistance aux antibiotiques. Nous remercions l'équipe à Wiley‐Blackwell, dirigée par Mindy Okura‐Marszycki and Kshitija Iyer, qui nous ont guidés tout au long du processus de rédaction, de l'idée conceptuelle jusqu'à la publication. Nous exprimons également notre profonde gratitude envers Philippe Raphanel qui nous a gracieusement permis d'utiliser une photographie d'une de ses peintures pour égayer la couverture du livre.

Patricia offre ses remerciements à ses collègues du département de génie civil à University of British Columbia, ainsi qu'à ses collègues du New York Institute of Technology, particulièrement aux membres du programme de gestion de l'énergie au campus de Vancouver pour avoir fait de la rédaction de ce livre une expérience agréable et enrichissante. Elle voudrait également exprimer sa profonde appréciation à Steve Clark pour sa gentillesse, sa patience et son support technique tout au long du projet. Raphaël remercie chaleureusement René Fugère pour son support indéfectible et ses encouragements tout au long de cette expérience. Le projet de livre a été inspiré par une lettre de Julian Davies dans le journal Nature, publiée en 2012. Patricia et Raphaël tenaient à exprimer leur sincère reconnaissance envers Julian pour son enthousiasme à partager son inspiration, ses connaissances, son amitié et rigueur académique.

Référence

Cooper PF (2001). Historical aspects of wastewater treatment. In:

Decentralised Sanitation and Reuse: Concepts, Systems and Implementation

, P Lens, G Zeeman, and G Lettinga (eds). IWA Publishing.

About the Cover Artist

Paris‐born Canadian painter Philippe Raphanel has a deeply held passion for the natural environment, which is reflected in nearly all of his work. As a member of the Young Romantics, a Vancouver‐based group of artists whose work in the mid‐1980s signaled a distinct shift in contemporary painting, Philippe refined a unique visual language that consistently references beauty in nature. Having spent much of his life on the west coast of Canada, his paintings are imbued with a similar reverence for sensuality in nature as that also captured in works by Emily Carr, Gordon Smith, and members of the Group of Seven. His work constantly explores the eternal bond between humans and the environment.

As an artist, Philippe is one of very few individuals whose formative years included a direct link to the realm of microbiology. As a young man in Paris, Philippe was close to long‐time family friends and well‐known microbiologists Germaine Stanier Cohen‐Bazire and Roger Stanier. Known for their pioneering research in ultrastructure and physiology of cyanobacteria, Germaine and Roger Stanier introduced Philippe to the natural beauty of the microbiological world during their time at the Pasteur Institute, and later they invited him to their summer home in British Columbia. That appreciation for nature at the cellular level and, of course, the friendship has lasted a lifetime.

Philippe has been recognized with multiple awards celebrating achievement in contemporary art throughout his career and he is currently a lecturer at the Emily Carr University of Arts and Design in Vancouver, BC. His paintings can be found in museums, public institutions, corporate collections, and private collections worldwide. We are very pleased that a segment of Philippe’s painting “Quick Sands” is presented on the cover of this book.

List of Abbreviations

ACs

antibiotic compounds

AOP

advanced oxidation process

AR

antibiotic/antimicrobial resistance

ARB

antibiotic/antimicrobial resistant bacteria

ARGs

antibiotic/antimicrobial resistance genes

BACI

before‐after‐control‐impact

BHR

broad host range

CAS

conventional activated sludge

CEC

contaminant of emerging concern

CFU

colony forming unit

CPO

carbapenamase‐producing organisms

DAGs

directed acyclic graphs

DGGE

denaturing gradient gel electrophoresis

DOC

dissolved organic carbon

DS

dissolved solids

dsDNA

double strand DNA

ESBL

extended‐spectrum beta‐lactamase

FTICR

Fourier transform ion cyclotron resonance

GC

gene cassette

GTA

gene transfer agent

HBP

human bacterial pathogen

HGT

horizontal gene transfer

HRMS

high‐resolution mass spectrometry

HRT

hydraulic retention time

HWW

hospital wastewater

Inc

plasmid incompatibility

IR

inverted repeat

IS

insertion sequence

LC

liquid chromatography

LCMS

liquid chromatography tandem mass spectrometry

LOD

limit of detection

LOQ

limit of quantification

MBR

membrane bioreactor

MDR

multidrug resistant

MECs

measured environmental concentrations

MGEs

mobile genetic elements

MIC

minimal inhibitory concentration

MLOQ

method limits of quantification

MLS

macrolides‐lincosamides and streptogramin

MPN

most probable number

MRM

multiple reaction monitoring

MRSA

methicillin resistant

Staphylococcus aureus

MS

mass spectrometry

MST

microbial source tracking

NOM

natural organic matter

NPS

nonpoint source

ORF

open reading frame

PCR

polymerase chain reaction

PECO

population; exposure; comparator; outcome

PECs

predicted environmental concentrations

PS

point source

QACs

quaternary ammonium compounds

QMRA

quantitative microbial risk assessment

qPCR

quantitative polymerase chain reaction

QqQ

triple quadrupole mass spectrometry

RIs

resistance integrons

ROS

reactive oxygen species

RCTs

randomized control trials

RWI

reclaimed water irrigated

SAT

soil aquifer treatment

SMX

sulfamethoxazole

SPE

solid phase extraction

SRT

solid retention time

SS

suspended solids

TIAC

total investigated antibiotic concentration

TMP

trimethoprim

ToF

MS time of flight mass spectrometry

TOC

total organic carbon

TPs

transformation products

TRACA

transposon‐aided capture

TWW

treated wastewater

UV

ultraviolet

UWWTP

urban wastewater treatment plant

VRE

vancomycin resistant enterococci

WW

wastewater

WWTP

wastewater treatment plant

1Antimicrobial Resistance Genes and Wastewater Treatment

Mehrnoush Mohammadali1 and Julian Davies2

1 Department of Civil Engineering, University of British Columbia, Vancouver, Canada

2 Department of Microbiology and Immunology, University of British Columbia, Vancouver, Canada

Since ancient times, humans have randomly disposed of waste into the environment, such as in rivers and cesspits. The industrial revolution of the late eighteenth and early ninteenth centuries was a period that saw increased disposal of toxic organic chemicals by direct release into the environment. Many of these toxic molecules had antimicrobial activity, and it can be assumed that microbes resistant to these toxins multiplied in such environments. As a modern example, one can cite the concentrations of heavy oils that were dumped near detection stations in the distant early warning line at the end of the Second World War. These sites are now excellent sources of bacteria with enhanced biodegradation capacities and have been extensively studied in recent years.

Following the discovery of the chemically synthesized sulphonamides and trimethoprim and the identification of dual resistance in 1969, the subsequent and most disastrous environmental pollution has come from the disposal of antibiotic production wastes in various forms. These discarded products were developed as food supplements for farm animals to promote weight gain in all aspects of animal and fish husbandry worldwide. The amounts of antibiotics and antibiotic wastes disposed in this way cannot be accurately identified. However, according to recent estimates by the Union of Concerned Scientists in the United States, antibiotic use for nontherapeutic purposes in three major livestock sectors (chickens, cattle, and swine) was about eight times more than the consumption for human medicine (Mellon et al., 2001).

In the past 50 years, we have seen the rapid evolution of a new plague—that of worldwide antibiotic resistance. Though not a disease in itself, antimicrobial resistance (AR) results in the failure to effectively prevent and treat many diseases, leading to widespread untreatable microbial infections and greatly increased morbidity and mortality: a plague of resistance genes (Davies and Davies, 2010). The global use of antibiotics at low cost, auto medication, and short duration of treatment has accelerated, extended, and expanded the spectra of resistance worldwide. The earth has been continuously bathed in a dilute solution of antibiotics for more than half a century.

Aquatic ecosystems have been identified as hotspots of resistance mechanisms (Rizzo et al., 2013). This is due to the large diversity of pathogenic and commensal microorganisms and the continuous discharge of antibiotic resistant bacteria (ARB) and antibiotic resistance genes (ARGs) into these environments. As part of aquatic ecosystems, urban wastewater treatment systems (collecting sanitary sewage, hospital effluents, and storm water runoff) possess all the components required to ensure the acquisition of all varieties of resistance genes. The antimicrobials present in wastewater due to incomplete degradation by humans and animals, disposal of unused drugs, and runoff losses from land application, together with environmental and pathogenic bacteria in nutrient‐rich engineered systems, provide all the necessary requirements to support a breeding ground for horizontal gene transfer and the propagation of resistance genes (Davies and Davies, 2010; Ferreira da Silva et al., 2006; Kim and Aga, 2007; Lefkowitz and Duran, 2009).

Since 1890 with the building of the first biological wastewater treatment plant (WWTP) in Worcester, Massachusetts, advances in wastewater treatment technology have been improving the efficient removal of biodegradable organic pollutants. Currently, enhanced biological phosphorus removal processes have not only enabled the removal of traditional carbonaceous contaminants but also reduced phosphorus concentrations to very low levels (<0.1 mg/L) in the effluent discharge (Zuthi et al., 2013).

Over the past 15 years, increasing attention has shifted toward the identification and removal mechanisms of micropollutants from wastewater and sludge. Micropollutants are persistent organic or mineral substances such as pharmaceuticals and personal care products, detergents, and pesticides whose discharge, even at very low concentrations, is a constant growing environmental contamination (Luo et al., 2014).

Despite the evolution of wastewater treatment technologies from conventional to advanced treatment configurations, existing urban biological wastewater treatment systems are not designed to remove micropollutants and ARGs. Studies on antibiotics as emerging classes of micropollutants have confirmed the high frequency of antimicrobial resistant genotypes as well as ARB in wastewater treatment systems, including constructed wetlands and WWTPs (Martins da Costa et al., 2006; Kim et al., 2010; Volkmann et al., 2004; Luczkiewicz et al., 2010; Reinthaler et al., 2003).

In a landmark series of papers published between 2003 and 2009, Szczepanowski and colleagues presented the first extensive DNA sequence–based screening of a large set of known ARGs in samples of activated sludge and the final effluent of a WWTP in Bielefeld‐Heepen, Germany. This comprehensive survey identified 140 different clinically relevant antimicrobial resistant genotypes and contaminants. From these investigations, it is evident that such treatment systems may play important roles in the development and assortment of multidrug‐resistant (MDR) bacteria among complex populations.

The occurrence of ARB and ARGs in the two main by‐products of wastewater treatment systems (biosolids and effluent discharge) has been reported frequently. Currently, effluent water quality standards, prior to discharge, are limited to controlling the concentrations of carbonaceous biochemical oxygen‐demanding matter, suspended solids, total residual chlorine and un‐ionized ammonia. There exist no regulatory guidelines to monitor and control the levels of ARGs in bacteria and extracellular DNA from lysed microbial cells in the effluent discharge. Accordingly, studies have reported that antibiotic resistance determinants and MDR pathogens are transported from the effluent to the receiving water (Iwane et al., 2001; Galvin et al., 2010; Goñi‐Urriza et al., 2000). For example, LaPara et al. (2011) showed that the quantities of three tetracycline resistance genes were significantly higher in a tertiary treated effluent discharge than in receiving water samples in the St. Louis River, Duluth‐Superior Harbor, and Lake Superior, USA.

Despite the evidence for the occurrence of resistance genes in effluent discharge points, the overall impact of treated wastewater applications on irrigation processes is unclear. Some studies have observed an increase in soil microbial activity and biomass after irrigation by treated wastewater as shown by a shift in the composition of soil bacterial communities (Oved et al., 2001; Broszat et al., 2014). However, recent studies have observed no significant impact on AR in the wastewater‐irrigated soil microbiome (Gatica and Cytryn, 2013; Negreanu et al., 2012).

The presence of ARB and ARGs in biosolids‐amended soils is well documented (Brooks et al., 2006; Rahube et al., 2014). Biosolids are the treated and stabilized nutrient‐rich organic residuals produced as a by‐product of wastewater treatment and widely used as fertilizer to stimulate plant growth (Lu and Stoffella, 2012). Recent studies have demonstrated that complementary technologies such as aerobic digestion and lime stabilization can be used as approaches to reduce the quantities of ARGs in biosolids (Munir et al., 2011). However, ARG concentrations and corresponding decay rates can be variable depending on the application methods, biosolids treatment reactor design, storage conditions, the specific ARGs involved, and the frequency of biosolids application (Burch et al., 2013; Miller et al., 2014).