Next Article in Journal
Investigation of the Quality of the 12 Most-Used Antibiotics Available in Retail Private Pharmacies in Rwanda
Previous Article in Journal
Exploring the Antifungal Activity and Action of Saussurea costus Root Extracts against Candida albicans and Non-albicans Species
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Antibiotics
Volume 11
Issue 3
10.3390/antibiotics11030328
antibiotics-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Extraintestinal Pathogenic Escherichia coli: Beta-Lactam Antibiotic and Heavy Metal Resistance

by
Catia Longhi
1,*,
Linda Maurizi
1,
Antonietta Lucia Conte
1,
Massimiliano Marazzato
1,
Antonella Comanducci
1,
Mauro Nicoletti
2 and
Carlo Zagaglia
1
1
Dipartimento di Sanità Pubblica e Malattie Infettive, “Sapienza” Università di Roma, 00185 Rome, Italy
2
Dipartimento di Scienze Sperimentali e Cliniche, Università “G. D’Annunzio”, 66100 Chieti, Italy
*
Author to whom correspondence should be addressed.
Antibiotics 2022, 11(3), 328; https://doi.org/10.3390/antibiotics11030328
Submission received: 7 February 2022 / Revised: 25 February 2022 / Accepted: 26 February 2022 / Published: 1 March 2022
Versions Notes

Abstract

:
Multiple-antibiotic-resistant (MAR) extra-intestinal pathogenic Escherichia coli (ExPEC) represents one of the most frequent causes of human nosocomial and community-acquired infections, whose eradication is of major concern for clinicians. ExPECs may inhabit indefinitely as commensal the gut of humans and other animals; from the intestine, they may move to colonize other tissues, where they are responsible for a number of diseases, including recurrent and uncomplicated UTIs, sepsis and neonatal meningitis. In the pre-antibiotic era, heavy metals were largely used as chemotherapeutics and/or as antimicrobials in human and animal healthcare. As with antibiotics, the global incidence of heavy metal tolerance in commensal, as well as in ExPEC, has increased following the ban in several countries of antibiotics as promoters of animal growth. Furthermore, it is believed that extensive bacterial exposure to heavy metals present in soil and water might have favored the increase in heavy-metal-tolerant microorganisms. The isolation of ExPEC strains with combined resistance to both antibiotics and heavy metals has become quite common and, remarkably, it has been recently shown that heavy metal resistance genes may co-select antibiotic-resistance genes. Despite their clinical relevance, the mechanisms underlining the development and spread of heavy metal tolerance have not been fully elucidated. The aim of this review is to present data regarding the development and spread of resistance to first-line antibiotics, such as beta-lactams, as well as tolerance to heavy metals in ExPEC strains.

1. Introduction

Escherichia coli is a harmless normal inhabitant of the gut of humans and warm-blooded animals. However, several pathogenic E. coli variants (pathotypes) endowed with the ability to cause intestinal (intestinal pathogenic E. coli or IPEC) or systemic infections (extra-intestinal pathogenic E. coli or ExPEC) have been described [1,2]. ExPEC strains are recognized as the most common Gram-negative human pathogens, globally responsible for the deaths of more than two million humans/year. ExPEC infections include urinary tract infections (UTI), hospital-acquired pneumonia, sepsis, surgical site infection, cholecystitis, cholangitis, peritonitis cellulitis osteomyelitis and arthritis. Moreover, E. coli is the leading cause of neonatal meningitis [3]. In this context, uropathogenic E. coli (UPEC) strains are the primary causes of community-acquired UTIs worldwide, with an estimated 40% of women and 12% of men, over the age of 18, who have to face to at least one symptomatic UTI episode during their lifetime, and with 27-48% of women suffering from recurrent UTIs [4,5,6]. Moreover, it has been suggested that the intestine could be the reservoir of UPECs, from which they can move to infect the urinary tract of the carrier, as well as that of other hosts, by the fecal–oral route and/or by sexual intercourse. In the intestine, ExPECs may stay asymptomatic even for a long time, while, under particular circumstances, they may gain entry into extra-intestinal tissues or districts by the expression of specific virulence determinants that allow them to colonize susceptible hosts [1,2,7,8]. Conversely, commensal E. coli strains rarely cause disease, except in immune-compromised hosts or, as in the case of peritonitis, when they may passively reach the peritoneal cavity through breaches in the gastrointestinal barrier. E. coli being endowed with notable genome plasticity, it is believed that pathogenic E. coli may have originated from commensals by the acquisition of specific virulence traits and by the loss or inactivation of house-keeping genes whose expression would negatively interfere with the new pathogenic lifestyle [1]. At the end of such complex recombination events, pathogenic mutants able to colonize new environmental niches may arise and spread the infections to other hosts. Furthermore, the newly generated pathogens have to fight against the host’s innate immune response, which may eliminate them, or mutants able to evade the host immune response may be selected [1,8]. Despite their clinical relevance, crucial aspects of ExPEC virulence (e.g., characterization of their reservoirs, routes of transmission, the mechanisms driving the onset of antibiotic- and heavy-metal-resistant mutants) remain to be fully elucidated. Understanding of these points will be of decisive relevance in order to develop new effective strategies aimed at counteracting or at least to limit the insurgence and the spread of these powerful pathogens. ExPECs harbor a variety of virulence-associated factors, including adhesins, toxins, iron acquisition systems, lipopolysaccharides, polysaccharide capsules, mobile genetic elements and the ability to manipulate the host innate immune response. Nevertheless, screening of clinical isolates for the simple carriage of virulence genes does not ensure correct identification of E. coli pathotypes since virulence-associated factors, found in ExPEC, are often found among commensal E. coli strains [4,9]. Due to biochemical similarities, the identification of the different pathotypes is not an easy task considering that specific, straightforward identification protocols are not available yet. Consequently, the identification of the different pathotypes is mainly based on taking into account the source of isolation, the carriage and expression of specific virulence-associated genes, the phylogenetic background and, when possible, their behavior in the experimental infection of suitable cellular/animal models. The introduction of molecular techniques, such as multiplex-PCR technology, the multilocus sequence type (MLST) and, more recently, phylogenetic comparison, extended to the whole bacterial genome, have highly contributed to providing new insights about this matter. Given the clinical importance of ExPEC and their propensity for the emergence of pandemic strains worldwide, surveillance systems are carried out to trace and prevent the global diffusion of pandemic serotypes. To this end, a simple and versatile method is phylogenetic analysis, which allows the classification of E. coli isolates into the A, B1, B2, C, D, E, F, G and clade I phylogroups [10,11,12]. Using this approach, commensal E. coli strains are placed mainly in the A or B1 phylogroups, while ExPEC strains are in the B2 group and, to a lesser extent, in group D. Strains of group E are related to those of group D, while group F is related to the main group, B2. Clones of E. coli strains, which are genetically diverse but phenotypically indistinguishable, are assigned to cryptic clade I [13]. Strains belonging to the same group may vary in the carriage and expression of relevant characteristics, such as antibiotic-resistance and virulence-associated genes. Today, multilocus sequence type (MLST) analysis is the gold standard, used to identify ExPEC strains as well as to evaluate their evolutionary relationships among different lineages. The method is based on PCR amplification and sequencing of internal DNA fragments of seven well-known E. coli house-keeping genes [14]. Differences in the DNA sequence are determined by comparison with specific databases of alleles. The alleles found at each locus define the allelic profile or sequence type (ST) of each isolate. The application range of the MLST technique is vast and it provides important information that may be of interest, such as environmental ExPEC reservoirs, whose identification might help the microbiological and clinical community to prevent the future insurgence and spread of high-risk pandemic lineages within the community setting. In the last decade, the development of next-generation sequencing (NGS) techniques made the access to the whole-genome sequences (WGSs) of microorganisms fast and cost-effective. The huge amount of genomic data produced by NGS clearly determines the entire genomic content of a single microorganism, permitting us to delineate the whole gene repertoire carried by microbial taxa and to extend the genomic comparisons among strains to the whole-genome level. In this context, the classification of E. coli strains, based on WGS, gradually integrates the seven loci MLST-based ST-typing and related classification systems, allowing deeper knowledge of the origin, evolution and spread of these strains.
Despite the huge diversity of ExPEC STs, it has been recently reported that ExPEC ST12, ST69, ST73, ST95, ST127 and ST131 are the predominant lineages causing extraintestinal infections worldwide [15,16,17]. Among these lineages, it has been shown that ST69 is mainly associated with resistance to trimethoprim–sulfamethoxazole [18], while the UPEC pandemic ST131 lineage appears to be associated with fluoroquinolone resistance and with β-lactam resistance by extended-spectrum β-lactamase (ESBL) enzymes. In addition, it has been proposed that ST131 may have significantly contributed to the global dissemination of cephalosporin and fluoroquinolone resistance [19,20].
Conversely, the finding that ST95, ST73 and ST127 are fully antibiotic-susceptible indicated that factors other than antibiotic resistance might be responsible for the global distribution of these ST lineages. Infections due to multiple-antibiotic-resistant (MAR) pathogenic bacteria are steadily increasing worldwide, both in hospital and community settings, rendering always more difficult their control. Consequently, the number of therapy failures is also increasing, together with increased hospitalization, morbidity/mortality and societal costs. With respect to the recent past, this condition is worsened considering that we are in the so-called “post-antibiotic era”, when the discovery of new, effective antibacterial drugs is dramatically low. In this context, the scarcity of new, effective antibiotics, together with expanding antibiotic resistance, has renewed the interest of the scientific community in heavy metals as substitutes for antibiotics and as adjuvants for the efficacy of already existing ones [9].

2. Resistance to Antibiotics and Heavy Metals

2.1. Antibiotic Resistance

The mechanisms by which bacteria become antibiotic-resistant are diverse, complex and not completely understood. In this regard, commensal E. coli strains, especially those inhabiting the intestines of humans and warm-blooded animals, have been shown to play a pivotal role in the onset and diffusion of antibiotic-resistance genes [21,22]. The high intestinal bacterial density, together with antibiotic exposure, due to global indiscriminate and, in many cases, inappropriate use of antibiotics, have likely led to the selection and spread of antibiotic-resistance mutants among commensal E. coli strains, which are considered a primary reservoir of antibiotic-resistance genes. Moreover, the remarkable E. coli genome plasticity may have favored the acquisition of virulence-associated determinants that may be transmitted to bacteria of the same and/or of related species [8,23].
The results of epidemiological surveys indicate that 20–45% of ExPEC isolates were resistant to first-line antibiotics including beta-lactams, fluoroquinolones and trimethoprim–sulfamethoxazole [24,25,26,27], so that the management of patients suffering from MAR ExPEC infections has become more complicated.
The fluoroquinolones are a family of broad-spectrum antibiotics used since the late 1980s for the treatment of severe infections, especially UTIs, although long-term therapy with fluoroquinolones is linked to serious adverse effects. Consequently, the U.S. Food and Drug Administration recommends the restricted use of these antibiotics to UTIs untreatable with commonly used antibiotics. Nevertheless, fluoroquinolones continue to be widely prescribed in several countries [16,17,18,19,20] and the incidence of resistant E. coli is continuously increasing. To resist to the action of fluoroquinolones (the inhibition of topoisomerase enzymes, DNA gyrase and topoisomerase IV), E. coli may become resistant by mutations that alter the target enzymes, by reducing the entrance of the antibiotic into the cell or by activating efflux systems, which extrude the drug from the cell. Aminoglycosides are a family of bactericidal broad-spectrum antibiotics that may also act in synergy with other antibiotics. Despite the adverse side effects due to the prolonged use of these antibiotics, several members of this family were intensively used in the past, until they were replaced in the 1980s with cephalosporins, carbapenems and fluoroquinolones. The mechanism of action of aminoglycosides targets the binding to the aminoacyl-tRNA recognition site (A-site) of the 16S rRNA of 30S ribosome, leading to the inhibition of polypeptide synthesis and subsequent cell death. Resistance to aminoglycosides may occur based on several mechanisms, namely (i) enzymatic modification and inactivation of the aminoglycosides, mediated by aminoglycoside acetyltransferases, nucleotidyltransferases or phosphotransferases, both in Gram-positive and -negative bacteria; (ii) increased efflux of the antibiotic outside the cell; (iii) decreased permeability; and iv) modifications of the 30S ribosomal subunit that alter the binding of the aminoglycosides [28,29,30,31,32,33].

2.2. Heavy Metal Resistance

In the pre-antibiotic era, heavy metals were largely used as chemotherapeutics and/or as antimicrobials in human and animal healthcare, and some heavy metals are still in use today in medicine and agriculture settings [34]. As with antibiotics, resistance to heavy metals has recently increased, and ExPECs presenting combined resistance to both antibiotics and heavy metals are commonly isolated [9,13,16,17,18,19,35,36]. This finding is of particular concern considering that heavy metals have been associated with the co-selection of antibiotic resistance genes and that, thanks to mobile genetic elements, heavy metal resistance genes are transmitted to microorganisms of the same or of related species [37,38]. Although the efficacy of metal preparations is controversial, nevertheless, several heavy metals are still in use in agriculture and aquaculture (i) as organic/inorganic fertilizers; (ii) as preservatives in animal food production and (iii) as biocides and antimicrobials in cases of antibiotic failure [39]. Due to their elevated toxicity, some of the treatments with metals such as mercury and arsenic/antimony have now been eliminated or greatly limited in several countries [40,41]. Since they are chemically stable elements, heavy metals accumulate in soil and water and exercise a strong selective pressure that may trigger the onset of metal-resistant mutants. Thus, decontamination of metal-polluted zones appears to be an inevitable step to limit the development and diffusion of both antibiotic and metal resistance genes [42]. This is of particular concern also considering that the environmental metal pollution is remarkably more diffused than antibiotic pollution. According to what is reported above, the strong association between metal exposure, metal- and antibiotic-resistance genes led the European Scientific Committee for Emerging and Newly Identified Health Risks to warn about bacterial exposure to heavy metals, which may boost the onset and the spread of antibiotic-resistance genes [35]. Apart from their importance in co-selection, heavy metals also play a role in the regulatory mechanisms governing complex aspects of the bacterial physiology, such as the two-component CpxA/CpxR system of Gram-negative bacteria, which senses and responds to stress stimuli, such as those caused by cell-envelope-targeting drugs and heavy metals. Once activated, the CpxA/CpxR system activates the transcription of 11 out of 28 Cu-inducible genes whose expression is also required to transform Cu-susceptible microorganisms into Cu-tolerant derivatives [43]. Furthermore, as well as counteracting antibiotic activity, bacteria have to face the potential lethal effects of poisonous oxygen derivatives (molecular oxygen does not react with cell components, but its derivatives are toxic) such as hydrogen peroxide and superoxide anions, which directly undermine the metabolic activities of enzymes co-factored with iron and flavins. Consequently, when bacteria accumulate substantial reactive oxygen insults, coming from environmental or cellular sources, growth is inhibited. Although hydrogen peroxide and superoxide anions do not oxidize DNA directly, these molecules feed directly or indirectly the generation of the highly reactive hydroxyl radicals, which damages the bacterial chromosome [44]. Characteristically, three reactive oxygen species (ROS) are considered, i.e., superoxide anions (O2−), hydrogen peroxide (H2O2) and hydroxyl radicals (HO•), though other reactive and abundant molecules may exist. Several common oxidants derived from molecular oxygen are found in the environment or even produced by the cellular metabolism. To meet this challenge, E. coli activates complex mechanisms to resist the accumulation of these radicals. The activity of the sigma factor protein family is linked to bacterial stress responses. In E. coli, activation of RpoE is required for maintaining the integrity of periplasmic and outer membrane compartments; it is regulated by Zn and also responsible for the transition to Zn- and Cu-tolerance phenotypes [45]. Again, Cu has also been shown to regulate the expression of the oxidative stress-responsive regulatory gene soxR, whose encoded SoxS protein regulates the expression of the AcrAB efflux pump [46]. Lastly, it has been recently reported that exposure to sub-inhibitory concentrations of heavy metals, such as Cu, Ag, Cr and Zn, promotes the conjugative transfer of antibiotic-resistance genes. This finding highlights even more the urgent need to develop new, effective strategies to control the environmental diffusion of these metal pollutants [9,47,48,49,50].

3. Resistance to Beta-Lactams

Beta-lactams (comprising penicillins, cephalosporins, carbapenems and monobactams) are one of classes of antibiotics most successful for the treatment of bacterial infections. However, over the years, their efficacy has been considerably challenged by the rapid spread worldwide of bacteria resistant to β-lactams.
Beta-lactam antibiotics are bactericidal agents towards actively replicating bacteria; they affect the formation of the bacterial cell wall by covalently binding to the penicillin-binding proteins (PBPs) that are involved in the terminal steps of peptidoglycan cross-linking in both Gram-negative and Gram-positive bacteria. Penicillin G (benzylpenicillin) was the first beta-lactam to be clinically used, mostly to treat streptococcal infections, towards which it shows high activity. Penicillin V (phenoxymethylpenicillin) is another naturally occurring penicillin whose oral formulation is used therapeutically and prophylactically for mild to moderate infections in pediatric patients [51].
The rise of resistant strains quickly followed the introduction of penicillins for clinical use. The most common beta-lactam resistance mechanism found in Gram-negative bacteria is the production of beta-lactamase periplasmic enzymes that hydrolyze the beta-lactam ring. The rapid increase in the incidence of clinically relevant beta-lactamase-producing strains prompted the search for penicillins endowed with increased stability towards these enzymes. In the 1950s, the discovery of the beta-lactamase-stable cephalosporin C introduced new opportunities for the development of a number of novel cephalosporins very active against major beta-lactamase-producing pathogens of medical interest. Several products were introduced into clinical practice, although it was quickly evident that, as with penicillins, the use of cephalosporins in medical practice would have led to the rapid onset of resistant mutants [52].
Beta-lactamases represent the most common mechanism of resistance to beta-lactams in Gram-negative bacteria. AmpC-type β-lactamases and extended-spectrum β-lactamases (ESBLs) represent the two groups of hydrolytic enzymes mainly involved in cephalosporin resistance. The term AmpC defines a class of enzymes that belong to the molecular class C (of the Ambler’s classification system), whereas ESBLs belong to class A and are able to hydrolyze later-generation cephalosporines. A serine residue is present within the active site of both AmpC and ESBL enzymes, though their protein sequences are remarkably different [8,53,54,55]. The class B, which groups metallo-beta lactamases (MBLs) and zinc(II)-dependent enzymes that can accommodate β-lactams in their active site, is able to hydrolyze almost all β-lactams, including carbapenems [56]. Recently, the global dissemination of Gram-negative bacteria harboring plasmid-encoded MBLs (e.g., the New-Delhi metallo-β-lactamase (NDM-1)) has increased the clinical relevance of this class of enzymes. The carriage of plasmid-encoded MBLs seems to be the reason for the high level of expression of this class of enzymes, as well their rapid dissemination [54,55]. The extensive (mis)use of ß-lactams in the recent past in human and animal settings is believed to have favored the selection of beta-lactam resistance worldwide [57]. The search for novel broad-spectrum beta-lactamase inhibitors that may work against many problematic beta-lactamases, such as cephalosporinases and serine-based carbapenemases, which severely limit their therapeutic use, is underway. Carbapenems are a class of highly effective, broad-spectrum antibiotics commonly used for the treatment of severe or high-risk bacterial infections by Gram-positive and Gram-negative microorganisms. As a result, they are often used as “last-line agents” in patients who are gravely ill or suspected of harboring resistant bacteria. The recent emergence of multidrug-resistant pathogens seriously threatens this class of lifesaving drugs. As with other beta-lactams, carbapenems bind to critical PBPs, disrupting the growth and structural integrity of bacterial cell walls [58,59,60].
The antibacterial efficacy of this class of antibiotics lies mainly in the high affinity for penicillin-binding proteins (PBPs) and in their excellent stability against β-lactamases [60]; carbapenems enter Gram-negative bacteria through outer membrane porins and, after crossing the periplasmic space, they “permanently” acylate the PBPs. Furthermore, carbapenems are strong inducers of chromosomal β-lactamases, which may lead to antagonism to penicillins and cephalosporins. Initially, it was thought that bacteria producing carbapenamases circulated mainly among long-term-hospitalized patients; nowadays, the global dissemination of carbapenemase-producing Gram-negative environmental bacteria highlights the need to develop new, efficient strategies to limit the incidence of carbapenem-resistant microorganisms [60,61].

3.1. AmpC Beta-Lactamases

In E. coli, the AmpC beta-lactamase-encoding gene can be either chromosomal (campC) or plasmid-associated (pampC). campC is expressed at low levels since it is under the control of a weak promoter and a strong attenuator [4]. The main feature of cAmpC is represented by its variable level of expression that may be constitutive or inducible by several β-lactams, resulting in different resistance phenotypes. When campC is constitutively expressed, it hydrolyzes penicillins, most cephalosporins, cephamycins and monobactams, but not the fourth-generation cephalosporins and carbapenems. Furthermore, AmpC β-lactamases are not inhibited by “classical” β-lactamase inhibitors [62]. The regulation of campC expression in E. coli is considerably different from other Enterobacteriaceae. E. coli lacks ampR, and thus campC expression cannot be inducible. However, various mutations in the campC promoter/attenuator region may result in overexpression of campC [63]. It is generally accepted that pampC likely originated by the horizontal gene transfer of a campC gene of Enterobacteriaceae [64]. A surveillance study conducted in Canada indicated that CMY-2-producing E. coli could be considered a pathogen whose principal target appears to be the urogenital tract of older women [65]. Failure to detect AmpC-overproducing strains may hamper the clinical management of patients subjected to cephalosporin-based therapy [63,66]. In addition, it has been reported that AmpC overproduction together with porin mutations may reduce susceptibility to carbapenems [67].

3.2. Extended-Spectrum Beta-Lactamases

First described in 1983, the extended-spectrum beta-lactamases (ESBLs) belong to the family of the so-called “newer” beta-lactamases. From the late 1990s, ExPEC strains producing ESBLs begun to emerge globally. ESBLs are able to hydrolize penicillins, cephalosporins and monobactams, but not carbapenems and cephamycins, and their hydrolytic activity is subject to the inhibitory effect of β-lactamase inhibitors. Recently, an ESBL variant, the CTX-M β-lactamase, has become the most common and globally widespread ESBL type [4,68]. Epidemiological surveys have shown an alarming link between CTX-M-15 and resistance to TMP-SMZ, tetracycline, gentamicin, tobramycin and ciprofloxacin [24]. It has been suggested that the global spread of the pandemic UPEC strain of sequence type ST131 may have been favored by the worldwide insurgence of CTX-15-producing E. coli. Furthermore, by comparing E. coli strains producing CTX-M with E. coli strains encoding other ESBLs, it was found that the former were more antibiotic-resistant and more commonly linked to cases of community-acquired UTIs. Thus, ESBLs are considered the predominant source of E. coli resistance against the new generation of cephalosporins, and CTX-M-15-producing E. coli ST131 is the principal source of community-acquired UTIs [4,18,69].

3.3. Metallo-Beta-Lactamases

Metallo-β-lactamases (MBLs) are a family of enzymes that require Zn2+ for operating. MBLs probably originated from commensal and/or environmental bacteria and, from them, horizontally transferred to microorganisms of the same or related species [70]. According to the beta-lactamase sequence-based Ambler’s classification system, class B represents the zinc-dependent MBLs, whereas class A, C and D are serine beta-lactamases [71]. Class B enzymes are of particular concern since they present a broad spectrum of activity against almost all β-lactam antibiotics. Based on sequence similarities and the employment of zinc in catalysis, MBLs have been grouped into three subclasses, namely B1, B2 and B3, which differ in the active site residues, metal content requirement and substrate specificity [72,73].
The type of metallo-β-lactamase found in Klebsiella pneumoniae and E. coli strains, which was isolated from a Swedish patient previously hospitalized at New Delhi, and named NDM-1, is particularly relevant: it is able to hydrolyze a variety of beta-lactams, including penicillins, cephalosporins and carbapenems, except monobactams (aztreonam), and is inhibited by EDTA [74,75,76]. Since then, several NDM-1 variants were identified in Enterobacteriaceae, in Vibrionaceae and in other non-fermenter Gram-negative bacteria. It is thought that NDM-1 probably originated from a very rare genetic fusion event between two previously known antibiotic-resistance genes [75]. Moreover, the majority of NDM-producing bacteria were also found to be resistant to various classes of antibiotics, including aminoglycosides and fluoroquinolones, further reducing the therapeutic options [4,77]. In this context, it appears evident that MBLs are key players for antibiotic resistance. The majority of NDMs identified so far belong to subclass B1. B1 beta-lactamases require one or two Zn2+ ions for catalysis. Among MBLs, the most clinically significant B1 beta-lactamases are NDM, VIM, IMP, SPM and CcrA [73]. Of these, the genes encoding IMP, VIM and NDM are largely plasmid-encoded and thus may be horizontally transmitted to bacteria of the same or related species, contributing to the inter/intra-species genetic variability of these strains [77]. A number of variants of NDMs have been described in Gram-negative pathogens, including ExPECs and E. coli of animal origin [21]. Interestingly, the first MBL of the subclass B1 to be described, in 1966, was the BcII beta-lactamase isolated from Bacillus cereus, a spore-forming environmental bacterium [72].
Concerning MBLs of subclass B2, they are mainly chromosomally encoded and require only one Zn2+ ion to operate. MBLs of subclass B2 are strict carbapenemases acting poorly on penicillins and cephalosporins [78]. Regarding MBLs of subclass B3, they can operate either with one or two Zn2+ ions. MBLs of subclass B3 present a broad substrate spectrum of activity and, remarkably, they share only nine conserved residues with the other MBLs [79].
It is reasonable to believe that NDMs might have contributed to the worldwide spread and success of the pandemic ST131 E. coli strain [4,80]. Regardless, NDM-producing bacteria have to be considered particularly risky (i) because of the lack of available standardized phenotypic tests; and (ii) because of the scarcity of new antibiotics effective for the treatment of these virulent MAR E. coli strains. Accordingly, there is agreement in considering a priority the development of new, efficient strategies to counteract CTX-M- and NDM-producing E. coli strains [81].

4. Metal Resistance

The availability of antibiotics was the endpoint for the wide antimicrobial usage of heavy metal preparations both in medicine and veterinary science. The rapid emergence and diffusion of MAR pathogens worldwide, together with the scarcity of new, effective antibiotics, has led the medical community to reconsider the use of some heavy metals against infections untreatable with conventional antibiotic-based therapies. Heavy metals are naturally present in the environment. We will consider heavy metals that are extensively utilized in agriculture and as additives in feed or preservatives in food, and in medicine.

4.1. Resistance to Arsenic

In the environment, microorganisms are continuously exposed to heavy metals, some of which are taken up as essential nutrients, whereas others (e.g., mercury, lead, cadmium, arsenic and silver) are toxic for a variety of organisms, including bacteria [82]. Among heavy metals endowed with toxic activity, arsenic (As) is of particular concern, mainly because of its use in agriculture settings. Arsenic is a ubiquitous element present primarily in natural geological as well as in anthropogenic sources (e.g., herbicides, pesticides, wood preservatives, animal feeds and semiconductors). Despite its elevated toxicity, in the past, As has been extensively used in human and animal healthcare. In nature, As is present in soil and in groundwater, where it is found in the oxidation states of arsenite As(III), the most dangerous As form, and arsenate As(V) [83]. Although there are a number of methods suitable to rescue As-contaminated areas, none is devoid of serious drawbacks. Actually, the use of engineered bacteria able to absorb and transform As(III) into the less toxic As(V) seems to be very promising to resolve this problem. However, since As oxidation is influenced by pH changes, it is possible that As(III)-decontaminated areas may revert to the previous As(III)-contaminated one. Now, since As(V) is also toxic, researchers have agreed that the best strategy to detoxify As-contaminated areas is to reduce As(III) to the more stable and insoluble form, As(0) [84].
As represents a relevant health threat for human populations living near contaminated areas since long-term As exposure (mainly through the consumption of contaminated drinking water and food) has been associated with several severe diseases, including cardiovascular and peripheral vascular diseases, neurological disorders, diabetes mellitus and various forms of cancer. For these reasons, As ranks first on the Superfund List of dangerous compounds (http://www.atsdr.cdc.gov/spl/, accessed on 6 November 2021) and its use has been largely restricted or even banned in several countries [85,86]. To escape from As toxicity, nearly every organism has evolved export strategies (the ars operon), mainly directed at extruding As(III) outside the cell and thus reducing its intracellular accumulation. Regarding Enterobacteriaceae, ars operons have been found in Serratia marcescens, Yersinia spp. Klebsiella spp. and Salmonella enterica [82]. In E. coli, the ars operon may be either chromosomal or plasmid-encoded. The chromosomal ars operon (arsRBC) codes for three proteins, namely (i) ArsC, an arsenate-reductase that oxidizes intracellular As(III) to As(V), which is then exported from the cells by an energy-dependent efflux process; (ii) ArsB, an arsenate-permease that confers As resistance by pumping As(V) outside the cell; and (iii) ArsR, an arsenic-inducible repressor regulating ars operon expression. Conversely, more complex appears the expression of the plasmid-encoded arsRDABC operon, where arsA codes for an ATPase that binds to the ArsB permease and to ArsD, which appears to function as a second trans-acting repressor that prevents excess transcription [87,88,89,90]. Interestingly, Sütterlin et al., 2018 [91], by investigating the susceptibility to heavy metals of a cohort of 186 putative ExPEC isolated from urine samples of patients hospitalized in Sweden, Germany and Spain, found the ars operon present only in all non-B2 phylogenetic groups, which have previously been associated with the environment and commensalism in both humans and animals, while all B2 clades lacked a functional ars operon and consequentially were susceptible to sodium arsenite. The absence of a functional ars operon appears to be characteristic of the putative ExPEC strains examined; thus, it seems to lead to a survival disadvantage for those strains; on the contrary, bacteria might benefit in some way from the lack of a functional ars operon. Further investigation is needed to understand why arsenic resistance in E. coli strains appears prevalent among E. coli phylogroups associated with the environment rather than among E. coli pathotypes. These findings highlight the importance of better knowledge of the phylogenetic relationships among E. coli strains, whose elucidation might contribute to a better understanding of the mechanisms that drive the resistance and selection of ExPEC in human and veterinary settings [91].

4.2. Resistance to Silver

Although categorized among the list of toxic metals, silver (Ag) does not pose significant risks to human health, whereas it is highly toxic, even at low concentrations, for most microorganisms [37,92]. The silver cation (Ag+) has a long history of use as an antimicrobial agent and it is still used in several bacterial infections, especially in the prevention and treatment of burns and chronic wound infections. Moreover, silver-impregnated dressings and antimicrobial coatings are used in infection management and in the stimulation of wound healing. In addition, silver is used in dental amalgam and silver-impregnated medical devices, such as catheters and heart valves. The widespread and uncontrolled use of silver may result in increasing the rate of bacterial resistance to silver-containing compounds, where silver-resistant bacteria are as problematic as antibiotic-resistant ones [93,94].
Hence, there is a fear that the increasing development and spread of Ag-tolerant microorganisms may compromise the therapeutic utility of this valuable element.
Initially, Ag-tolerant bacterial species were found mainly among environmental bacteria isolated from areas highly polluted by heavy metals. Likely due to the extensive use of heavy metals in livestock farm activities and the lack of effective decontamination measures, the incidence of metal-tolerant bacteria has increased together with the co-selection of antibiotic-resistance genes. The risk of increasing antibiotic resistance has led several laboratories to investigate the mechanisms underlying the onset of heavy metal tolerance in a number of bacterial species [95].
In this context, Gram-positive bacteria do not appear to represent a problem since there is no evidence to date of the development of Ag+ tolerance in Gram-positive pathogens, such as Staphylococcus aureus. On the other hand, low prevalence of Ag+ resistance in Gram-negative pathogens exposed to silver nitrate has been reported [91].
Silver exerts its toxic activity by oxidizing sensitive cellular thiol groups and by inducing the production of reactive oxygen species (ROS), which damage the cell membrane. To protect themselves from the oxidative stress and to become Ag-tolerant, Gram-negative bacteria utilize the sil operon [46]. In E. coli, resistance to Ag+ mainly depends on a combination of periplasmic Ag+ sequestration and subsequent efflux outside the cells [96]. Silver resistance can arise by mutation (endogenous-acquired) or by horizontal gene transfer (exogeneous-acquired). Endogenous-acquired resistance to silver in Gram-negative bacteria can arise from the expression of the chromosomal Cus system and from the loss of outer membrane porins, whereas exogenous-acquired silver resistance is due to the acquisition of a plasmid-encoded sil system. A sil operon was first described in 1975 on plasmid pMG101 (an IncHI2 incompatibility group plasmid, which carries several antibiotic-resistance genes as well as tolerance to mercury, tellurite and silver; present in an epidemic strain of Salmonella enterica serovar Typhimurium [97]). To evaluate the incidence of cryptic Ag+ resistance, Elkrewi et al., 2017 [96] analyzed a collection of 444 Gram-negative clinical pathogens by plating bacteria onto agar plates containing AgNO3. Using this approach, previous results have been confirmed indicating that overt Ag+ resistance is not so common, while cryptic sil operons are found in the majority of Enterobacter spp. and of Klebsiella spp. strains [96]. Only one isolate out 135 E. coli strains tested (0.7%) was found to be Ag+-resistant. The finding that none of the isolates tested displayed overt Ag+-tolerance clearly indicated that cryptic sil operons are common in Gram-negative pathogens such as Enterobacter and Klebsiella spp. Regarding the sil operon, it comprises nine open reading frames (ORFs) (silE, silS, silR, silC, silF, silB, silA, ORF105 and silP) defining three transcriptional units [94]. Either endogenous or exogenous, sil-mediated resistance mainly consists of preventing intracellular silver accumulation. To this end, SilE, a small periplasmic silver-binding protein, binds silver at the cell surface, presenting the first line of defense against silver toxicity, together with the two-component silver-responsive transcriptional regulatory system silRS. This system controls the expression of the silver efflux ATPase silP gene, of the tripartite silCBA silver effluxer and of silF, which is a periplasmic silver chaperone. Endogenous silver resistance is mainly due to porin loss and overexpression of the Cus system, which contributes to silver efflux and to limited Ag accumulation inside the cell [94,98]. Further knowledge regarding the mechanisms involved in the development and regulation of sil operon expression is a prerequisite to understand the meaning of the carriage of a cryptic sil operon in Gram-negative bacteria.

4.3. Resistance to Cadmium

Heavy metal contamination can impact soil ecosystems, resulting in significant loss of soil quality by altering biological processes catalyzed by microorganisms. Microorganisms are highly adaptable to extreme environmental conditions such as those characterized by heavy metal contamination. Cadmium (Cd) is a non-essential, non-biodegradable, highly diffused metal element, extremely toxic for all organisms. When Cd enters into a susceptible host cell, it accumulates in the cytoplasm, altering the activity of several enzymes and directly attacking nuclear DNA [99,100]. The worldwide presence of Cd in nature is considered to be mainly due to ungoverned industrial and anthropological activities, such as corrosive reagents, as stabilizers in the synthesis of PVC products, mining, electroplating, as stabilizers of plastics, manufacturing batteries, alloy pigments and high-phosphate fertilizers [101,102].
Heavy metal pollution poses many risks to human health considering that human consumption of cadmium-contaminated food, water or air has been associated with the development of severe kidney, lung, liver, bone and reproductive system diseases. Moreover, according to the International Agency for Research on Cancer, Cd is now designated as a human carcinogen [103,104]. However, some microbes survive well in Cd-polluted environments as they have evolved various metal resistance mechanisms [105]. Bacterial exposure to Cd may give rise to Cd-tolerant mutants as well as to the co-selection of antibiotic-resistance genes [106]. Thus, as Cd pollution is a primary source of health concern for human and animal health, measures have been taken to decontaminate and conserve the environment by reducing this type of heavy metal pollution. To this end, although several investigations have been conducted in order to develop suitable tools to decontaminate aqueous metal-polluted environments, so far, none has been found to be completely satisfactory. Actually, a quite promising approach for bioremediation appears to be that centered on the development of engineered microorganisms [105]. To cope with the damaging effects of the intracellular accumulation of Cd2+ in the cell, E. coli strains have developed a variety of resistance mechanisms, including efflux transport of Cd2+ outside the cell and intracellular sequestration by precipitation by metal-binding proteins, such as metallothionein and other thiol-containing compounds. Czc is one of the best-characterized metal efflux systems and confers resistance against cadmium, zinc and cobalt in many Gram-negative bacteria, including E. coli [107]. In E. coli, the cadmium efflux pump operon czcCBA consists of three structural genes whose products form a complex efflux pump. Of these, CzcA is the chemiosmotic cation/H+ antiporter, CzcB is the membrane fusion protein, and CzcC is the outer membrane protein [108]. Furthermore, chelation of metal ions by intracellular metallothioneins (MTs) is another strategy used by E. coli to survive under Cd toxicity. MTs are a family of small polypeptides with a high percentage of cysteine residues and metal-binding sites, which bind Cd ions, thus contributing to the maintenance of homeostasis and to the induction of Cd tolerance. MTs also play a role in other cellular processes, including DNA damage repair, the metabolism of metallo-drugs, responses to stress conditions and scavenging of reactive oxygen species [109]. In particular, the transition from Cd susceptibility to tolerance appears to be regulated by the coordinated expression of some chromosomal genes, including the zntA gene, which encodes for the Pb2+-, Zn2+- and Cd2+-transporting ATPases, and the capB gene, whose expression also enhances E. coli Cd resistance [100,110]. In addition, the plasmid-associated czcABC operon and the cnr system are also thought to be involved in Cd2+ tolerance. Moreover, by generating E. coli B strain BL21(D3) mutants highly resistant to Cd, two other genes were identified, namely htpX and gor. At present, it is impossible to exclude that other genes related to Cd resistance may exist in the E. coli genome. A better understanding of the mechanism underlining Cd tolerance is needed to improve the development of new, effective tools to be used in order to reduce the presence of this toxic element in the environment [100].

4.4. Resistance to Copper and Zinc

Antibiotic and heavy metal supplementation has been extensively used to promote growth and animal health. Alongside antibiotics, heavy metals have been used in livestock production for a long time. However, the negative impact of the environmental release of these substances on the development and spread of antibiotic- as well as of heavy-metal-resistant microorganisms has recently led to their ban in several countries. Copper (Cu) and zinc (Zn) are two ubiquitous essential trace elements whose principal role is to ensure proper cellular functions [111]. Regarding Cu, this element has been shown to be necessary for the human body because its major function includes fetal growth and early postnatal development, hemoglobin synthesis, maturation of the connective tissues and inflammatory processes [112]. Cu supplementation is used to prevent Cu-deficiency syndromes. To ensure that the necessary amount of Cu is available for absorption in agriculture settings, the concentrations of Cu added to feed are, in general, higher than necessary, highly contributing to increased Cu pollution as well as the selective pressure towards environmental microorganisms [95]. Needed to sustain life, excess Cu is extremely toxic, with Cu(I) being more toxic than Cu(II), which damages iron–sulfur clusters and catalyzes the production of reactive oxygen species [113]. Organisms have had to develop strategies to deal with the toxic effects of Cu to cells. However, it was recently reported that, at therapeutic concentrations, Cu might also exert a selection pressure on the gut microbiota that may lead to the development of Cu-tolerant mutants. To avoid toxicity, bacteria have evolved effective strategies to limit the amount of Cu accumulation in the cell through the synthesis of specific metal transport systems that balance the influx and efflux of metals to and from the cell [95,114]. Nevertheless, exposure to metals also selects for the development of metal-resistant strains, which, in turn, will increase the risk of co-selection of antibiotic-resistant genes [95].
The antimicrobial nature of copper has been recognized since ancient times so that when, in 2006, the UE banned the use of antibiotics in animal husbandry, considered the primary reservoirs of virulence and antibiotic-resistance genes, much interest turned towards heavy metals as alternative antibiotics [115]. A relevant characteristic of Cu toxicity lies in its ability to undergo redox cycling between Cu(II), the less toxic oxidized cupric form, and Cu(I), the toxic cuprous reduced form. Under aerobic conditions, this redox cycling generates highly reactive hydroxyl radicals that damage biomolecules, such as proteins, lipids and DNA. In E. coli, at physiological Cu levels, these fluctuations are under the control of two chromosomal operons, the copper translocating P-type ATPase CopA system, and the central components in copper homeostasis, the multi-copper oxidase CueO and the multi-component copper transport system CusCFBA, which remove the excess of Cu(I), thus protecting the periplasmic space from copper-induced toxicity. As soon as Cu enters the E. coli cytoplasm, cytosolic chaperones bind and transport Cu to copper-requiring enzymes, such as cytochrome oxidase, superoxide dismutase and lysyl oxidase, as well as to specific efflux systems, such as members of the P1B-1-ATPase subfamily, including Cu(I) transporters and the Cpx-ATPase [95,116]. The chromosomally encoded P1B-1-ATPases are involved in the removal of excesses of cytoplasmic Cu out of the cell. Of these, the best-characterized ones are those of the copper homeostasis systems, including copA, which encodes the P1B-ATPase copA. copA is part of the CueR regulon, where the repressor CueR binds Cu(I) and regulates the expression of copA and cueO [95,117]. While copA expels Cu(I) from the cytoplasm, its presence in the periplasm may cause damage to the cell. To cope with this, bacteria utilize cueO, a periplasmic multicopper oxidase enzyme, which oxidizes Cu(I) to Cu(II). Genes encoding homologs of copA and cueO are present. Other than to be chromosomally encoded, Cu-resistant determinants have been found also on E. coli plasmids linked to the presence of the pco system, which encodes the two-component regulatory system PcoRS [95,118,119]. Zn is the second most abundant transition metal in seawater and in humans. It is an essential trace element required to fulfill the dietary requirements of all organisms. Zn is considerably less toxic than redox-active metals such as copper and is more soluble than iron. Zn is widely used in the pig farming industry in order to overcome problems during weaning, including infections caused by pathogenic E. coli [120,121,122]. Remarkably, Zn serves as a cofactor in a variety of enzymes, as well as in several regulatory proteins. Several families of integral membrane proteins transport Zn(II), moving it across membranes into and outside cells [95]. The precise mechanisms used by E. coli to sense, store and/or incorporate Zn(II) as a cofactor have to be fully elucidated. A common assumption is that Zn(II)-requiring enzymes and transcription factors acquire this essential element from a cytosolic pool, assumed to be 10−16 M in free Zn(II) [45,123,124]. Several Zn(II)-responsive transcription factors are known to mediate zinc homeostasis by sensing changes in the cytosolic level of free Zn(II) [95]. Bacteria exposed to elevated concentrations of Zn(II), such as those encountered in contaminated soil and water, and in feed additives in agriculture, may lead to the insurgence of Zn-tolerant mutants. Recent studies conducted with piglets fed with high concentrations of Zn reported a rise in the proportion of multidrug-resistant E. coli in the guts of the animals [115,125,126]. These findings have generated doubts regarding the convenience of the use of this element in agriculture, since Zn-associated co-selection with antibiotic-resistance genes has been demonstrated [115,127,128,129]. Accordingly, withdrawal of veterinary products containing Zn has been highly recommended in the EU states [95]. In E. coli, Zn binds to around 10% of all bacterial proteins, contributing to proper 3D structure and catalysis [95]. Interestingly, the antioxidant enzyme copper-zinc-superoxide dismutase (CuZn-SOD) is unique in requiring both metals for its catalytic activity [115]. As for copper, E. coli resistance to Zn mainly depends on the ability to control the cytoplasmic concentration of Zn(II) by uptake and efflux-specific systems [130]. In E. coli, the Zn(II) regulators ZntR and Zur are activated in the presence of very low concentrations of free Zn(II). At least three systems (ABC transporter, ZIP transporter and phosphate-bound uptake) are known to be involved in bacterial zinc uptake, while at least four systems (P1B-type ATPases, CDF transporters, 2-TM-GxN transporters and CBA efflux systems), either chromosomally or plasmid-encoded, have been found to be involved in transporting Zn(II) outside the cell. Under Zn-limiting conditions, E. coli utilizes the ABC (ATP binding cassette) transporter ZnuABC operon, where ZnuA is a zinc-binding protein, ZnuB spans the cytoplasmic membrane and forms the channel used to transport Zn(II) into the cytoplasm, and ZnuC is bound to the cytoplasmic site on ZnuB, providing the energy required for Zn(II) transport via ATP hydrolysis [131]. Thus, since several metal-resistance genes, including those encoding for Cu and Zn tolerance, have been involved in the co-selection of antibiotic-resistance genes, the limited use of these elements and/or decontamination of polluted soil and groundwater sites appear to be essential tasks to limit the onset and diffusion of multiple pathogenic, antibiotic-resistant bacteria. Furthermore, along with their role in co-selection, heavy metals may form complexes with several classes of antibiotics, whose effects may vary from the inactivation and/or reduction of antibiotic activity, decrease in metal availability, increase in impermeability-based resistance mechanisms or perturbation of metal-bound proteins [113]. These findings strongly support the belief that heavy metal tolerance may be considered an important virulence factor of pathogenic microorganisms [132].

5. Metal Nanoparticles

The incidence of MAR pathogens is a serious health problem and their eradication has become a very difficult or even impossible task to achieve with the traditional antimicrobial therapy, thus leading to an increase in morbidity and mortality. Consequently, several alternative strategies to combat these MAR pathogens have been proposed; metal nanoparticles (NPs) are considered one of the most promising alternatives. Actually, NPs are increasingly used as a delivery system for medical products, including antibiotics, or directly as antibacterial agents. Although the exact mechanism through which NPs exert their antimicrobial activity is not completely understood, metal and metal oxide NPs have been shown to have many useful features, such as to modify both the toxicity and the antibacterial activity of antibiotics; to damage the bacterial outer membrane and/or cell wall; to favor the interaction between intra- and extracellular components and ions; to produce reactive oxygen species that damage bacterial structures; to inhibit DNA synthesis; to inhibit enzyme activity [133,134].

6. Conclusions

Extra-intestinal pathogenic E. coli (ExPEC) strains represent one of the most frequent causes of human infections, resulting in massive direct medical and social costs and approximately two million human deaths/year. ExPEC strains comprise several pathogenic lineages, of which only a few are responsible for the vast majority of infections. The emergence and the worldwide spread of multiple-antibiotic-resistant (MAR) ExPEC strains that we are witnessing today are of particular concern due to the shortage of new antibiotics that are effective against these MAR pathogens and to the limited success of the measures that have been put in place to control their development and propagation (e.g., the sparing use of antibiotics in order to prolong their effectiveness; the ban of the use of antibiotic as animal growth promoters). Although the mechanism(s) underlining the development and the global spread of MAR ExPEC strains have not been completely elucidated yet, the widespread and very often unnecessary use of antibiotics in clinical and agriculture settings is considered to be the leading cause of this condition. Similarly to antibiotics, resistance to heavy metals has recently increased, likely due to the long-lasting strong selective pressure exercised by the environmental anthropogenic levels of these substances (unlike antibiotics, heavy metals are not subject to degradation). As a result, E. coli strains, pathogenic or not, presenting a combination of heavy metals and antibiotic-resistance genes are now frequently isolated. The rise of heavy metal resistance is of great concern because (i) heavy metal resistance determinants appear to play an important role in the selection and diffusion of antibiotic-resistance genes through co-carriage and/or co-selection of antibiotic and metals resistance genes; and (ii) heavy metals are still in use in medicine to treat a number of bacterial infections, so heavy-metal-tolerant mutants may limit their potential therapeutic use. In conclusion, this review highlights recent aspects of antibiotic and heavy metal resistance. Future research will be needed to develop effective strategies addressed at limiting the impact of MAR pathogens on human and animal health.

Author Contributions

Conceptualization, C.L., L.M., A.L.C., M.M., A.C., M.N. and C.Z.; writing—review and editing, C.L., L.M., A.L.C., M.M., A.C., M.N. and C.Z.; supervision, C.L. and C.Z.; funding acquisition, C.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Ricerca Scientifica Ateneo 2019 “Sapienza” University of Roma to C.L.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Kaper, J.B.; Nataro, J.P.; Mobley, H.L.T. Pathogenic Escherichia coli. Nat. Rev. Microbiol. 2004, 2, 123–140. [Google Scholar] [CrossRef] [PubMed]
  2. Denamur, E.; Clermont, O.; Bonacorsi, S.; Gordon, D. The population genetics of pathogenic Escherichia coli. Nat. Rev. Microbiol. 2021, 19, 37–54. [Google Scholar] [CrossRef]
  3. Camacho-Gonzalez, A.; Spearman, P.W.; Stoll, B.J. Neonatal Infectious Diseases: Evaluation of Neonatal Sepsis. Pediatr. Clin. N. Am. 2013, 60, 367–389. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Pitout, J.D.D. Extraintestinal pathogenic Escherichia coli: An update on antimicrobial resistance, laboratory diagnosis and treatment. Expert Rev. Anti.-Infect. Ther. 2012, 10, 1165–1176. [Google Scholar] [CrossRef] [PubMed]
  5. Brumbaugh, A.R.; Smith, S.N.; Mobley, H.L.T. Immunization with the Yersiniabactin Receptor, FyuA, Protects against Pyelonephritis in a Murine Model of Urinary Tract Infection. Infect. Immun. 2013, 81, 3309–3316. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  6. Micali, S.; Isgro, G.; Bianchi, G.; Miceli, N.; Calapai, G.; Navarra, M. Cranberry and Recurrent Cystitis: More than Marketing? Crit. Rev. Food Sci. Nutr. 2014, 54, 1063–1075. [Google Scholar] [CrossRef]
  7. Barnich, N.; Darfeuille-Michaud, A. Adherent-invasive Escherichia coli and Crohn’s disease. Curr. Opin. Gastroenterol. 2007, 23, 16–20. [Google Scholar] [CrossRef]
  8. Tenaillon, O.; Skurnik, D.; Picard, B.; Denamur, E. The population genetics of commensal Escherichia coli. Nat. Rev. Microbiol. 2010, 8, 207–217. [Google Scholar] [CrossRef]
  9. Marazzato, M.; Aleandri, M.; Massaro, M.R.; Vitanza, L.; Conte, A.L.; Conte, M.P.; Nicoletti, M.; Comanducci, A.; Goldoni, P.; Maurizi, L.; et al. Escherichia coli strains of chicken and human origin: Characterization of antibiotic and heavy-metal resistance profiles, phylogenetic grouping, and presence of virulence genetic markers. Res. Vet. Sci. 2020, 132, 150–155. [Google Scholar] [CrossRef]
  10. Clermont, O.; Christenson, J.K.; Denamur, E.; Gordon, D.M. The Clermont Escherichia coli phylo-typing method revisited: Improvement of specificity and detection of new phylo-groups. Environ. Microbiol. Rep. 2013, 5, 58–65. [Google Scholar] [CrossRef]
  11. Dale, A.P.; Woodford, N. Extra-Intestinal Pathogenic Escherichia coli (ExPEC): Disease, Carriage and Clones. J. Infect. 2015, 71, 615–626. [Google Scholar] [CrossRef] [Green Version]
  12. Clermont, O.; Dixit, O.V.A.; Vangchhia, B.; Condamine, B.; Dion, S.; Bridier-Nahmias, A.; Denamur, E.; Gordon, D. Characterization and rapid identification of phylogroup G in Escherichia coli, a lineage with high virulenceand antibiotic resistance potential. Environ. Microbiol. 2019, 21, 3107–3117. [Google Scholar] [CrossRef] [PubMed]
  13. Sarowska, J.; Futoma-Koloch, B.; Jama-Kmiecik, A.; Frej-Madrzak, M.; Ksiazczyk, M.; Bugla-Ploskonska, G.; Choroszy-Krol, I. Virulence factors, prevalence and potential transmission of extraintestinal pathogenic Escherichia coli isolated from different sources: Recent reports. Gut Pathog. 2019, 11, 10. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Wirth, T.; Falush, D.; Lan, R.; Colles, F.; Mensa, P.; Wieler, L.H.; Karch, H.; Reeves, P.R.; Maiden, M.C.J.; Ochman, H.; et al. Sex and virulence in Escherichia coli: An evolutionary perspective. Mol. Microbiol. 2006, 60, 1136–1151. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  15. Riley, L.W. Pandemic lineages of extraintestinal pathogenic Escherichia coli. Clin. Microbiol. Infect. 2014, 20, 380–390. [Google Scholar] [CrossRef] [Green Version]
  16. Kallonen, T.; Brodrick, H.J.; Harris, S.R.; Corander, J.; Brown, N.M.; Martin, V.; Peacock, S.J.; Parkhill, J. Systematic longitudinal survey of invasive Escherichia coli in England demonstrates a stable population structure only transiently disturbed by the emergence of ST131. Genome Res. 2017, 27, 1437–1449. [Google Scholar] [CrossRef] [Green Version]
  17. Yamaji, R.; Friedman, C.R.; Rubin, J.; Suh, J.; Thys, E.; McDermott, P.; Hung-Fan, M.; Riley, L.W. A Population-Based Surveillance Study of Shared Genotypes of Escherichia coli Isolates from Retail Meat and Suspected Cases of Urinary Tract Infections. mSphere 2018, 15, e00179-18. [Google Scholar] [CrossRef] [Green Version]
  18. Kot, B. Antibiotic Resistance Among Uropathogenic Escherichia coli. Pol. J. Microbiol. 2019, 68, 403–415. [Google Scholar] [CrossRef] [Green Version]
  19. Petty, N.K.; Ben Zakour, N.L.; Stanton-Cook, M.; Skippington, E.; Totsika, M.; Forde, B.M.; Phan, M.D.; Gomes Moriel, D.; Peters, K.M.; Davies, M.; et al. Global dissemination of a multidrug resistant Escherichia coli clone. Proc. Natl. Acad. Sci. USA 2014, 111, 5694–5699. [Google Scholar] [CrossRef] [Green Version]
  20. Longhi, C.; Conte, M.P.; Marazzato, M.; Iebba, V.; Totino, V.; Santangelo, F.; Gallinelli, C.; Pallecchi, L.; Riccobono, E.; Schippa, S.; et al. Plasmid-mediated fluoroquinolone resistance determinants in Escherichia coli from community uncomplicated urinary tract infection in an area of high prevalence of quinolone resistance. Eur. J. Clin. Microbiol. Infect. Dis. 2012, 31, 1917–1921. [Google Scholar] [CrossRef]
  21. Poirel, L.; Madec, J.Y.; Lupo, A.; Schink, A.K.; Kieffer, N.; Nordmann, P.; Schwarz, S. Antimicrobial resistance in Escherichia coli. Microbiol. Spectr. 2018, 6, 289–316. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Massella, E.; Reid, C.J.; Cummins, M.L.; Anantanawat, K.; Zingali, T.; Serraino, A.; Piva, S.; Giacometti, F.; Djordjevic, S.P. Snapshot Study of Whole Genome Sequences of Escherichia coli from Healthy Companion Animals, Livestock, Wildlife, Humans and Food in Italy. Antibiotics 2020, 9, 782. [Google Scholar] [CrossRef]
  23. Nji, E.; Kazibwe, J.; Hambridge, T.; Joko, C.A.; Larbi, A.A.; Damptey, L.A.O.; Nkansa-Gyamf, N.A.; Stålsby Lundborg, C.; Lien, L.T.Q. High prevalence of antibiotic resistance in commensal Escherichia coli from healthy human sources in community settings. Sci. Rep. 2021, 11, 3372. [Google Scholar] [CrossRef] [PubMed]
  24. Pitout, J.D.D.; Laupland, K.B. Extended-spectrum beta-lactamase-producing Enterobacteriaceae: An emerging public-health concern. Lancet Infect. Dis. 2008, 8, 159–166. [Google Scholar] [CrossRef]
  25. Foxman, B. The epidemiology of urinary tract infection. Nat. Rev. Urol. 2010, 7, 653–660. [Google Scholar] [CrossRef]
  26. Duan, Y.; Gao, H.; Zheng, L.; Liu, S.; Cao, Y.; Zhu, S.; Wu, Z.; Ren, H.; Mao, D.; Luo, Y. Antibiotic Resistance and Virulence of Extraintestinal Pathogenic Escherichia coli (ExPEC) Vary According to Molecular Types. Front. Microbiol. 2020, 11, 598305. [Google Scholar] [CrossRef]
  27. Manges, A.R.; Geum, H.M.; Guo, A.; Edens, T.J.; Fibke, C.D.; Pitout, J.D.D. Global Extraintestinal Pathogenic Escherichia coli (ExPEC) Lineages. Clin. Microbiol. Rev. 2019, 32, e00135-18. [Google Scholar] [CrossRef]
  28. Krause, K.M.; Serio, A.W.; Kane, T.R.; Connolly, L.E. Aminoglycosides: An Overview. Cold Spring Harb. Perspect. Med. 2016, 6, a027029. [Google Scholar] [CrossRef] [Green Version]
  29. Magnet, S.; Courvalin, P.; Lambert, T. Resistance-nodulation-cell division-type efflux pump involved in aminoglycoside resistance in Acinetobacter baumannii strain BM4454. Antimicrob. Agents Chemother. 2001, 45, 3375–3380. [Google Scholar] [CrossRef] [Green Version]
  30. Périchon, B.; Courvalin, P.; Galima, M. Transferable resistance to aminoglycosides by methylation of G1405 in 16S rRNA and to hydrophilic fluoroquinolones by QepA-mediated efflux in Escherichia coli. Antimicrob. Agents Chemother. 2007, 51, 2464–2469. [Google Scholar] [CrossRef] [Green Version]
  31. Davis, M.A.; Baker, K.N.K.; Orfe, L.H.; Shah, D.H.; Besser, T.E.; Call, D.R. Discovery of a Gene Conferring Multiple-Aminoglycoside Resistance in Escherichia coli. Antimicrob. Agents Chemother. 2010, 54, 2666–2669. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  32. Poolman, J.T.; Wacker, M. Extraintestinal Pathogenic Escherichia coli, a Common Human Pathogen: Challenges for Vaccine Development and Progress in the Field. J. Infect. Dis. 2016, 213, 6–13. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Herisse, M.; Duverger, Y.; Martin-Verstraete, I.; Barras, F.; Ezraty, B. Silver potentiates aminoglycoside toxicity by enhancing their uptake. Mol. Microbiol. 2017, 105, 115–126. [Google Scholar] [CrossRef] [Green Version]
  34. Briffa, J.; Sinagra, E.; Blundell, R. Heavy metal pollution in the environment and their toxicological effects on humans. Heliyon 2020, 6, e04691. [Google Scholar] [CrossRef] [PubMed]
  35. Pal, C.; Asiani, K.; Arya, S.; Rensing, C.; Stekel, D.J.; Larsson, D.G.J.; Hobman, J.L. Metal Resistance and Its Association With Antibiotic Resistance. Adv. Microb. Physiol. 2017, 70, 261–313. [Google Scholar] [PubMed]
  36. Sütterlin, S.; Téllez-Castillo, C.J.; Anselem, L.; Yin, H.; Bray, J.E.; Maiden, M.C.J. Heavy Metal Susceptibility of Escherichia coli Isolated from Urine Samples from Sweden, Germany, and Spain. Antimicrob. Agents Chemother. 2018, 62, e00209–e00218. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  37. Hobman, J.L.; Crossman, L.C. Bacterial antimicrobial metal ion resistance. J. Med. Microbiol. 2015, 64, 471–497. [Google Scholar] [CrossRef]
  38. Wales, A.W.; Davies, R.H. Co-Selection of Resistance to Antibiotics, Biocides and Heavy Metals, and Its Relevance to Foodborne Pathogens. Antibiotics 2015, 4, 567–604. [Google Scholar] [CrossRef] [Green Version]
  39. Tchounwou, P.B.; Yedjou, C.G.; Patlolla, A.K.; Sutton, D.J. Heavy metal toxicity and the environment. Exp. Suppl. 2012, 101, 133–164. [Google Scholar]
  40. Jaishankar, M.; Tseten, T.; Anbalagan, N.; Mathew, B.B.; Beeregowda, K.N. Toxicity, mechanism and health effects of some heavy metals. Interdiscip. Toxicol. 2014, 7, 60–72. [Google Scholar] [CrossRef] [Green Version]
  41. Balali-Mood, M.; Naseri, K.; Tahergorabi, Z.; Khazdair, M.R.; Sadeghi, M. Toxic Mechanisms of Five Heavy Metals: Mercury, Lead, Chromium, Cadmium, and Arsenic. Front. Pharmacol. 2021, 12, 643972. [Google Scholar] [CrossRef] [PubMed]
  42. Stepanauskas, R.; Glenn, T.C.; Jagoe, C.H.; Tuckfield, R.C.; Lindell, A.H.; McArthur, J.V. Elevated microbial tolerance to metals and antibiotics in metal-contaminated industrial environments. Environ. Sci. Technol. 2005, 39, 3671–3678. [Google Scholar] [CrossRef] [PubMed]
  43. Yamamoto, K.; Ishihama, A. Characterization of copper-inducible promoters regulated by CpxA/CpxR in Escherichia coli. Biosci. Biotechnol. Biochem. 2006, 70, 1688–1695. [Google Scholar] [CrossRef] [Green Version]
  44. Mendoza-Chamizo, B.; Løbner-Olesen, A.; Charbon, G. Coping with Reactive Oxygen Species to Ensure Genome Stability in Escherichia coli. Genes 2018, 9, 565. [Google Scholar] [CrossRef] [Green Version]
  45. Egler, M.; Grosse, C.; Grass, G.; Nies, D.H. Role of the extracytoplasmic function protein family sigma factor RpoE in metal resistance of Escherichia coli. J. Bacteriol. 2005, 187, 2297–2307. [Google Scholar] [CrossRef] [Green Version]
  46. Harrison, J.J.; Tremaroli, V.; Stan, M.A.; Chan, C.S.; Vacchi-Suzzi, C.; Heyne, B.J.; Parsek, M.R.; Ceri, H.; Turner, R.J. Chromosomal antioxidant genes have metal ion-specific roles as determinants of bacterial metal tolerance. Environ. Microbiol. 2009, 11, 2491–2509. [Google Scholar] [CrossRef]
  47. Gullberg, E.; Albrecht, L.M.; Karlsson, C.; Sandegren, L.; Andersson, D.I. Selection of a Multidrug Resistance Plasmid by Sublethal Levels of Antibiotics and Heavy Metals. mBio 2014, 5, e01918-14. [Google Scholar] [CrossRef] [Green Version]
  48. Zhang, Y.; Gu, A.Z.; Cen, T.; Li, X.; He, M.; Li, D.; Chen, J. Sub-inhibitory concentrations of heavy metals facilitate the horizontal transfer of plasmid-mediated antibiotic resistance genes in water environment. Environ. Pollut. 2018, 237, 74–82. [Google Scholar] [CrossRef] [PubMed]
  49. Wang, Q.; Liu, L.; Hou, Z.; Wang, L.; Ma, D.; Yang, G.; Guo, S.; Luo, J.; Qi, L.; Luo, Y. Heavy metal copper accelerates the conjugative transfer of antibiotic resistance genes in freshwater microcosms. Sci. Total Environ. 2020, 717, 137055. [Google Scholar] [CrossRef]
  50. Li, J.; Phulpoto, I.A.; Zhang, G.; Yu, Z. Acceleration of emergence of E. coli antibiotic resistance in a simulated sublethal concentration of copper and tetracycline co-contaminated environment. AMB Express 2021, 11, 14. [Google Scholar] [CrossRef]
  51. Pottegård, A.; Broe, A.; Aabenhus, R.; Bjerrum, L.; Hallas, J.; Damkier, P. Use of Antibiotics in Children A Danish Nationwide Drug Utilization Study. Pediatr. Infect. Dis. J. 2015, 34, e16–e22. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Bush, K.; Bradford, P.A. β-Lactams and β-Lactamase Inhibitors: An Overview. Cold Spring Harb. Perspect. Med. 2016, 6, a025247. [Google Scholar] [CrossRef] [PubMed]
  53. Martinez-Medina, M.; Mora, A.; Blanco, M.; López, C.; Alonso, M.P.; Bonacorsi, S.; Nicolas-Chanoine, M.H.; Darfeuille-Michaud, A.; Garcia-Gil, J.; Blanco, J. Similarity and divergence among adherent-invasive Escherichia coli and extraintestinal pathogenic E. coli strains. J. Clin. Microbiol. 2009, 47, 3968–3979. [Google Scholar] [CrossRef] [Green Version]
  54. Livermore, D.M.; Woodford, N. The β-Lactamase Threat in Enterobacteriaceae, Pseudomonas and Acinetobacter. Trends Microbiol. 2006, 14, 413–420. [Google Scholar] [CrossRef] [PubMed]
  55. Adamus-Białeka, W.; Wawszczaka, M.; Arabskib, M.; Majchrzak, M.; Gulba, M.; Jarych, D.; Parniewski, P.; Głuszeka, S. Ciprofloxacin, amoxicillin, and aminoglycosides stimulate genetic and phenotypic changes in uropathogenic Escherichia coli strains. Virulence 2019, 10, 260–276. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. De Angelis, G.; Del Giacomo, P.; Posteraro, B.; Sanguinetti, M.; Tumbarello, M. Molecular Mechanisms, Epidemiology, and Clinical Importance of β-Lactam Resistance in Enterobacteriaceae. Int. J. Mol. Sci. 2020, 21, 5090. [Google Scholar] [CrossRef]
  57. Sun, S.; Zhang, W.; Mannervik, B.; Andersson, D.I. Evolution of Broad Spectrum β-Lactam Resistance in an Engineered Metallo-β-lactamase. J. Biol. Chem. 2013, 288, 2314–2324. [Google Scholar] [CrossRef] [Green Version]
  58. Armstrong, T.; Fenn, S.J.; Hardie, K.R. JMM Profile: Carbapenems: A broad-spectrum antibiotic. J. Med. Microbiol. 2021, 70, 1462. [Google Scholar] [CrossRef]
  59. Codjoe, F.S.; Donkor, E.S. Carbapenem Resistance: A Review. Med. Sci. 2018, 6, 1. [Google Scholar] [CrossRef] [Green Version]
  60. Papp-Wallace, K.M.; Endimiani, A.; Taracila, M.A.; Bonomo, R.A. Carbapenems: Past, Present, and Future. Antimicrob. Agents Chemother. 2011, 55, 4943–4960. [Google Scholar] [CrossRef] [Green Version]
  61. Woodford, N.; Wareham, D.W.; Guerra, B.; Teale, C. Carbapenemase producing Enterobacteriaceae and non-Enterobacteriaceae from animals and the environment: An emerging public health risk of our own making? J. Antimicrob. Chemother. 2014, 69, 287–291. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  62. Vázquez-Ucha, J.C.; Arca-Suárez, J.; Bou, G.; Beceiro, A. New Carbapenemase Inhibitors: Clearing the Way for the β-Lactams. Int. J. Mol. Sci. 2020, 21, 9308. [Google Scholar] [CrossRef] [PubMed]
  63. Peter-Getzlaff, S.; Polsfuss, S.; Poledica, M.; Hombach, M.; Giger, J.; Böttger, E.C.; Zbinden, R.; Bloemberg, G.V. Detection of AmpC Beta-Lactamase in Escherichia coli: Comparison of Three Phenotypic Confirmation Assays and Genetic Analysis. J. Clin. Microbiol. 2011, 49, 2924–2932. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. Jacoby, G.A. AmpC—Lactamases. Clin. Microbiol. Rev. 2009, 22, 161–182. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Pitout, J.D.D.; Gregson, D.B.; Church, D.L.; Laupland, K.B. Population-based Laboratory Surveillance for AmpC β-Lactamase–producing Escherichia coli, Calgary. Emerg. Infect. Dis. 2007, 13, 443–448. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  66. Siu, L.K.; Lu, P.L.; Chen, J.Y.; Lin, F.M.; Chang, S.C. High-level expression of ampC beta-lactamase due to insertion of nucleotides between −10 and −35 promoter sequences in Escherichia coli clinical isolates: Cases not responsive to extended-spectrum-cephalosporin treatment. Antimicrob. Agents Chemother. 2003, 47, 2138–2144. [Google Scholar] [CrossRef] [Green Version]
  67. Mammeri, H.; Guillon, H.; Eb, F.; Nordmann, P. Phenotypic and Biochemical Comparison of the Cabapenem-Hydrolyzing Activities of Five Plasmid-Borne AmpC β-lactamases. Antimicrob. Agents Chemother. 2010, 54, 4556–4560. [Google Scholar] [CrossRef] [Green Version]
  68. Castanheira, M.; Simner, P.J.; Bradford, P.A. Extended-spectrum b-lactamases: An update on their characteristics, epidemiology and detection. JAC Antimicrob. Resist. 2021, 3, dlab092. [Google Scholar] [CrossRef] [PubMed]
  69. Totsika, M.; Beatson, S.A.; Sarkar, S.; Phan, M.D.; Petty, N.K.; Bachmann, N.; Szubert, M.; Sidjabat, H.E.; Paterson, D.L.; Upton, M.; et al. Insights into a Multidrug Resistant Escherichia coli Pathogen of the Globally Disseminated ST131 Lineage: Genome Analysis and Virulence Mechanisms. PLoS ONE 2011, 6, e26578. [Google Scholar] [CrossRef] [Green Version]
  70. Mojica, M.F.; Bonomo, R.A.; Fast, W. B1-Metallo-β-Lactamases: Where Do We Stand? Curr. Drug Targets 2016, 17, 1029–1050. [Google Scholar] [CrossRef]
  71. Palzikill, T. Metallo-β-lactamase structure and function. Ann. N. Y. Acad. Sci. 2013, 1277, 91–104. [Google Scholar] [CrossRef] [PubMed]
  72. Crowder, M.W.; Spencer, J.; Vila, A.J. Metallo-beta-lactamases: Novel weaponry for antibiotic resistance in bacteria. Acc. Chem. Res. 2006, 39, 721–728. [Google Scholar] [CrossRef] [PubMed]
  73. Tooke, C.L.; Hinchliffe, P.; Bragginton, E.C.; Colenso, C.K.; Hirvonen, V.H.A.; Takebayashi, Y.; Spencer, J. β-Lactamases and β-Lactamase Inhibitors in the 21st Century. J. Mol. Biol. 2019, 431, 3472–3500. [Google Scholar] [CrossRef] [PubMed]
  74. Sykes, R.B.; Bonner, D.P. Aztreonam: The first monobactam. Amer. J. Med. 1985, 78, 2–10. [Google Scholar] [CrossRef]
  75. Yong, D.; Toleman, M.A.; Giske, C.G.; Cho, H.S.; Sundman, K.; Lee, K.; Walsh, T.R. Characterization of a new metallo-beta-lactamase gene, bla(NDM-1), and a novel erythromycin esterase gene carried on a unique genetic structure in Klebsiella pneumoniae sequence type 14 from India. Antimicrob. Agents Chemother. 2009, 53, 5046–5054. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  76. Bush, K. A resurgence of beta-lactamase inhibitor combinations effective against multidrug-resistant Gram-negative pathogens. Int. J. Antimicrob. Agents. 2015, 46, 483–493. [Google Scholar] [CrossRef]
  77. Nordmann, P.; Dortet, L.; Poirel, L. Carbapenem resistance in Enterobacteriaceae: Here is the storm! Trends Mol. Med. 2012, 18, 263–272. [Google Scholar] [CrossRef]
  78. Queenan, A.M.; Bush, K. Carbapenemases: The versatile beta-lactamases. Clin. Microbiol. Rev. 2007, 20, 440–458. [Google Scholar] [CrossRef] [Green Version]
  79. Bebrone, C. Metallo-beta-lactamases (classification, activity, genetic organization, structure, zinc coordination) and theirsuperfamily. Biochem. Pharmacol. 2007, 74, 1686–1701. [Google Scholar] [CrossRef]
  80. Peirano, G.; Schreckenberger, P.; Pitout, J.D.D. Characteristics of NDM-1-producing Escherichia coli isolates that belong to the successful and virulent clone ST131. Antimicrob. Agents Chemother. 2011, 55, 2986–2988. [Google Scholar] [CrossRef] [Green Version]
  81. Talbot, G.H.; Bradley, J.; Edwards, J.E., Jr.; Gilbert, D.; Scheld, M.; Bartlett, J.G.; Antimicrobial Availability Task Force of the Infectious Diseases Society of America. Bad bugs need drugs: An update on the development pipeline from the Antimicrobial Availability Task Force of the Infectious Diseases Society of America. Clin. Infect. Dis. 2006, 42, 657–668. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  82. Cervantes, C.; Guangyong, J.; Ramírez, J.L.; Silver, S. Resistance to arsenic compounds in microorganisms. FEMS Microbiol. Rev. 1994, 15, 355–367. [Google Scholar] [CrossRef] [PubMed]
  83. Jones, F.T. A broad view of arsenic. Poult. Sci. 2007, 86, 2–14. [Google Scholar] [CrossRef]
  84. Igiri, B.E.; Okoduwa, S.I.R.; Idoko, G.O.; Akabuogu, E.P.; Adeyi, A.O.; Ejiogu, I.K. Toxicity and Bioremediation of Heavy Metals Contaminated Ecosystem from Tannery Wastewater: A Review. J. Toxicol. 2018, 2018, 2568038. [Google Scholar] [CrossRef] [PubMed]
  85. Paez-Espino, D.; Tamames, J.; de Lorenzo, V.; Cánovas, D. Microbial responses to environmental arsenic. Biometals 2009, 22, 117–130. [Google Scholar] [CrossRef] [PubMed]
  86. Fekih, I.B.; Zhang, C.; Li, Y.P.; Zhao, Y.; Alwathnani, H.A.; Saquib, Q.; Rensing, C.; Cervantes, C. Distribution of Arsenic Resistance Genes in Prokaryotes. Front. Microbiol. 2018, 9, 2473. [Google Scholar] [CrossRef]
  87. Hedges, R.W.; Baumberg, S. Resistance to Arsenic Compounds Conferred by a Plasmid Transmissible Between Strains of Escherichia coli. J. Bacteriol. 1973, 115, 459–460. [Google Scholar] [CrossRef] [Green Version]
  88. Chen, C.M.; Mobley, H.L.; Rosen, B.P. Separate resistances to arsenate and arsenite (antimonate) encoded by the arsenical resistance operon of R factor R773. J. Bacteriol. 1985, 161, 758–763. [Google Scholar] [CrossRef] [Green Version]
  89. Mukhopadhyay, R.; Rosen, B.P.; Phung, L.T.; Silver, S. Microbial arsenic: From geocycles to genes and enzymes. FEMS Microbiol. Rev. 2002, 26, 311–325. [Google Scholar] [CrossRef]
  90. Cabanel, N.; Galimand, M.; Bouchier, C.; Chesnokova, M.; Klimov, V.; Carniel, E. Molecular bases for multidrug resistance in Yersinia pseudotuberculosis. Int. J. Med. Microbiol. 2017, 307, 371–381. [Google Scholar] [CrossRef]
  91. Johnson, J.R.; Owens, K.L.; Clabots, C.R.; Weissman, S.J.; Cannon, S.B. Phylogenetic relationships among clonal groups of extraintestinal pathogenic Escherichia coli as assessed by multi-locus sequence analysis. Microbes Infect. 2006, 8, 1702–1713. [Google Scholar] [CrossRef] [PubMed]
  92. Lemire, J.A.; Harrison, J.J.; Turner, R.J. Antimicrobial activity of metals: Mechanisms, molecular targets and applications. Nat. Rev. Microbiol. 2013, 11, 371–384. [Google Scholar] [CrossRef] [PubMed]
  93. Hosny, A.E.D.M.S.; Rasmy, S.A.; Aboul-Magd, D.S.; Kashef, M.T.; El-Bazz, Z.E. The increasing threat of silver-resistance in clinical isolates from wounds and burns. Infect. Drug Resist. 2019, 12, 1985–2001. [Google Scholar] [CrossRef] [Green Version]
  94. Randall, C.P.; Gupta, A.; Jackson, N.; Busse, D.; O’Neill, A.J. Silver resistance in Gram-negative bacteria: A dissection of endogenous and exogenous mechanisms. J. Antimicrob. Chemoter. 2015, 70, 1037–1046. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  95. Rensing, C.; Moodley, A.; Cavaco, L.M.; McDevitt, S.F. Resistance to Metals Used in Agricultural Production. Microbiol. Spectr. 2018, 6, 83–107. [Google Scholar] [CrossRef] [PubMed]
  96. Elkrewi, E.; Randall, C.P.; Ooi, N.; Cottell, J.L.; O’Neill, A.J. Cryptic silver resistance is prevalent and readily activated in certain Gram-negative pathogens. Antimicrob. Chemother. 2017, 72, 3043–3046. [Google Scholar] [CrossRef]
  97. McHugh, G.L.; Moellering, R.C.; Hopkins, C.C.; Swartz, M.N. Salmonella typhimurium resistant to silver nitrate, chloramphenicol, and ampicillin. Lancet 1975, 1, 235–240. [Google Scholar] [CrossRef]
  98. Asiani, K.R.; Williams, H.; Bird, L.; Jenner, M.; Searle, M.S.; Hobman, J.L.; Scott, D.J.; Soultanas, P. SilE is an intrinsically disordered periplasmic “molecular sponge” involved in bacterial silver resistance. Mol. Microbiol. 2016, 101, 731–742. [Google Scholar] [CrossRef]
  99. Qin, W.; Liu, X.; Yu, X.; Chu, X.; Tian, J.; Wu, N. Identification of cadmium resistance and adsorption gene from Escherichia coli BL21 (DE3). RSC Adv. 2017, 7, 51460–51465. [Google Scholar] [CrossRef] [Green Version]
  100. Qin, W.; Zhao, J.; Yu, X.; Liu, X.; Chu, X.; Tian, J.; Wu, N. Improving Cadmium Resistance in Escherichia coli Through Continuous Genome Evolution. Front. Microbiol. 2019, 10, 278. [Google Scholar] [CrossRef]
  101. Klaassen, C.D.; Liu, J.; Diwan, B.A. Metallothionein protection of cadmium toxicity. Toxicol. Appl. Pharmacol. 2009, 238, 215–220. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  102. Yazdankhah, S.; Skjerve, E.; Wasteson, Y. Antimicrobial resistance due to the content of potentially toxic metals in soil and fertilizing products. Microb. Ecol. Health Dis. 2018, 29, 1548248. [Google Scholar] [CrossRef] [PubMed]
  103. Satir, S. The relationship between oral cancer and cadmium: A review. Mol Biol. Rep. 2021, 49, 2413–2419. [Google Scholar] [CrossRef] [PubMed]
  104. Bhattacharyya, K.; Sen, D.; Laskar, P.; Saha, T.; Kundu, G.; Chaudhuri, A.G.; Ganguly, S. Pathophysiological effects of cadmium(II) on human health—A critical review. J. Basic Clin. Physiol. Pharmacol. 2021. [Google Scholar] [CrossRef] [PubMed]
  105. Huang, F.; Guo, C.L.; Lu, G.N.; Yi, X.Y.; Zhu, L.D.; Dang, Z. Bioaccumulation characterization of cadmium by growing Bacillus cereus RC-1 and its mechanism. Chemosphere 2014, 109, 134–142. [Google Scholar] [CrossRef] [PubMed]
  106. Mazhar, S.H.; Li, X.; Rashid, A.; Su, J.; Xu, J.; Brejnrod, A.D.; Su, J.Q.; Wu, Y.; Zhu, Y.G.; Zhou, S.G.; et al. Co-selection of antibiotic resistance genes, and mobile genetic elements in the presence of heavy metals in poultry farm environments. Sci. Total Environ. 2021, 755, 142702. [Google Scholar] [CrossRef]
  107. Rensing, C.; Grass, G. Escherichia coli mechanisms of copper homeostasis in a changing environment. FEMS Microbiol. Rev. 2003, 27, 197–213. [Google Scholar] [CrossRef] [Green Version]
  108. Jain, S.; Bhatt, A. Proteomic Analysis of Diversified Extremophilic Strains of Pseudomonas in the Presence of Cadmium. Agric. Res. J. 2013, 2, 354–359. [Google Scholar] [CrossRef] [Green Version]
  109. Pan, Y.; Pan, Y.; Zhai, J.; Xiong, Y.; Li, J.; Du, X.; Su, C.; Zhang, X. Cucumber Metallothionein-Like 2 (CsMTL2) Exhibits Metal-Binding Properties. Genes 2016, 7, 106. [Google Scholar] [CrossRef] [Green Version]
  110. Binet, M.R.B.; Poole, R.K. Cd(II), Pb(II) and Zn(II) ions regulate expression of the metal-transporting P-type ATPase ZntA in Escherichia coli. FEBS Lett. 2000, 473, 67–70. [Google Scholar] [CrossRef] [Green Version]
  111. Hill, G.M.; Shannon, M.C. Copper and Zinc Nutritional Issues for Agricultural Animal Production. Biol. Trace Elem. Res. 2019, 188, 148–159. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  112. European Commissions Scientific Committee for Animal Nutrition (SCAN). Opinion of the Scientific Committee for Animal Nutrition on the Use of Copper in Feeding Stuffs; European Commissions Scientific Committee for Animal Nutrition: Brussels, Belgium, 2003; pp. 1–47. [Google Scholar]
  113. Poole, K. At the Nexus of Antibiotics and Metals: The Impact of Cu and Zn on Antibiotic Activity and Resistance. Trends Microbiol. 2017, 25, 820–832. [Google Scholar] [PubMed]
  114. Chandrangsu, P.; Rensing, C.; Helmann, J.D. Metal homeostasis and resistance in bacteria. Nat. Rev. Microbiol. 2017, 15, 338–350. [Google Scholar] [CrossRef] [PubMed]
  115. Ghazisaeedi, F.; Ciesinski, L.; Bednorz, C.; Johanns, V.; Pieper, L.; Tedin, K.; Wieler, L.H.; Günther, S. Phenotypic zinc resistance does not correlate with antimicrobial multi-resistance in fecal E. coli isolates of piglets. Gut Pathog. 2020, 12, 4. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  116. Argüello, J.M.; Eren, E.; González-Guerrero, M. The structure and function of heavy metal transport P1B-ATPases. Biometals 2007, 20, 233–248. [Google Scholar] [CrossRef] [PubMed]
  117. Outten, F.W.; Huffman, D.L.; Hale, J.A.; O’Halloran, T.V. The independent cue and cus systems confer copper tolerance during aerobic and anaerobic growth in Escherichia coli. J. Biol. Chem. 2001, 276, 30670–30677. [Google Scholar] [CrossRef] [Green Version]
  118. Tetaz, T.J.; Luke, R.K. Plasmid-controlled resistance to copper in Escherichia coli. J. Bacteriol. 1983, 154, 1263–1268. [Google Scholar] [CrossRef] [Green Version]
  119. Brown, N.L.; Barrett, S.R.; Camakaris, J.; Lee, B.T.; Rouch, D.A. Molecular genetics and transport analysis of the copper-resistance determinant (pco) from Escherichia coli plasmid pRJ1004. Mol. Microbiol. 1995, 17, 1153–1166. [Google Scholar] [CrossRef]
  120. Crane, J.K.; Broome, J.E.; Reddinger, R.M.; Werth, B.B. Zinc protects against shiga-toxigenic Escherichia coli by acting on host tissues as well as on bacteria. BMC Microbiol. 2014, 14, 145. [Google Scholar] [CrossRef] [Green Version]
  121. Melin, L.; Wallgren, P. Aspects on feed related prophylactic measures aiming to prevent post weaning diarrhoea in pigs. Acta Vet. Scand. 2002, 43, 231–245. [Google Scholar] [CrossRef] [Green Version]
  122. Kwon, C.H.; Lee, C.Y.; Han, S.J.; Kim, S.J.; Park, B.C.; Jang, I.; Han, J.H. Effects of dietary supplementation of lipid-encapsulated zinc oxide on colibacillosis, growth and intestinal morphology in weaned piglets challenged with enterotoxigenic Escherichia coli. Anim. Sci. J. 2014, 85, 805–813. [Google Scholar] [CrossRef] [PubMed]
  123. Beard, S.J.; Hashim, R.; Wu, G.; Binet, M.R.; Hughes, M.N.; Poole, R.K. Evidence for the transport of zinc(II) ions via the pit inorganic phosphate transport system in Escherichia coli. FEMS Microbiol. Lett. 2000, 184, 231–235. [Google Scholar] [CrossRef] [PubMed]
  124. Jackson, R.J.; Binet, M.R.; Lee, L.J.; Ma, R.; Graham, A.I.; McLeod, C.W.; Poole, R.K. Expression of the PitA phosphate/metal transporter of Escherichia coli is responsive to zinc and inorganic phosphate levels. FEMS Microbiol. Lett. 2008, 289, 219–224. [Google Scholar] [CrossRef] [Green Version]
  125. Vahjen, W.; Pietruszynska, D.; Starke, I.C.; Zentek, J. High dietary zinc supplementation increases the occurrence of tetracycline and sulfonamide resistance genes in the intestine of weaned pigs. Gut Pathog. 2015, 7, 23. [Google Scholar] [CrossRef] [Green Version]
  126. Bednorz, C.; Oelgeschlager, K.; Kinnemann, B.; Hartmann, S.; Neumann, K.; Pieper, R.; Bethe, A.; Semmler, T.; Tedin, K.; Schierack, P.; et al. The broader context of antibiotic resistance: Zinc feedsupplementation of piglets increases the proportion of multi-resistant Escherichia coli in vivo. Int. J. Med. Microbiol. 2013, 303, 396–403. [Google Scholar] [CrossRef]
  127. Seiler, C.; Berendonk, T.U. Heavy metal driven co-selection of antibiotic resistance in soil and water bodies impacted by agriculture and aquaculture. Front. Microbiol. 2012, 3, 399. [Google Scholar] [CrossRef] [Green Version]
  128. Pal, C.; Bengtsson-Palme, J.; Kristiansson, E.; Larsson, D.G.J. Co-occurrence of resistance genes to antibiotics, biocides and metals reveals novel insights into their co-selection potential. BMC Genom. 2015, 16, 964. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  129. Lee, L.J.; Barrett, J.A.; Poole, R.K. Genome-wide transcriptional response of chemostat-cultured Escherichia coli to zinc. J. Bacteriol. 2005, 187, 1124–1134. [Google Scholar] [CrossRef] [Green Version]
  130. Ghosh, A.; Singh, A.; Ramteke, P.W.; Singh, V.P. Characterization of large plasmids encoding resistance to toxic heavy metals in Salmonella abortus equi. Biochem. Biophys. Res. Commun. 2000, 272, 6–11. [Google Scholar] [CrossRef]
  131. Sabri, M.; Houle, S.; Dozois, C.M. Roles of the extraintestinal pathogenic Escherichia coli ZnuACB and ZupT zinc transporters during urinary tract infection. Infect. Immun. 2009, 77, 1155–1164. [Google Scholar] [CrossRef] [Green Version]
  132. Baker-Austin, C.; Wright, M.S.; Stepanauskas, R.; McArthur, J.V. Co-selection of antibiotic and metal resistance. Trends Microbiol. 2006, 14, 176–182. [Google Scholar] [CrossRef] [PubMed]
  133. Muzammil, S.; Hayat, S.; Fakhar-e-Alam, M.; Aslam, B.; Siddique, M.H.; Nisar, M.A.; Saqalein, M.; Atif, M.; Sarwar, A.; Khurshid, A.; et al. Nanoantibiotics: Future nanotechnologies to combat antibiotic resistance. Front. Biosci. 2018, 10, 352–374. [Google Scholar]
  134. Murugaiyan, J.; Kumar, A.; Rao, G.S.; Iskandar, K.; Hawser, S.; Hays, J.P.; Mohsen, Y.; Adukkadukkam, S.; Awuah, W.A.; Jose, R.A.M.; et al. Progress in Alternative Strategies to Combat Antimicrobial Resistance: Focus on Antibiotics. Antibiotics 2022, 11, 200. [Google Scholar] [CrossRef] [PubMed]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Longhi, C.; Maurizi, L.; Conte, A.L.; Marazzato, M.; Comanducci, A.; Nicoletti, M.; Zagaglia, C. Extraintestinal Pathogenic Escherichia coli: Beta-Lactam Antibiotic and Heavy Metal Resistance. Antibiotics 2022, 11, 328. https://doi.org/10.3390/antibiotics11030328

AMA Style

Longhi C, Maurizi L, Conte AL, Marazzato M, Comanducci A, Nicoletti M, Zagaglia C. Extraintestinal Pathogenic Escherichia coli: Beta-Lactam Antibiotic and Heavy Metal Resistance. Antibiotics. 2022; 11(3):328. https://doi.org/10.3390/antibiotics11030328

Chicago/Turabian Style

Longhi, Catia, Linda Maurizi, Antonietta Lucia Conte, Massimiliano Marazzato, Antonella Comanducci, Mauro Nicoletti, and Carlo Zagaglia. 2022. "Extraintestinal Pathogenic Escherichia coli: Beta-Lactam Antibiotic and Heavy Metal Resistance" Antibiotics 11, no. 3: 328. https://doi.org/10.3390/antibiotics11030328

APA Style

Longhi, C., Maurizi, L., Conte, A. L., Marazzato, M., Comanducci, A., Nicoletti, M., & Zagaglia, C. (2022). Extraintestinal Pathogenic Escherichia coli: Beta-Lactam Antibiotic and Heavy Metal Resistance. Antibiotics, 11(3), 328. https://doi.org/10.3390/antibiotics11030328

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop