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Review

Overview of Virulence and Antibiotic Resistance in Campylobacter spp. Livestock Isolates

by
Iulia Adelina Bunduruș
1,
Igori Balta
1,
Lavinia Ștef
1,
Mirela Ahmadi
1,
Ioan Peț
1,
David McCleery
1,2,* and
Nicolae Corcionivoschi
1,2,*
1
Faculty of Bioengineering of Animal Resources, University of Life Sciences King Mihai I from Timisoara, 300645 Timisoara, Romania
2
Bacteriology Branch, Veterinary Sciences Division, Agri-Food and Biosciences Institute, Belfast BT4 3SD, UK
*
Authors to whom correspondence should be addressed.
Antibiotics 2023, 12(2), 402; https://doi.org/10.3390/antibiotics12020402
Submission received: 1 February 2023 / Revised: 9 February 2023 / Accepted: 10 February 2023 / Published: 17 February 2023
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Abstract

:
Campylobacter remains the most prevalent foodborne pathogen bacterium responsible for causing gastroenteritis worldwide. Specifically, this pathogen colonises a ubiquitous range of environments, from poultry, companion pets and livestock animals to humans. The bacterium is uniquely adaptable to various niches, leading to complicated gastroenteritis and, in some cases, difficult to treat due to elevated resistance to certain antibiotics. This increased resistance is currently detected via genomic, clinical or epidemiological studies, with the results highlighting worrying multi-drug resistant (MDR) profiles in many food and clinical isolates. The Campylobacter genome encodes a rich inventory of virulence factors offering the bacterium the ability to influence host immune defences, survive antimicrobials, form biofilms and ultimately boost its infection-inducing potential. The virulence traits responsible for inducing clinical signs are not sufficiently defined because several populations have ample virulence genes with physiological functions that reflect their pathogenicity differences as well as a complement of antimicrobial resistance (AMR) systems. Therefore, exhaustive knowledge of the virulence factors associated with Campylobacter is crucial for collecting molecular insights into the infectivity processes, which could pave the way for new therapeutical targets to combat and control the infection and mitigate the spread of MDR bacteria. This review provides an overview of the spread and prevalence of genetic determinants associated with virulence and antibiotic resistance from studies performed on livestock animals. In addition, we have investigated the relevant coincidental associations between the prevalence of the genes responsible for pathogenic virulence, horizontal gene transfer (HGT) and transmissibility of highly pathogenic Campylobacter strains.

1. Introduction

Virulence and antibiotic resistance frequently arise at the same time, but the relationship between the two at the genetic level has been largely overlooked. Studies have associated virulence with multi-drug resistance in multiple animal infection models [1], but the regulation of virulence in the presence of antibiotic resistance remains unclear [2]. Antibiotic resistance and virulence can manifest through different forms of adaptative, innate and acquired resistance. The regulation of genes coding for virulence and antibiotic resistance is complex and interconnected, while environmental factors influence gene expression, making the regulation of these genes difficult. Common mechanisms involved in regulation serve as a link between antibiotic resistance and virulence [2]. Bacteria’s great ability to adapt to various environmental conditions, coupled with antibiotic pressure, has led to the rise and dispersion of antibiotic-resistant bacteria. The relationship between antibiotic resistance and virulence in bacterial pathogens depends on the species of bacteria, the specific mechanisms of virulence and resistance, the host and the ecological niche [3]. To effectively control the spread of antibiotic resistance, the control of increased virulence is also necessary, as it may evolve concurrently with antibiotic resistance. A better understanding of the interrelated regulation of antibiotic resistance and virulence can lead to more directed and specific drug treatments [2].
Hospital-acquired diseases caused by antibiotic-resistant bacteria derive from complex interactions between various dynamic factors, including fitness costs, bacterial pathogenicity and selective pressures from antibiotic therapy. The rise and aftermath of mutations that confer antibiotic resistance are shaped by these interactions. Mutations that increase antibiotic resistance can either cause decreased or increased pathogenic potential. Further research is needed to elucidate the origin of altered virulence potential in pathogens displaying antibiotic resistance and to better understand the modulating implications of resistance traits on disease outcomes. Additionally, it is important to note that the disease process itself generates selective pressures that constrain the resistance spectrum [4]. For example, in response to different antibiotic levels, Acinetobacter baumannii augments its virulence, altering its normally low virulence into one that induces lethal disease [5]. This ability was observed in the presence of erythromycin and chloramphenicol resistance, which temporarily enhance the production of capsular exopolysaccharide via triggering a transcriptional response by targeting the 50S ribosome [6]. Research has shown that antibiotic use can affect the expression of virulence genes. However, the relationship between genes that confer virulence and antibiotic resistance is highly intricate. Previously, it was believed that these events were regulated separately, but recent studies unveiled that genetic regulation is closely connected and intertwined [4,7,8].
The development of “new-generation” antibiotics, which are mostly derivatives of already existing classes, has been followed by the rise of antibiotic-resistant bacterial strains [9]. The spread of antimicrobial resistance is largely facilitated by horizontal gene transfer (HGT), with acquired resistance primarily propagated through three mechanisms: mobile genetic elements, the acquisition of DNA originating from the environment, or transfection by bacteriophages [10]. The acquisition of antibiotic resistance can not only impact virulence but also lead to the co-selection of both traits through mobile genetic elements through mechanisms of transfer, such as conjugation, transformation and transduction among bacterial strains of the same or different species. Plasmids, which are extra-chromosomal elements, can also confer attributes such as resistance, virulence and persistence to bacteria, aiding their adaptation to various environments and niches [11]. The regulation of virulence-encoding genes is intricately intertwined with that of genes responsible for antimicrobial resistance, and both are indirectly and ultimately influenced by environmental factors [2]. Figure 1 provides a comprehensive illustration of the mechanisms and factors that govern the regulation of this gene set.
Concerns are rising regarding the presence of antibiotic-resistance genes and virulence-associated genes in food-producing animals and humans. These genes, considered environmental pollutants, can cause severe complications for animals and humans. Misuse and overuse of antibiotics are accelerating the problem of increasing antimicrobial resistance and posing a threat to all inhabitants on earth [12]. Thus, the emergence and spread of ARGs have become the primary obstacle in managing infectious diseases [13]. It is crucial to identify antibiotic resistance patterns and the pathogenicity of bacteria to minimise complications and treatment failure in infections caused by multidrug-resistant pathogens. Recent research found that waterfowls may act as a significant reservoir of these strains, which can spread into the environment through water, meat, carcasses and droppings, posing a threat to human health. Therefore, surveillance programs are needed to regulate the use of antibiotics and ensure clinical prescriptions are based on antibiograms in both veterinary and human medicine [14].
It has been observed that various species within the Campylobacter genus can exchange genetic material with one another, as well as with other bacterial genera [15,16,17,18,19,20]. This facilitates the transfer of genes that enhance the virulence of Campylobacter and allow it to withstand exposure to antibiotics. This bacterial genus is widely present in multiple hosts, including humans, animals, food products and the environment. The interconnected nature of these factors presents challenges for effectively addressing the potential negative consequences for human and animal health. Exposure to the recent relevant discoveries concerning virulence factors and emphasising the genomic diversity and plasticity of Campylobacter makes it inconceivable to control its spread and evolution. However, monitoring the molecular changes could pave the way to a better understanding of the pathogenicity of evolution and virulence in humans, animals and the environment. Clearly, our review is not aiming to identify a genetic relationship between antibiotic resistance and virulence since it has been shown that there is no linkage between virulence and antibiotic resistance at either the chromosomal or plasmid levels [21], but rather try to provide the coincidental data most recently published. This review only provides an overview of the spread and prevalence of genes associated with virulence, including the genes conferring resistance to antibiotics in Campylobacter species belonging to different sources and hosts. We also showed associations between the prevalence of the genes responsible for pathogenic virulence, horizontal gene transfer (HGT) and transmissibility of highly pathogenic Campylobacter strains.

2. Campylobacter spp. Overview

The Campylobacter genus represents a well-known group of foodborne pathogens responsible for causing self-limited gastroenteritis in humans, which sometimes requires antimicrobial treatment due to the potential for serious complications [22]. In the European Union, campylobacteriosis was the most frequently reported zoonosis in humans, with a total of 127,840 confirmed cases and with the majority of Campylobacter spp. being detected in all major animal categories, including pigs, broilers, small ruminants, cattle, cats and dogs [23]. However, data from the last 20 years also includes livestock as a reservoir for the emergence of methicillin-resistant Staphylococcus aureus, Clostridium difficile and Escherichia coli, besides Campylobacter and Salmonella, with an increased impact on human health. Mitigation measures, such as increased biosecurity or vaccines, are proposed as solutions to reduce antimicrobial use in livestock [24]. Natural antimicrobials (e.g., plant extracts) could represent one of the solutions able to reduce antibiotic usage in livestock since they have been shown to reduce Campylobacter spp. poultry gut colonisation and virulence, both in vitro and in vivo [25]. The positive impact of these mitigation measures extends to other bacterial species, such as Staphylococcus aureus and Clostridium difficile [26] and could potentially prevent and alleviate viral infections [27]. These novel solutions are very useful to farmers as recently it has been reported that cattle and chickens are an important reservoir of campylobacters, associated with human disease, and resistant to erythromycin, ampicillin, tetracycline, nalidixic acid and ciprofloxacin [28]. Measures implemented at the slaughterhouse, rather than at the farm, must also be considered since contamination can also occur in such environments [29]; however, the management involved in farming activities seems to take priority in preventing Campylobacter spp. spreading in livestock [30]. The availability of such mitigation measures will prevent the overuse of antibiotics in livestock production, which lead to a high prevalence of Campylobacter spp. from chickens and pigs to macrolides suggesting that continuous surveillance is required to reduce the antibiotic-resistant campylobacteriosis in livestock and humans [31].
Infections with Campylobacter spp. can have various clinical consequences in animals as well, including reproductive failures in ruminants. For example, C. fetus subsp. venerealis induces cattle infertility, C. fetus subsp. fetus causes abortions in goats, sheep and cattle, and C. hepaticus causes spotty liver disease in layer hens [19,32]. The origin of these strains is of particular importance, and it has been proposed that C. hepaticus in chickens may have an environmental origin [33,34]. The widespread resistance of Campylobacter to β-lactams, tetracyclines, fluoroquinolones and macrolides emphasises the importance of ongoing susceptibility testing. The global crisis of multi-drug resistance (MDR) among bacteria is of significant public health concern, prompting efforts to restrict or eliminate antibiotic use across sectors, including their use in animal feed and for metaphylaxis. In 2019, the European Union implemented a regulation addressing the use of antibiotics in metaphylaxis [35]. Resistance to antibiotics can be acquired by activating a diverse set of molecular mechanisms, namely by inactivating the drug, altering the target of the antimicrobial, expressing antibiotic efflux pumps or decreasing membrane permeability [36].
Antibiotic resistance in Campylobacter can be acquired through various mechanisms, including drug inactivation, target alteration, modification of the antibiotic efflux pumps and decreasing membrane permeability [36]. Macrolides resistance is mainly caused by point mutations of the 23S rRNA gene within its V domain or by the presence of the cmeABC operon encoding for multidrug efflux pump [37,38]. The presence of the tetO gene, which encodes a protective ribosomal protein, is generally associated with resistance to tetracycline [39]. Resistance to fluoroquinolones is frequently related to point mutation(s) in the DNA gyrase gene (gyrA) gene within the quinolone resistance-determining region (QRDR). Other genes associated with Campylobacter MDR are the aadE or sat4 (streptomycin/streptothricin resistance), ermB (erythromycin resistance), aphA-3 (aminoglycosides resistance) and blaOXA-61 (b-lactams resistance) genes [40]. Ultimately, these mechanisms contribute to antibiotic ineffectiveness and the development of multi-drug resistance. The overuse of antimicrobials in human medicine and the misuse of antibiotics in animal husbandry are significant contributing factors to the increased rates of antibiotic resistance among Campylobacter species [40]. All these antibiotic-resistance genes (ARGs) are also present in plants, animals, human hosts and generally in all natural environments, and their transmission and migration can be more dangerous than antibiotics (Figure 2).
The dissemination of these genes between host bacterial cells occurs through horizontal gene transfer (HGT) or vertical gene transfer (VGT). The HGT process relies on the transfer of genetic material via mobile genetic elements (MGEs) such as phages, plasmids, transposons and integrons [41,42]. MDR may be facilitated by these critical MGEs, particularly plasmids, which harbour drug-resistance genes and can be transmitted between bacterial populations [43]. The acquisition of plasmids can enhance the adaptive capabilities and ecological scopes of bacterial populations by providing new traits and modulating gene expression and mutation rates. The incorporation of plasmids is often accompanied by the acquisition of novel traits that allow bacteria, including pathogens, to inhabit specific environments [44]. Notably, unlike plasmid-mediated HGT, HGT mediated by phages is mainly limited within species because phage transmission is restricted by the similarity of the hosts’ genetic material [42,45].
The persistence of plasmids in bacterial populations has been studied due to their potential negative impact on host fitness. Empirical data suggests that plasmids can persist for extended periods, even in the absence of positive selection for their traits, which presents a challenge to understanding the mechanisms of plasmid persistence [46]. They also exhibit a wide range of sizes, with some being designated as “megaplasmids” due to their particularly large size. While there is no strict criterion for distinguishing megaplasmids from other large plasmids, the size threshold for what is considered a megaplasmid has varied [47].
Plasmid-encoded antibiotic resistance is a well-studied trait and is becoming increasingly important in clinical settings [47]. Consequently, the main mechanism for ARG spread is HGT. Antimicrobials have been broadly administered within farm animal husbandry and healthcare facilities to promote animal husbandry and prevent or treat bacterial infections. Consequently, this resulted in an overload of antimicrobials generated antibiotic residues in farm soils, sewage treatment plants, clinical settings and other sites [42]. The dissemination of ARGs through the environment via wastewater irrigation and manure application has the potential to impact plant and human health. Research has shown that antibiotic-resistant E. coli can migrate within plants and transfer ARGs through HGT. The use of antimicrobials in healthcare settings also leads to the occurrence of antibiotic-resistant bacteria in domestic wastewater, which can be a source of horizontal gene transfer of ARGs in municipal wastewater treatment facilities [41]. Moreover, it has been demonstrated that E. coli strains isolated from wastewater successfully transfer resistance genes and all together give rise to antibiotic resistance phenotypes [48].
The pathogenic character of Campylobacter resides in the diversity of its virulence factors, including invasion of epithelial cells, adhesion to the intestinal mucosa, toxicity, motility and chemotaxis, as well as surface structure [33,49]. Adhesion-related virulence factors include the cadF gene, encoding the Campylobacter adhesion protein to fibronectin (CadF), the flaA gene, encoding the major flagellin protein FlaA and the docA gene, encoding a periplasmic cytochrome C peroxidase. Other adhesion-associated factors include the FlpA, PEB1, MOMP, HtrA, CapA and JlpA [33]. Among significant virulence markers linked with invasion encompass the Campylobacter invasion antigen conferred by the ciaB gene, phospholipase A encoded by the pldA gene, invasion-associated marker (encrypted by the iam gene) and the virB11 gene [40,50]. The flagella and chemotaxis factors are mainly involved in processes of mucosal colonisation, adhesion and invasion, as well as in biofilm formation. The surface structures associated with the virulence of Campylobacter spp. consist of capsular polysaccharide (CPS), lipooligosaccharide (LOS) and S-layer proteins. CPS participates in the invasion, adherence, intestinal colonisation and systemic infection, withstanding complement-mediated killing, while LOS is a mediator of invasion and adherence. LOS activates Toll-like receptor 4-mediated innate immunity and resists killing via cationic antimicrobial peptides. The S-layer proteins are relevant to immune evasion and resist complement-mediated killing [33]. Of all the toxins produced by Campylobacter spp., the most characterised is the cytolethal distending toxin (CDT) encoded by the cdtABC operon. Some genes have been associated with GBS occurrence, namely cgtB and wlaN genes, which both encode a β-1,3-galactosyltransferase enzyme involved in the production of sialylated lipooligosaccharide (LOSSIAL) [50].

3. Distribution of Virulence-Associated Genes across Different Campylobacter spp. Hosts

Campylobacter spp. was initially identified as a cause of animal disease in 1909, but it was not until 1980 that it was discovered that it also induces human infection [51]. This genus is commonly found in the intestinal tract of warm-blooded animals, including poultry, ruminants and swine, and can be transmitted to humans through the consumption of contaminated food or water or through close contact with infected animals [52]. Despite their inability to thrive outside the digestive tracts of homeotherms, pathogenic Campylobacter spp. is capable of surviving in food products for long periods of time. These bacteria are usually sensitive to environmental stress but have developed various mechanisms for survival in the environment and the food chain, which can lead to human infection [52]. Thermophilic Campylobacter spp. are widely distributed in the environment, which ultimately serves as an intermediate link between different hosts and habitats in the transmission of this bacterial pathogen [53,54]. Determining the virulence markers that contribute to the pathogenesis of campylobacteriosis is critical for identifying potentially more virulent strains and for gaining a deeper understanding of the mechanisms of infection [33,55]. Consequently, Table 1 shows a summary of genes related to virulence that have been detected in different Campylobacter spp. recovered from various animal and human hosts, including the environment.

4. Virulence and Antibiotic Resistance of Campylobacter spp. Poultry Isolates

Given the large spectrum of available data from poultry and because of the different approaches taken in these studies, connecting increased/decreased virulence with the levels of antibiotic resistance is difficult. Campylobacter spp. colonises the mucosa of the cecum and cloaca crypts in infected chickens and may also be present in other organs such as the spleen and liver [52]. A genomic analysis performed on C. jejuni isolates recovered from avian and human samples in Egypt revealed the presence of the flaA gene in all C. jejuni isolates, while the cdtA, cdtB and cdtC genes were present together in only ≈58.54% of the strains. None of the isolates displayed a concomitant presence of all the virulence genes screened (i.e., flaA, cdtA, cdtB and cdtC, virB11, wlaN, iam) in this study. Moreover, the cdtC gene revealed high similarity among C. jejuni isolates investigated, while the iam and cdtB genes showed the lowest similarity. Notably, the analysed strains unveiled 13 novel alleles. The C. jejuni strains obtained from the same host showed high heterogeneity, although the isolates recovered from chicken strains displayed the highest diversity [56]. Similarly, the virulence factors of 113 C. jejuni isolates obtained from poultry, and human sources were investigated by Ammar et al. (2021) in Egypt. All tested isolates unveiled the presence of the flaA gene, while 52% displayed the presence of the virB11 gene, and 36% encoded the wlaN gene [57].
Also, based on genome analysis of two fluoroquinolones (FQs) resistant Campylobacter chicken isolates (C. jejuni 200605 and C. coli 200606), it was revealed that strain 200605 is more virulent than strain 200606. This observation was based on the identification of cadF, pebA, jlpA (adhesion), ciaBC (invasion), cdtABC (toxin production), flgSR, as well as eptC (biofilm formation) genes only in the C. jejuni strain 200605. Similarities we only identified in regard to genes cheAVW (chemotaxis), gmh, waa, kps (capsule formation), kpsDEFCST (capsular genes) and hldE (LPS-associated gene). Notably, genes expressing capsular biosynthesis were detected in C. coli strain 200606, namely Cj1416c, Cj1417c, Cj1419c and Cj1420c, suggesting potential genetic exchange between C. coli and C. jejuni species [18]. The same authors analysed the presence of virulence factors in 55 Campylobacter (C. jejuni and C. coli) isolates originating from a layer farm in South Korea. The presence of the cdtB, cstII, cadF, dnaJ and flaA genes was reported in all of the isolates, while no strain was positive for the ggt gene. The prevalence of csrA, pldA and ciaB genes varied between 33.3 and 95.9% [59]. All 55 tested isolates showed resistance to ciprofloxacin and nalidixic acid, while tetracycline resistance was observed in 93.9% and 83.3% of the C. jejuni and C. coli strains, respectively. Furthermore, all tested isolates showed susceptibility to sitafloxacin, as well as low erythromycin and gentamicin resistance and the presence of both gyrA gene point mutation and tetO gene was reported [59].
The antibiotic resistance and virulence factors of C. jejuni were also investigated in Brazilian slaughterhouse isolates from two different time periods (2011–2012; 2015–2016). The antimicrobial-resistant isolates, including those displaying multidrug resilience, were significantly more prevalent in 2011–2012, except for tetracycline. More prevalence rates were observed regarding C. jejuni isolation. However, the virulence genes revealed higher prevalence among the isolates from 2015 to 2016. All isolates were also tested for seven virulence-associated genes, namely ciaB, flaA, pldA, cadF and cdtABC genes. Approximately 83.6% of the 2011–2012 C. jejuni isolates harboured at least one of the screened virulence genes, whereas the 2015–2016 isolates revealed a significantly higher prevalence (97.7%). Despite the low prevalence rate of 2015–2016 C. jejuni isolates, these strains revealed increased virulence potential compared to the 2011–2012 group [62]. More recently, the same authors performed a comparative analysis of 44 C. jejuni isolates obtained from chicken carcasses and 20 C. jejuni clinical strains. Regardless of origin, 43.7% of all tested isolates harboured the flaA, pldA, cadF, luxS, dnaJ, cbrA, ciaB, cdtABC, htrA, cstII, neuA and hcp genes, while none of the analysed genomes displayed the presence of pVir genes. Their results indicated that the chicken isolates were more pathogenic than the human strains. The cadF, pldA and ciaB genes showed higher prevalence among the isolates obtained from chicken carcasses. Moreover, the ctdABC and luxS genes showed low prevalence among the clinical isolates, showing their presence in only 15% and 45% of human C. jejuni genomes [63].
The genetic elements of Gram-negative bacteria, such as integrons, may play an important role in the spread of resistance genes, given their presence in mobile genetic elements such as plasmids and transposons [93]. In South African C. jejuni chicken isolates, 26.92% of the tested isolates had more than two virulence-associated genes. For example, the ciaB, cdtA, cdtB, cdtC, pldA and cadF genes revealed 23.1%, 26.9%, 30.8%, 42.3%, 34.6% and 23.1% prevalence among the C. jejuni isolates, respectively. Integrons, particularly class I and II, play a crucial role in the transmission of antibiotic resistance and are frequently associated with the Tn7 transposon family [94,95,96]. Class I integrons have been found in Campylobacter, but neither class II nor class III integrons have been detected in these species [97]. However, 92.3% of C. jejuni isolates displayed the presence of Class I integrons, whereas 65.4% of the tested isolates harboured Class II integrons [66].
An earlier comparative analysis regarding the aerotolerance, virulence-associated genes and antimicrobial resistance of C. jejuni isolates derived from chicken and duck meat showed that virulence factors were more prevalent in the C. jejuni strains obtained from retail chicken meat, while the duck meat isolates displayed a more increased prevalence of antibiotic resistance. Notably, the findings of this study were the first ones to present aerotolerant duck meat C. jejuni isolates. Particularly, the isolates obtained from duck meat displayed a more inferior prevalence for ciaB and cdtB genes than chicken isolates, whereas the virB11 gene showed low prevalence in both cases. The iam gene was harboured by 97.8% of the chicken isolates, while the C. jejuni isolates obtained from duck meat revealed its presence in 88.9% of the tested isolates. PldA gene was present in 94.4% of the poultry isolates and 91.1% of the tested duck isolates. Both aerotolerant and hyper-aerotolerant C. jejuni strains isolated from duck meat revealed higher prevalence for the cadF, peb1, pldA and docA genes in contrast to the oxygen-sensitive strains [74]. The prevalence of virulence markers in 220 Campylobacter isolates from ducks in southwestern China revealed that the most prevalent virulence-associated genes were cadF, cheY and cdtB, present in 100%, 92.7% and 92.3% of the isolates. Other highly prevalent virulence determinants consisted of flaA, iamA, cdtA, cdtC and ciaB, harbouring 77.2%, 71.8%, 60%, 54.1% and 42.7% of the isolates of interest. The virB11 gene was detected in only 7.7% of the isolates. Collectively, the C. jejuni strains displayed a higher number of virulence genes when compared to C. coli [75].

5. Campylobacter spp. Isolates Originating from Wild Birds

Wild birds can serve as vectors for the transmission of Campylobacter spp., either directly or indirectly, due to their high mobility. Many free-living and migratory birds serve as reservoirs for pathogenic Campylobacter species, which can cause illness in humans. While the risk of human infection from zoonotic agents in wild birds is low, it is considered a growing concern [80]. In a recent study, researchers collected 91 cloacal swabs from various wildlife waterfowl species to evaluate the genetic diversity and prevalence of Campylobacter spp. The flaA, racR, docA, cadF and dnaJ genes were present in all white-fronted geese and bean geese isolates, while a high prevalence (66.7–100%) was observed among both graylag geese and mallards. The ciaB gene displayed high prevalence rates among bean geese, greylag geese, white-fronted geese and mallards isolates. Likewise, the pldA gene was also positively prevalent in the bean, white-fronted geese and mallards isolates. Only the strains originating from mallards sheltered the virB11 and iam genes, showing 40% and 10% frequency, respectively. All isolates obtained from graylag, bean and white-fronted geese harboured the cdtB and cdtC genes, while only 55% and 75% of the mallard isolates carried these genes. The Campylobacter isolates originating from white-fronted geese, mallards, and greylag geese displayed the presence of the cdtA gene in a proportion of 80%, 60% and 33.3% of the investigated strains, respectively. The cgtB gene was carried by 20%, 33.3% and 20% of white-fronted geese, graylag geese isolates and mallards, respectively, while the wlaN gene was only found in 5% of Campylobacter isolates originating from mallards. The results underlined that adhesion-associated genes (flaA, cadF, racR, dnaJ and docA) were highly prevalent among all tested isolates [50].
The variation of the cdtABC genes among Campylobacter isolates originating from humans, wild birds and broiler chickens reveals a high diversity of the cdtABC operon from the wild bird C. jejuni isolates, while both broiler and human isolates displayed high conservation of cdtABC. The cdtA gene showed a higher number of nucleotide substitutions and was less prevalent among the tested Campylobacter isolates compared to both cdtB and cdtC genes. Moreover, non-functional cdtABC operons were detected among the wild bird isolates. This study’s findings indicate that the cdtABC operon plays a key role in host-specific colonisation efficiency [76]. Others analysed 60 Campylobacter isolates originating from 12 species of wild birds from South Korea. All wild bird-derived Campylobacter isolates showed a high occurrence of all 11 tested virulence genes, while no correlation between any particular sequence type and a specific virulence profile was observed. The cadF gene was present in 100% of the Campylobacter spp. isolates. All C. coli isolates harboured the cdtB and cdtC genes, while C. jejuni strains carried them in 98.1% and 94.3% of the tested isolates, respectively. The wlaN gene was present in six C. jejuni isolates, while the virB11 gene was carried by 11.3% of C. jejuni and 28.6% of C. coli strains [80].
A whole genome sequencing (WGS) analysis recently performed by Aksomaitiene et al. (2021) on seven (wild birds and cattle) C. jejuni isolates from Lithuania enabled the identification of virulent genes involved in adhesion (cadF and peb1), cytotoxicity (cdtA, cdtB and cdtC) and invasion (yidC and yidD). In addition to this, two C. jejuni strains unveiled the presence of nine phage-specific genes. Two of the isolates revealed the presence of czc (Zn resistance), chr (Cr resistance), ncc (Ni resistance) and mer (Hg resistance) genes. Also, both cationic antimicrobial peptide system and platinum drug resistance (ctpA) genes were found in three of the isolates. The genomes of three C. jejuni isolates revealed the presence of virB2, virB4, virB8 and virB9 genes responsible for the type IV-secretion system T4SS). Trg, flgE (chemotaxis and flagellar motility) and bdlA (biofilm dispersion) genes were also identified [81].

6. Campylobacter spp. Isolates Originated from Ruminants and Swine

Campylobacter spp. also colonises the intestines of cattle and can cause miscarriages in cows and sheep, although they are usually asymptomatic. Campylobacter spp. can also be found in lymphatic nodes, on the surface of hooves, and in the bristles of ruminants. Both meat and dairy products can be contaminated with Campylobacter spp., with raw milk being especially susceptible to infection [52,98]. There is a significant positive correlation between adherence and invasion of the isolates derived from cattle and swine. The low invasion level was correlated with the absence of the virB11 gene. Moreover, the iam gene proved to be a trusted invasion-associated marker, and the gene pattern virB11-iam was ascribed to the isolates that presented the highest invasion level. This study showed a high prevalence for adherence (flaA, cadF and racR) and invasion (virB11, iam and pldA) associated genes in Campylobacter spp. isolates from Poland [82].
The virulence and the prevalence of antimicrobial determinants were described for the first time in sheep on Campylobacter isolates obtained from Pernambuco, Brazil. Out of the 40 tested strains, 27.5% belonged to C. jejuni, 30% to C. fetus subsp. fetus, and 42.5% of them were C. coli strains [83]. The cdtA gene was found in 92.5% of all tested isolates, while cdtB and cdtC genes were harboured by ≈75% and 70% of the Campylobacter strains, respectively. The cadF and racR genes also revealed high prevalence, namely 95% and 80%, while the dnaJ and ciaB genes were present in only 47.5% and 20% of the isolates, respectively. The pldA gene was found in only one C. jejuni isolate, while none of the strains carried the wlaN and virB11 genes. Additionally, the C257T point mutation of the gyrA gene was present in all Campylobacter strains, while the A256G mutation and point mutations A2074G and A2075G of 23S rRNA were absent [83].
In a separate study performed on 98 Campylobacter spp. isolates from pork, beef, unpasteurised dairy products and raw milk, all isolates sheltered the iam, racR, cdtB, sodB, csrA and virB11 genes. The wlaN gene was present in all isolates, regardless of source origin, except C. coli isolates originating from pork meat. The highest prevalence rate was observed for the cdtB, sodB and csrA genes [84]. A similar investigation determined the prevalence rates and virulence genes of Campylobacter spp. identified an overall 83.3% prevalence in pigs and 16.1% in calves. The most frequent species detected were C. jejuni, except in pig samples, where C. coli was more prevalent. C. jejuni isolates carried the cdtABC, peb3 (major antigenic peptide), Cj0020c (cytochrome C551 peroxidase) and pglG (N-linked glycosylation gene) genes, while the C. coli isolates only harboured the cdtB and cdtC genes [79].
Interestingly, researchers from Portugal have identified a previously undescribed species of Campylobacter by analysing 5 isolates recovered from preputial bull mucosa originating from a beef herd with a reproductive failure medical history. The isolates displayed microaerophilic, catalase-negative, oxidase-positive, non-motile and Gram-negative characteristics. The identified bacteria were proposed as a novel Campylobacter species via hsp60 and 16S rRNA genes analysis. The novel-defined Campylobacter portucalensis displays similarity to other Campylobacter species in terms of certain coding sequences, including genes encoding for adhesion and invasion, a type IV secretion system (T4SS) and antimicrobial resistance. The genome of C. portucalensis also revealed a high degree of homology with the T4SS of C. fetus subsp. venerealis. The pathogenic potential of C. portucalensis is currently unknown [99].

7. Recent Updates on Antibiotic Resistance among Campylobacter spp. Livestock Isolates

Recent data identified the presence of 18 distinct genetic determinants associated with antimicrobial resistance on either chromosomes or plasmids in Campylobacter spp. related to aminoglycosides, fluoroquinolones, β-lactams, lincosamides, phenicols, macrolides and tetracyclines. Compared to other Campylobacter species, C. coli genomes harboured both the highest number of antimicrobial resistance factors and a higher prevalence of multidrug genotypes. C. coli revealed the presence of 1 to 4 plasmids in 86.4% of the isolates, while C. jejuni isolates harboured 1 or 2 plasmids in only 14.1% of their genomes. Most antimicrobial resistance genes of C. coli were detected on plasmids, whereas other Campylobacter isolates revealed chromosomally encoded resistance. Collectively, only C. jejuni/C. coli isolates had antimicrobial resistance genes located on plasmids [100].
In poultry, fluoroquinolones and tetracycline resistance rates were higher among duck meat isolates compared to chicken isolates, while resistance to macrolides was detected in only a single duck C. jejuni isolate. Moreover, regardless of meat origin, gentamicin resistance was found in all tested isolates [74]. Earlier resistome analysis of 464 Campylobacter isolates obtained from chicken samples originating from various stages of the poultry production chain showed different patterns of virulence gene profiles between the C. jejuni and C. coli isolates. The C. jejuni isolates revealed the presence of 8 out of 9 investigated virulence factors, namely cadF, cdtABC, iamA, flaA, ciaB and cheY genes, while only three virulence-associated genes were detected in the C. coli isolates, including virB11, flaA and cheY genes. Aminoglycoside resistance was highly prevalent among the tested isolates, revealing the presence of aph(3′)-III, aph(2″)-If, ant(6)-Ia, aac(6′)-aph(2″) and aadE-Cc genes. Genes encoding for β-lactamases resistance were diverse, including blaOXA−456, blaOXA−184, blaOXA−460 and blaOXA−193. All tested Campylobacter strains carried the catA gene, while the fexA gene was reported in only two C. coli ST830 isolates. The lnuC gene was reported in 95% of the C. jejuni isolates, while the emrB gene was detected in only one C. coli ST872 isolate. The tetO gene was highly prevalent among both strains, while the tetL gene was present in 85% of the C. jejuni isolates and in only 15% of the C. coli isolates [61].
Likewise, the antimicrobial resistance determinants of 81 clinical Campylobacter strains from Santiago, Chile, revealed that C. jejuni and C. coli have 13 previously undescribed sequence types and alleles. All Campylobacter strains analysed showed the presence of the cmeABC operon, while a QRDR point mutation of the gyrA gene was present in only 53.1% of the isolates. The analysed strains maintained the tetO gene and a 23S rRNA mutation in 22.2% and 4.94% of the analysed strains. Notably, none of the strains unveiled the presence of the ermB gene, while 79% of the isolates displayed the presence of the blaOXA-61 gene [89]. Two clinical C. fetus isolates displayed resilience to streptomycin and sheltered aminoglycoside nucleotidyltransferase ant(6)-Ib. One of the isolates also revealed resistance to tetracycline and ciprofloxacin, conferred by the presence of the ribosomal protection protein tet44 and a mutation of the gyrA gene [101]. A recent WGS examination of 70 Campylobacter isolates presented a high genetic diversity among C. jejuni, and C. coli isolates derived from various ruminants (dairy cattle, beef cattle and sheep) from northern Spain. The C. coli isolates harboured various resistance encoding genes, such as aph(2″)-Ic, aph(3′)-III, ant(6)-Ia, aadE-Cc, aad9, tetO, tetO/M/O, blaOXA-489 and blaOXA-193 genes. The antimicrobial resistance genes detected in the C. jejuni isolates were ant(6)-Ia, blaOXA-184, blaOXA-193, blaOXA-461, blaOXA-61, tetO/32/O and tetO genes, as well as an rpsL K43R point mutation in only one C. jejuni isolate. Both C. jejuni and C. coli isolates showed the presence of aminoglycoside resistance clusters; however, none maintained the aadE-Cc gene. Eight out of twelve C. jejuni plasmids showed high similarity with pTet plasmids, carrying the tetO and T4SS-associated genes. One C. jejuni isolate included a plasmid-encoded tetO/32/O gene, while eleven of them acquired tetracycline resistance via the plasmid-encoded tetO gene. Notably, evenly distributed pTet plasmids were observed among all tested Campylobacter isolates, regardless of host origin. Quinolone resistance was encrypted by gyrA gene point mutations, namely C257T and T86I, which conferred resistance to ciprofloxacin and nalidixic acid. The A2075G point mutation of the 23S rRNA gene provided erythromycin resistance to seven C. coli isolates, while none of the tested isolates displayed the presence of the ermB gene. Moreover, no Campylobacter isolate presented to have cmeR and cmeABC operons [102].
In South African broilers, in 26 C. jejuni isolates, the highest antimicrobial resistance was detected to nalidixic acid (96.1%), tetracycline (80.7%) and erythromycin (84.6%), while resistance to ciprofloxacin was present in only 19.2%. The prevalence of the catI, catII, catIII, catIV, floR, ermB, tetO, tetA, mcr-4 and ampC genes were present in 84.2%, 78.9%, 52.6%, 10.5%, 52.6%, 73.7%, 68.4%, 47.4%, 42.1% and 10.5% of the tested isolates [66]. Similarly, antimicrobial resistance genes from 132 Campylobacter (C. jejuni and C. coli) poultry isolates were favourably prevalent, ranging from 80 to 100% for the cmeB, tetO and blaOXA-61 genes among all tested isolates, while the aphA-3 gene was not detected in any of the strains. The Thr-86-Ile mutation in the gyrA gene was detected in 80% of C. coli and 90% of C. jejuni strains. Moreover, the 23S rRNA A2075G point mutation was identified in 61% of C. coli and 86% of C. jejuni isolates, while the A2074C point mutation showed lower prevalence, holding by only 27% of C. coli and 14% of C. jejuni isolates. Notably, both A2074C and A2075G mutations were detected in 12% of the C. coli isolates [40].

8. Reports of Multi-Drug Resistant Campylobacter spp.

There have been numerous reports of multidrug resistance within the Campylobacter genus, regardless of the source of the isolates. Table 2 includes examples of antibiotic agents that have been identified in multidrug-resistant C. jejuni/C. coli strains isolated from both clinical and animal sources.
Previously investigated antimicrobial profiles and phylogenetic diversities of C. coli strains isolated from humans and swine between 2008 and 2014 in Osaka, Japan, identified that antimicrobial resistance (AMR) to erythromycin in the swine-derived strains was the highest. The swine strains that displayed erythromycin resistance harboured, besides a point mutation in the 23S rRNA, also the presence of the tetracycline resistance gene (tetO). The ST-1562 swine strain presented the highest frequency of multiple AMR, although this strain was not found in humans. Most of the human, poultry and cattle strains that displayed tetracycline resistance revealed the presence of the tetO gene on plasmids, yet swine strains displayed it on chromosomes [106]. The results of this study unveiled simultaneous antimicrobial resistance to at least three other antibiotic classes, namely quinolones, tetracyclines and β-lactams. Resistance to quinolones, macrolides and tetracyclines was observed in only one C. coli isolate [73].
The prevalence, virulence factors and antibiotic resistance profiles of 113 C. jejuni isolates obtained from Egypt’s poultry, and human sources also demonstrated a multidrug-resistant pattern, particularly to erythromycin and ampicillin. Approximately 96.5% of the isolates revealed resistance to five or more antibiotics [57]. Resistance to ciprofloxacin, cefixime and nalidixic acid was also identified in chicken isolates from Iran. Elevated antimicrobial resistance was identified to trimethoprim/sulfamethoxazole (80.8%), tetracycline (88.5%) and ampicillin (76.9%). Moreover, 80.2% of the tested isolates presented an increased multidrug resistance phenotype [58]. In a Chinese study, 220 Campylobacter isolates were classified as multidrug-resistant. C. jejuni showed relatively low resistance rates regarding gentamycin (15.6%), ciprofloxacin (13.8%) and nalidixic acid (25.7%), whereas the C. coli isolates displayed higher resistance rates to these antibiotics, namely 67.0%, 60.2% and 62.1%, respectively [75]. The genetic determinants associated with antimicrobial resistance were previously associated with point mutations into the gyrA gene or in the V domain of the 23S rRNA. Also, the presence of either the blaOXA-61 gene or the cmeABC efflux pump was also linked to the effect [90].
Phenotypic and genotypic characterisation of 541 Campylobacter isolates originating from various livestock at different stages of the production chain in North Carolina concluded that 90.4% of the tested isolates encoded antimicrobial resistance genes, while 43% revealed resistance to multiple antibiotics. Approximately 121 gyrA mutations were identified among poultry isolates, while only 9.7% belonged to the swine and cattle strains. All isolates showing high resistance to clindamycin, azithromycin and erythromycin also held the A2075G point mutation of 23S rRNA. Moreover, all Campylobacter isolates carrying cmeABC and cmeR operons also carried the 50S L22 point mutation, while C. coli isolates had resistance genes related to aminoglycoside resistance [77].
Multi-drug resistance to antimicrobials was also identified in all tested C. jejuni isolates from broiler chickens in Brazil. The cmeABC operon and the cmeG gene revealed high prevalence among the tested isolates, with 66.7% of the C. jejuni isolates showing the presence of tetO and blaOXA-61 genes, while only 30.43% of the strains carried the aphA-3 gene. All of the C. jejuni isolates harboured the Thr-86-Ile mutation in the gyrA gene and the A2075G point mutation in the 23S rRNA gene. Also, 85.7% of the C. jejuni strains included at least one plasmid [105]. Likewise, in broilers, in an Indian study, it has been identified that the highest antimicrobial resistance was detected to tetracycline, followed by macrolides, β-lactams, fluoroquinolones and sulphonamide, with a prevalence of 84.61%, 61.53%, 53.84%, 38.45% and 30.76% among all Campylobacter isolates. All the chicken isolates were resistant to tetracycline, while β-lactam, fluoroquinolone and macrolide resistance were detected in 66.66%, 25% and 33.33% of the tested isolates. Moreover, the isolates displaying resistance to macrolide and ampicillin carried the blaOXA-61 and 23SrRNA genes in 50% and 25% of the isolates [67]. Also, all 48 tested isolates from north-eastern Tunisia also displayed multi-drug resistance. Resistance to erythromycin, ciprofloxacin, gentamicin, chloramphenicol and nalidixic acid was detected in 97%, 60%, 30.3%, 72.7% and 87.9% of the C. jejuni isolates, respectively, while C. coli isolates displayed 100%, 86.7%, 20%, 80% and 80% resistance rates to the same antimicrobials. All screened antimicrobial resistance genes, namely tetO, tetA, tetL, tetB, cmeB, ermB, aphA-3 and blaOXA-61 genes, were detected among the tested Campylobacter isolates. Moreover, the C257T point mutation in the gyrA gene and the A2075G point mutation in the 23SrRNA gene were identified [68].
A similar study investigated the antimicrobial resistance genes of Campylobacter isolated from broilers, calves, pigs and humans in Latvia. The C. jejuni isolates unveiled high resistance to nalidixic acid (94%) and ciprofloxacin (93.6%), while C. coli strains presented the highest resistance to streptomycin (73.5%). Low resistance to erythromycin and gentamicin was observed in C. coli and C. jejuni isolates. Circa 9.5% of the C. jejuni isolates obtained from calves displayed multi-drug resistance, while the human isolates showed a 16.7% prevalence of multi-drug resistance. Moreover, the C. coli isolates revealed multi-drug resistance in 29.6% of the pig isolates and in one human isolate and three calves isolates. All 30 quinolones-resistant Campylobacter strains possessed a gyrA gene point mutation, while all tetracycline-resistant bacteria showed the presence of the tetO gene. Aminoglycoside resistance was conferred by the ant(6)-Ib and aph(3′)-IIIa genes. The cmeABC operon was detected in all sequenced isolates. Notably, the blaOXA-184 gene was detected in five clinical isolates and one pig isolate. Further analyses linked these two strains by clustering them together [79]. A similar trend in observations was observed in a Belgian study which determined the antimicrobial resistance phenotypes and genetic diversity of 59 C. coli isolates. Some of the C. coli isolates that displayed erythromycin-resistance carried the ermB gene, point mutations in the rplV and rplD ribosomal genes, 23S rRNA A2074G point mutation and the cmeABC operon [109]. It is indeed obvious that the multidrug resistance in C. jejuni or C. coli isolates originating from poultry is most often associated with gene mutations or the presence of plasmids encoding for such mutations indicating that surveillance and close monitoring of AMR in such isolates is necessary.

9. Conclusions

It has been observed that various species within the Campylobacter genus can exchange genetic material with one another, as well as with other bacterial genera. This facilitates the transfer of genes that enhance the virulence of Campylobacter and allow it to withstand exposure to antibiotics. This bacterial genus is widely present in multiple hosts, including humans, animals, food products and the environment. The interconnected nature of these factors presents challenges for effectively addressing the potential negative consequences for human and animal health. Altogether the findings of this study emphasise the need for monitoring the relationship between virulence factors and antimicrobial resistance in Campylobacter spp. regardless of host origin.

Author Contributions

All authors contributed equally. All authors have read and agreed to the published version of the manuscript.

Funding

The publication of this review paper was supported through the University of Life Sciences King Mihai I from Timisoara doctoral grants.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Roux, D.; Danilchanka, O.; Guillard, T.; Cattoir, V.; Aschard, H.; Fu, Y.; Angoulvant, F.; Messika, J.; Ricard, J.-D.; Mekalanos, J.J.; et al. Fitness cost of antibiotic susceptibility during bacterial infection. Sci. Transl. Med. 2015, 7, 297ra114. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Schroeder, M.; Brooks, B.D.; Brooks, A.E. The Complex Relationship between Virulence and Antibiotic Resistance. Genes 2017, 8, 39. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. Glasner, C.; Albiger, B.; Buist, G.; Andrašević, A.T.; Cantón, R.; Carmeli, Y.; Friedrich, A.W.; Giske, C.G.; Glupczynski, Y.; Gniadkowski, M.; et al. Carbapenemase-producing Enterobacteriaceae in Europe: A survey among national experts from 39 countries, February 2013. Eurosurveillance 2013, 18, 20525. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Pérez, V.K.C.; Costa, G.M.d.; Guimarães, A.S.; Heinemann, M.B.; Lage, A.P.; Dorneles, E.M.S. Relationship between virulence factors and antimicrobial resistance in Staphylococcus aureus from bovine mastitis. J. Glob. Antimicrob. Resist. 2020, 22, 792–802. [Google Scholar] [CrossRef] [PubMed]
  5. Geisinger, E.; Isberg, R.R. Antibiotic Modulation of Capsular Exopolysaccharide and Virulence in Acinetobacter baumannii. PLoS Pathog. 2015, 11, e1004691. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  6. Geisinger, E.; Isberg, R.R. Interplay Between Antibiotic Resistance and Virulence during Disease Promoted by Multidrug-Resistant Bacteria. J. Infect. Dis. 2017, 215, S9–S17. [Google Scholar] [CrossRef] [Green Version]
  7. Subramanian, D.; Natarajan, J. Network analysis of S. aureus response to ramoplanin reveals modules for virulence factors and resistance mechanisms and characteristic novel genes. Gene 2015, 574, 149–162. [Google Scholar] [CrossRef] [PubMed]
  8. Cameron, D.R.; Jiang, J.-H.; Kostoulias, X.; Foxwell, D.J.; Peleg, A.Y. Vancomycin susceptibility in methicillin-resistant Staphylococcus aureus is mediated by YycHI activation of the WalRK essential two-component regulatory system. Sci. Rep. 2016, 6, 30823. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  9. Moskowitz, S.M.; Foster, J.M.; Emerson, J.; Burns, J.L. Clinically Feasible Biofilm Susceptibility Assay for Isolates of Pseudomonas aeruginosa from Patients with Cystic Fibrosis. J. Clin. Microbiol. 2004, 42, 1915–1922. [Google Scholar] [CrossRef] [Green Version]
  10. von Wintersdorff, C.J.H.; Penders, J.; van Niekerk, J.M.; Mills, N.D.; Majumder, S.; van Alphen, L.B.; Savelkoul, P.H.M.; Wolffs, P.F.G. Dissemination of Antimicrobial Resistance in Microbial Ecosystems through Horizontal Gene Transfer. Front. Microbiol. 2016, 7, 173. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  11. Johnson, J.T.; Nolan, L.K. Pathogenomics of the Virulence Plasmids of Escherichia coli. Microbiol. Mol. Biol. Rev. 2009, 73, 750–774. [Google Scholar] [CrossRef] [Green Version]
  12. Zhu, Y.-G.; Zhao, Y.; Li, B.; Huang, C.-L.; Zhang, S.-Y.; Yu, S.; Chen, Y.-S.; Zhang, T.; Gillings, M.R.; Su, J.-Q. Continental-scale pollution of estuaries with antibiotic resistance genes. Nat. Microbiol. 2017, 2, 16270. [Google Scholar] [CrossRef] [PubMed]
  13. Oppegaard, H.; Steinum, T.M.; Wasteson, Y. Horizontal Transfer of a Multi-Drug Resistance Plasmid between Coliform Bacteria of Human and Bovine Origin in a Farm Environment. Appl. Environ. Microbiol. 2001, 67, 3732–3734. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Zhang, S.; Chen, S.; Rehman, M.U.; Yang, H.; Yang, Z.; Wang, M.; Jia, R.; Chen, S.; Liu, M.; Zhu, D.; et al. Distribution and association of antimicrobial resistance and virulence traits in Escherichia coli isolates from healthy waterfowls in Hainan, China. Ecotoxicol. Environ. Saf. 2021, 220, 112317. [Google Scholar] [CrossRef] [PubMed]
  15. Golz, J.C.; Stingl, K. Natural Competence and Horizontal Gene Transfer in Campylobacter. In Fighting Campylobacter Infections: Towards a One Health Approach; Backert, S., Ed.; Springer International Publishing: Cham, Switzerland, 2021; pp. 265–292. [Google Scholar]
  16. Guernier-Cambert, V.; Trachsel, J.; Maki, J.; Qi, J.; Sylte, M.J.; Hanafy, Z.; Kathariou, S.; Looft, T. Natural Horizontal Gene Transfer of Antimicrobial Resistance Genes in Campylobacter spp. From Turkeys and Swine. Front. Microbiol. 2021, 12, 732969. [Google Scholar] [CrossRef] [PubMed]
  17. Marasini, D.; Karki, A.B.; Buchheim, M.A.; Fakhr, M.K. Phylogenetic Relatedness among Plasmids Harbored by Campylobacter jejuni and Campylobacter coli Isolated from Retail Meats. Front. Microbiol. 2018, 9, 2167. [Google Scholar] [CrossRef] [Green Version]
  18. Gahamanyi, N.; Song, D.-G.; Yoon, K.-Y.; Mboera, L.E.G.; Matee, M.I.; Mutangana, D.; Komba, E.V.G.; Pan, C.-H.; Amachawadi, R.G. Genomic Characterization of Fluoroquinolone-Resistant Thermophilic Campylobacter Strains Isolated from Layer Chicken Feces in Gangneung, South Korea by Whole-Genome Sequencing. Genes 2021, 12, 1131. [Google Scholar] [CrossRef]
  19. Crawshaw, T. A review of the novel thermophilic Campylobacter, Campylobacter hepaticus, a pathogen of poultry. Transbound. Emerg. Dis. 2019, 66, 1481–1492. [Google Scholar] [CrossRef] [PubMed]
  20. Guirado, P.; Miró, E.; Iglesias-Torrens, Y.; Navarro, F.; Campoy, S.; Alioto, T.S.; Gómez-Garrido, J.; Madrid, C.; Balsalobre, C. A New Variant of the aadE-sat4-aphA-3 Gene Cluster Found in a Conjugative Plasmid from a MDR Campylobacter jejuni Isolate. Antibiotics 2022, 11, 466. [Google Scholar] [CrossRef] [PubMed]
  21. Darmancier, H.; Domingues, C.P.F.; Rebelo, J.S.; Amaro, A.; Dionisio, F.; Pothier, J.; Serra, O.; Nogueira, T. Are Virulence and Antibiotic Resistance Genes Linked? A Comprehensive Analysis of Bacterial Chromosomes and Plasmids. Antibiotics 2022, 11, 706. [Google Scholar] [CrossRef]
  22. Lopes, G.V.; Ramires, T.; Kleinubing, N.R.; Scheik, L.K.; Fiorentini, Â.M.; da Silva, W.P. Virulence factors of foodborne pathogen Campylobacter jejuni. Microb. Pathog. 2021, 161, 105265. [Google Scholar] [CrossRef] [PubMed]
  23. EFSA. The European Union One Health 2021 Zoonoses Report. EFSA J. 2022, 20, e07666. [Google Scholar] [CrossRef]
  24. Aarestrup, F.M. The livestock reservoir for antimicrobial resistance: A personal view on changing patterns of risks, effects of interventions and the way forward. Philos. Trans. B 2015, 370, 20140085. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Sima, F.; Stratakos, A.C.; Ward, P.; Linton, M.; Kelly, C.; Pinkerton, L.; Stef, L.; Gundogdu, O.; Lazar, V.; Corcionivoschi, N. A Novel Natural Antimicrobial Can Reduce the in vitro and in vivo Pathogenicity of T6SS Positive Campylobacter jejuni and Campylobacter coli Chicken Isolates. Front. Microbiol. 2018, 9, 2139. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. Balta, I.; Linton, M.; Pinkerton, L.; Kelly, C.; Stef, L.; Pet, I.; Stef, D.; Criste, A.; Gundogdu, O.; Corcionivoschi, N. The effect of natural antimicrobials against Campylobacter spp. and its similarities to Salmonella spp, Listeria spp., Escherichia coli, Vibrio spp., Clostridium spp. and Staphylococcus spp. Food Control 2021, 121, 107745. [Google Scholar] [CrossRef]
  27. Balta, I.; Marcu, A.; Linton, M.; Kelly, C.; Stef, L.; Pet, I.; Ward, P.; Pircalabioru, G.G.; Chifiriuc, C.; Gundogdu, O.; et al. The in vitro and in vivo anti-virulent effect of organic acid mixtures against Eimeria tenella and Eimeria bovis. Sci. Rep. 2021, 11, 16202. [Google Scholar] [CrossRef] [PubMed]
  28. Hlashwayo, D.F.; Sigaúque, B.; Bila, C.G. Epidemiology and antimicrobial resistance of Campylobacter spp. in animals in Sub-Saharan Africa: A systematic review. Heliyon 2020, 6, e03537. [Google Scholar] [CrossRef] [PubMed]
  29. Marin, C.; Lorenzo-Rebenaque, L.; Moreno-Moliner, J.; Sevilla-Navarro, S.; Montero, E.; Chinillac, M.C.; Jordá, J.; Vega, S. Multidrug-Resistant Campylobacer jejuni on Swine Processing at a Slaughterhouse in Eastern Spain. Animals 2021, 11, 1339. [Google Scholar] [CrossRef] [PubMed]
  30. Sibanda, N.; McKenna, A.; Richmond, A.; Ricke, S.C.; Callaway, T.; Stratakos, A.C.; Gundogdu, O.; Corcionivoschi, N. A Review of the Effect of Management Practices on Campylobacter Prevalence in Poultry Farms. Front. Microbiol. 2018, 9, 2002. [Google Scholar] [CrossRef]
  31. Tang, M.; Zhou, Q.; Zhang, X.; Zhou, S.; Zhang, J.; Tang, X.; Lu, J.; Gao, Y. Antibiotic Resistance Profiles and Molecular Mechanisms of Campylobacter from Chicken and Pig in China. Front. Microbiol. 2020, 11, 592496. [Google Scholar] [CrossRef]
  32. Courtice, J.M.; Mahdi, L.K.; Groves, P.J.; Kotiw, M. Spotty Liver Disease: A review of an ongoing challenge in commercial free-range egg production. Vet. Microbiol. 2018, 227, 112–118. [Google Scholar] [CrossRef] [PubMed]
  33. Wu, Z.; Sahin, O.; Zhang, Q. Campylobacter. In Pathogenesis of Bacterial Infections in Animals; Wiley-Blackwell: New York, NY, USA, 2022; pp. 393–412. [Google Scholar]
  34. Phung, C.; Vezina, B.; Anwar, A.; Wilson, T.; Scott, P.C.; Moore, R.J.; Van, T.T.H. Campylobacter hepaticus, the Cause of Spotty Liver Disease in Chickens: Transmission and Routes of Infection. Front. Vet. Sci. 2020, 6, 505. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  35. Urban-Chmiel, R.; Marek, A.; Stępień-Pyśniak, D.; Wieczorek, K.; Dec, M.; Nowaczek, A.; Osek, J. Antibiotic Resistance in Bacteria—A Review. Antibiotics 2022, 11, 1079. [Google Scholar] [CrossRef]
  36. Yang, Y.; Feye, K.M.; Shi, Z.; Pavlidis, H.O.; Kogut, M.; Ashworth, A.J.; Ricke, S.C. A historical review on antibiotic resistance of foodborne Campylobacter. Front. Microbiol. 2019, 10, 1509. [Google Scholar] [CrossRef] [Green Version]
  37. Iovine, N.M. Resistance mechanisms in Campylobacter jejuni. Virulence 2013, 4, 230–240. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  38. Wieczorek, K.; Osek, J. Antimicrobial Resistance Mechanisms among Campylobacter. BioMed Res. Int. 2013, 2013, 340605. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  39. Laprade, N.; Cloutier, M.; Lapen, D.R.; Topp, E.; Wilkes, G.; Villemur, R.; Khan, I.U.H. Detection of virulence, antibiotic resistance and toxin (VAT) genes in Campylobacter species using newly developed multiplex PCR assays. J. Microbiol. Methods 2016, 124, 41–47. [Google Scholar] [CrossRef] [PubMed]
  40. Gharbi, M.; Béjaoui, A.; Ben Hamda, C.; Ghedira, K.; Ghram, A.; Maaroufi, A. Distribution of virulence and antibiotic resistance genes in Campylobacter jejuni and Campylobacter coli isolated from broiler chickens in Tunisia. J. Microbiol. Immunol. Infect. 2021, 55, 1273–1282. [Google Scholar] [CrossRef] [PubMed]
  41. Xu, H.; Chen, Z.; Huang, R.; Cui, Y.; Li, Q.; Zhao, Y.; Wang, X.; Mao, D.; Luo, Y.; Ren, H. Antibiotic Resistance Gene-Carrying Plasmid Spreads into the Plant Endophytic Bacteria using Soil Bacteria as Carriers. Environ. Sci. Technol. 2021, 55, 10462–10470. [Google Scholar] [CrossRef] [PubMed]
  42. Meng, M.; Li, Y.; Yao, H. Plasmid-Mediated Transfer of Antibiotic Resistance Genes in Soil. Antibiotics 2022, 11, 525. [Google Scholar] [CrossRef]
  43. He, T.; Wang, R.; Liu, D.; Walsh, T.R.; Zhang, R.; Lv, Y.; Ke, Y.; Ji, Q.; Wei, R.; Liu, Z.; et al. Emergence of plasmid-mediated high-level tigecycline resistance genes in animals and humans. Nat. Microbiol. 2019, 4, 1450–1456. [Google Scholar] [CrossRef]
  44. Wein, T.; Dagan, T. Plasmid evolution. Curr. Biol. 2020, 30, R1158–R1163. [Google Scholar] [CrossRef] [PubMed]
  45. Redondo-Salvo, S.; Fernández-López, R.; Ruiz, R.; Vielva, L.; de Toro, M.; Rocha, E.P.C.; Garcillán-Barcia, M.P.; de la Cruz, F. Pathways for horizontal gene transfer in bacteria revealed by a global map of their plasmids. Nat. Commun. 2020, 11, 3602. [Google Scholar] [CrossRef] [PubMed]
  46. Carroll, A.C.; Wong, A. Plasmid persistence: Costs, benefits, and the plasmid paradox. Can. J. Microbiol. 2018, 64, 293–304. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  47. Hall, J.P.J.; Botelho, J.; Cazares, A.; Baltrus, D.A. What makes a megaplasmid? Philos. Trans. B 2022, 377, 20200472. [Google Scholar] [CrossRef] [PubMed]
  48. Liaw, J.; Hong, G.; Davies, C.; Elmi, A.; Sima, F.; Stratakos, A.; Stef, L.; Pet, I.; Hachani, A.; Corcionivoschi, N.; et al. The Campylobacter jejuni Type VI Secretion System Enhances the Oxidative Stress Response and Host Colonization. Front. Microbiol. 2019, 10, 2864. [Google Scholar] [CrossRef] [PubMed]
  49. de Oliveira, M.G.; Rizzi, C.; Galli, V.; Lopes, G.V.; Haubert, L.; Dellagostin, O.A.; da Silva, W.P. Presence of genes associated with adhesion, invasion, and toxin production in Campylobacter jejuni isolates and effect of temperature on their expression. Can. J. Microbiol. 2018, 65, 253–260. [Google Scholar] [CrossRef] [PubMed]
  50. Wysok, B.; Sołtysiuk, M.; Stenzel, T. Wildlife Waterfowl as a Source of Pathogenic Campylobacter Strains. Pathogens 2022, 11, 113. [Google Scholar] [CrossRef] [PubMed]
  51. Galate, L.; Bangde, S. Campylobacter—A foodborne pathogen. Int. J. Sci. Res. 2015, 4, 1250–1259. [Google Scholar]
  52. Chlebicz, A.; Śliżewska, K. Campylobacteriosis, salmonellosis, yersiniosis, and listeriosis as zoonotic foodborne diseases: A review. Int. J. Environ. Res. Public Health 2018, 15, 863. [Google Scholar] [CrossRef] [Green Version]
  53. Dearlove, B.L.; Cody, A.J.; Pascoe, B.; Méric, G.; Wilson, D.J.; Sheppard, S.K. Rapid host switching in generalist Campylobacter strains erodes the signal for tracing human infections. ISME J. 2016, 10, 721–729. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  54. Gölz, G.; Kittler, S.; Malakauskas, M.; Alter, T. Survival of Campylobacter in the Food Chain and the Environment. Curr. Clin. Microbiol. Rep. 2018, 5, 126–134. [Google Scholar] [CrossRef]
  55. Wysok, B.; Wojtacka, J.; Hänninen, M.-L.; Kivistö, R. Antimicrobial Resistance and Virulence-Associated Markers in Campylobacter Strains from Diarrheic and Non-diarrheic Humans in Poland. Front. Microbiol. 2020, 11, 1799. [Google Scholar] [CrossRef] [PubMed]
  56. Abd El-Hamid, M.I.; Abd El-Aziz, N.K.; Samir, M.; El-Naenaeey, E.-S.Y.; Abo Remela, E.M.; Mosbah, R.A.; Bendary, M.M. Genetic Diversity of Campylobacter jejuni Isolated from Avian and Human Sources in Egypt. Front. Microbiol. 2019, 10, 2353. [Google Scholar] [CrossRef]
  57. Ammar, A.M.; El-Naenaeey, E.-S.Y.; El-Malt, R.M.S.; El-Gedawy, A.A.; Khalifa, E.; Elnahriry, S.S.; Abd El-Hamid, M.I. Prevalence, Antimicrobial Susceptibility, Virulence and Genotyping of Campylobacter jejuni with a Special Reference to the Anti-Virulence Potential of Eugenol and Beta-Resorcylic Acid on Some Multi-Drug Resistant Isolates in Egypt. Animals 2021, 11, 3. [Google Scholar] [CrossRef]
  58. Fani, F.; Aminshahidi, M.; Firoozian, N.; Rafaatpour, N. Prevalence, antimicrobial resistance, and virulence-associated genes of Campylobacter isolates from raw chicken meat in Shiraz, Iran. Iran. J. Vet. Res. 2019, 20, 283–288. [Google Scholar]
  59. Gahamanyi, N.; Song, D.-G.; Yoon, K.-Y.; Mboera, L.E.G.; Matee, M.I.; Mutangana, D.; Amachawadi, R.G.; Komba, E.V.G.; Pan, C.-H. Antimicrobial Resistance Profiles, Virulence Genes, and Genetic Diversity of Thermophilic Campylobacter Species Isolated from a Layer Poultry Farm in Korea. Front. Microbiol. 2021, 12, 622275. [Google Scholar] [CrossRef]
  60. Rossler, E.; Olivero, C.; Soto, L.P.; Frizzo, L.S.; Zimmermann, J.; Rosmini, M.R.; Sequeira, G.J.; Signorini, M.L.; Zbrun, M.V. Prevalence, genotypic diversity and detection of virulence genes in thermotolerant Campylobacter at different stages of the poultry meat supply chain. Int. J. Food Microbiol. 2020, 326, 108641. [Google Scholar] [CrossRef]
  61. Tang, Y.; Jiang, Q.; Tang, H.; Wang, Z.; Yin, Y.; Ren, F.; Kong, L.; Jiao, X.; Huang, J. Characterization and Prevalence of Campylobacter spp. from Broiler Chicken Rearing Period to the Slaughtering Process in Eastern China. Front. Vet. Sci. 2020, 7, 227. [Google Scholar] [CrossRef]
  62. Melo, R.T.; Grazziotin, A.L.; Júnior, E.C.V.; Prado, R.R.; Mendonça, E.P.; Monteiro, G.P.; Peres, P.A.B.M.; Rossi, D.A. Evolution of Campylobacter jejuni of poultry origin in Brazil. Food Microbiol. 2019, 82, 489–496. [Google Scholar] [CrossRef]
  63. de Melo, R.T.; Dumont, C.F.; Braz, R.F.; Monteiro, G.P.; Takeuchi, M.G.; Lourenzatto, E.C.A.; dos Santos, J.P.; Rossi, D.A. Genotypical Relationship between Human and Poultry Strains of Campylobacter jejuni. Curr. Microbiol. 2021, 78, 2980–2988. [Google Scholar] [CrossRef] [PubMed]
  64. Prendergast, D.M.; Lynch, H.; Whyte, P.; Golden, O.; Murphy, D.; Gutierrez, M.; Cummins, J.; Johnston, D.; Bolton, D.; Coffey, A.; et al. Genomic diversity, virulence and source of Campylobacter jejuni contamination in Irish poultry slaughterhouses by whole genome sequencing. J. Appl. Microbiol. 2022, 133, 3150–3160. [Google Scholar] [CrossRef] [PubMed]
  65. Truccollo, B.; Whyte, P.; Burgess, C.; Bolton, D. Genetic characterisation of a subset of Campylobacter jejuni isolates from clinical and poultry sources in Ireland. PLoS ONE 2021, 16, e0246843. [Google Scholar] [CrossRef] [PubMed]
  66. Ramatla, T.; Mileng, K.; Ndou, R.; Tawana, M.; Mofokeng, L.; Syakalima, M.; Lekota, K.E.; Thekisoe, O. Campylobacter jejuni from Slaughter Age Broiler Chickens: Genetic Characterization, Virulence, and Antimicrobial Resistance Genes. Int. J. Microbiol. 2022, 2022, 1713213. [Google Scholar] [CrossRef]
  67. Rangaraju, V.; Malla, B.A.; Milton, A.A.P.; Madesh, A.; Madhukar, K.B.; Kadwalia, A.; Vinodhkumar, O.R.; Kumar, M.S.; Dubal, Z.B. Occurrence, antimicrobial resistance and virulence properties of thermophilic Campylobacter coli originating from two different poultry settings. Gene Rep. 2022, 27, 101618. [Google Scholar] [CrossRef]
  68. Béjaoui, A.; Gharbi, M.; Bitri, S.; Nasraoui, D.; Ben Aziza, W.; Ghedira, K.; Rfaik, M.; Marzougui, L.; Ghram, A.; Maaroufi, A. Virulence Profiling, Multidrug Resistance and Molecular Mechanisms of Campylobacter Strains from Chicken Carcasses in Tunisia. Antibiotics 2022, 11, 830. [Google Scholar] [CrossRef]
  69. Lima, L.M.; Perdoncini, G.; Borges, K.A.; Furian, T.Q.; Salle, C.T.P.; De Souza Moraes, H.; do Nascimento, V.P. Prevalence and distribution of pathogenic genes in Campylobacter jejuni isolated from poultry and human sources. J. Infect. Dev. Ctries. 2022, 16, 1466–1472. [Google Scholar] [CrossRef]
  70. De Melo, F.P.; da Silva, P.O.; Clemente, S.M.D.S.; de Melo, R.P.B.; da Silva, J.G.; Júnior, J.W.P.; Fonseca, B.B.; Mendonça, M.; Barros, M.R. Detection of Campylobacter jejuni, Campylobacter coli, and virulence genes in poultry products marketed in Northeastern Brazil. Res. Soc. Dev. 2021, 10, e542101019224. [Google Scholar] [CrossRef]
  71. Sierra-Arguello, Y.M.; Perdoncini, G.; Rodrigues, L.B.; dos Santos, L.R.; Borges, K.A.; Furian, T.Q.; Salle, C.T.P.; de Souza Moraes, H.L.; Gomes, M.J.P.; do Nascimento, V.P. Identification of pathogenic genes in Campylobacter jejuni isolated from broiler carcasses and broiler slaughterhouses. Sci. Rep. 2021, 11, 4588. [Google Scholar] [CrossRef]
  72. Noreen, Z. Comparative Genomic Analysis of Campylobacter jejuni cj255 Reveals Diverse Genetics, Pathogenicity Determinants and Variation in T6SS. Pak. Vet. J. 2019, 39, 145–150. [Google Scholar] [CrossRef]
  73. Wysok, B.; Wojtacka, J.; Wiszniewska-Łaszczych, A.; Szteyn, J. Antimicrobial Resistance and Virulence Properties of Campylobacter Spp. Originating from Domestic Geese in Poland. Animals 2020, 10, 742. [Google Scholar] [CrossRef] [PubMed]
  74. Kim, J.; Park, H.; Kim, J.; Kim, J.H.; Jung, J.I.; Cho, S.; Ryu, S.; Jeon, B. Comparative Analysis of Aerotolerance, Antibiotic Resistance, and Virulence Gene Prevalence in Campylobacter jejuni Isolates from Retail Raw Chicken and Duck Meat in South Korea. Microorganisms 2019, 7, 433. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  75. Han, X.; Guan, X.; Zeng, H.; Li, J.; Huang, X.; Wen, Y.; Zhao, Q.; Huang, X.; Yan, Q.; Huang, Y.; et al. Prevalence, antimicrobial resistance profiles and virulence-associated genes of thermophilic Campylobacter spp. isolated from ducks in a Chinese slaughterhouse. Food Control 2019, 104, 157–166. [Google Scholar] [CrossRef]
  76. Guirado, P.; Iglesias-Torrens, Y.; Miró, E.; Navarro, F.; Attolini, C.S.-O.; Balsalobre, C.; Madrid, C. Host-associated variability of the cdtABC operon, coding for the cytolethal distending toxin, in Campylobacter jejuni. Zoonoses Public Health 2022, 69, 966–977. [Google Scholar] [CrossRef]
  77. Hull, D.M.; Harrell, E.; van Vliet, A.H.M.; Correa, M.; Thakur, S. Antimicrobial resistance and interspecies gene transfer in Campylobacter coli and Campylobacter jejuni isolated from food animals, poultry processing, and retail meat in North Carolina, 2018–2019. PLoS ONE 2021, 16, e0246571. [Google Scholar] [CrossRef]
  78. Ngobese, B.; Zishiri, O.T.; El Zowalaty, M.E. Molecular detection of virulence genes in Campylobacter species isolated from livestock production systems in South Africa. J. Integr. Agric. 2020, 19, 1656–1670. [Google Scholar] [CrossRef]
  79. Meistere, I.; Ķibilds, J.; Eglīte, L.; Alksne, L.; Avsejenko, J.; Cibrovska, A.; Makarova, S.; Streikiša, M.; Grantiņa-Ieviņa, L.; Bērziņš, A. Campylobacter species prevalence, characterisation of antimicrobial resistance and analysis of whole-genome sequence of isolates from livestock and humans, Latvia, 2008 to 2016. Eurosurveillance 2019, 24, 1800357. [Google Scholar] [CrossRef] [Green Version]
  80. Wei, B.; Kang, M.; Jang, H.-K. Genetic characterization and epidemiological implications of Campylobacter isolates from wild birds in South Korea. Transbound. Emerg. Dis. 2019, 66, 56–65. [Google Scholar] [CrossRef] [Green Version]
  81. Aksomaitiene, J.; Novoslavskij, A.; Kudirkiene, E.; Gabinaitiene, A.; Malakauskas, M. Whole Genome Sequence-Based Prediction of Resistance Determinants in High-Level Multidrug-Resistant Campylobacter jejuni Isolates in Lithuania. Microorganisms 2021, 9, 66. [Google Scholar] [CrossRef]
  82. Wysok, B.; Wojtacka, J. Detection of virulence genes determining the ability to adhere and invade in Campylobacter spp. from cattle and swine in Poland. Microb. Pathog. 2018, 115, 257–263. [Google Scholar] [CrossRef]
  83. Lúcio, É.C.; Barros, M.R.; Souza, P.R.E.; de Cássia Carvalho Maia, R.; Mota, R.A.; Junior, J.W.P. Identification of virulence genes and antimicrobial resistance in Campylobacter spp. from sheep from the state of Pernambuco in Brazil. Res. Soc. Dev. 2022, 11, e41511427457. [Google Scholar] [CrossRef]
  84. Andrzejewska, M.; Szczepańska, B.; Śpica, D.; Klawe, J.J. Prevalence, Virulence, and Antimicrobial Resistance of Campylobacter spp. in Raw Milk, Beef, and Pork Meat in Northern Poland. Foods 2019, 8, 420. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  85. Igwaran, A.; Okoh, A.I. Occurrence, Virulence and Antimicrobial Resistance-Associated Markers in Campylobacter Species Isolated from Retail Fresh Milk and Water Samples in Two District Municipalities in the Eastern Cape Province, South Africa. Antibiotics 2020, 9, 426. [Google Scholar] [CrossRef]
  86. Nilsson, A.; Johansson, C.; Skarp, A.; Kaden, R.; Engstrand, L.; Rautelin, H. Genomic and phenotypic characteristics of Swedish C. jejuni water isolates. PLoS ONE 2017, 12, e0189222. [Google Scholar] [CrossRef] [Green Version]
  87. Chukwu, M.O.; Abia, A.L.K.; Ubomba-Jaswa, E.; Obi, L.; Dewar, J.B. Characterization and Phylogenetic Analysis of Campylobacter Species Isolated from Paediatric Stool and Water Samples in the Northwest Province, South Africa. Int. J. Environ. Res. Public Health 2019, 16, 2205. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  88. do Nascimento Veras, H.; Medeiros, P.H.Q.S.; Ribeiro, S.A.; Freitas, T.M.; Santos, A.K.S.; Amaral, M.S.M.G.; Bona, M.D.; Havt, A.; Lima, I.F.N.; Lima, N.L.; et al. Campylobacter jejuni virulence genes and immune-inflammatory biomarkers association with growth impairment in children from Northeastern Brazil. Eur. J. Clin. Microbiol. Infect. Dis. 2018, 37, 2011–2020. [Google Scholar] [CrossRef]
  89. Bravo, V.; Katz, A.; Porte, L.; Weitzel, T.; Varela, C.; Gonzalez-Escalona, N.; Blondel, C.J. Genomic analysis of the diversity, antimicrobial resistance and virulence potential of clinical Campylobacter jejuni and Campylobacter coli strains from Chile. PLOS Negl. Trop. Dis. 2021, 15, e0009207. [Google Scholar] [CrossRef]
  90. Halimeh, F.B.; Rafei, R.; Diene, S.M.; Osman, M.; Kassem, I.I.; Akoum, R.J.; Moudani, W.; Hamze, M.; Rolain, J.-M. Genome sequence of a multidrug-resistant Campylobacter coli strain isolated from a newborn with severe diarrhea in Lebanon. Folia Microbiol. 2022, 67, 319–328. [Google Scholar] [CrossRef] [PubMed]
  91. Kovács, J.K.; Cox, A.; Schweitzer, B.; Maróti, G.; Kovács, T.; Fenyvesi, H.; Emődy, L.; Schneider, G. Virulence Traits of Inpatient Campylobacter jejuni Isolates, and a Transcriptomic Approach to Identify Potential Genes Maintaining Intracellular Survival. Microorganisms 2020, 8, 531. [Google Scholar] [CrossRef] [Green Version]
  92. Fiedoruk, K.; Daniluk, T.; Rozkiewicz, D.; Oldak, E.; Prasad, S.; Swiecicka, I. Whole-genome comparative analysis of Campylobacter jejuni strains isolated from patients with diarrhea in northeastern Poland. Gut Pathog. 2019, 11, 32. [Google Scholar] [CrossRef] [Green Version]
  93. Stalder, T.; Barraud, O.; Casellas, M.; Dagot, C.; Ploy, M.-C. Integron Involvement in Environmental Spread of Antibiotic Resistance. Front. Microbiol. 2012, 3, 119. [Google Scholar] [CrossRef] [Green Version]
  94. Sin, M.; Yoon, S.; Kim, Y.B.; Noh, E.B.; Seo, K.W.; Lee, Y.J. Molecular characteristics of antimicrobial resistance determinants and integrons in Salmonella isolated from chicken meat in Korea. J. Appl. Poult. Res. 2020, 29, 502–514. [Google Scholar] [CrossRef]
  95. Cavicchio, L.; Dotto, G.; Giacomelli, M.; Giovanardi, D.; Grilli, G.; Franciosini, M.P.; Trocino, A.; Piccirillo, A. Class 1 and class 2 integrons in avian pathogenic Escherichia coli from poultry in Italy. Poult. Sci. 2015, 94, 1202–1208. [Google Scholar] [CrossRef] [PubMed]
  96. Deng, Y.; Bao, X.; Ji, L.; Chen, L.; Liu, J.; Miao, J.; Chen, D.; Bian, H.; Li, Y.; Yu, G. Resistance integrons: Class 1, 2 and 3 integrons. Ann. Clin. Microbiol. Antimicrob. 2015, 14, 45. [Google Scholar] [CrossRef] [Green Version]
  97. Piccirillo, A.; Dotto, G.; Salata, C.; Giacomelli, M. Absence of class 1 and class 2 integrons among Campylobacter jejuni and Campylobacter coli isolated from poultry in Italy. J. Antimicrob. Chemother. 2013, 68, 2683–2685. [Google Scholar] [CrossRef] [Green Version]
  98. Newell, D.G.; Mughini-Gras, L.; Kalupahana, R.S.; Wagenaar, J.A. Chapter 5-Campylobacter epidemiology—Sources and routes of transmission for human infection. In Campylobacter; Klein, G., Ed.; Academic Press: Cambridge, MA, USA, 2017; pp. 85–110. [Google Scholar]
  99. Silva, M.F.; Pereira, G.; Carneiro, C.; Hemphill, A.; Mateus, L.; Lopes-da-Costa, L.; Silva, E. Campylobacter portucalensis sp. nov., a new species of Campylobacter isolated from the preputial mucosa of bulls. PLoS ONE 2020, 15, e0227500. [Google Scholar] [CrossRef] [PubMed]
  100. Rivera-Mendoza, D.; Martínez-Flores, I.; Santamaría, R.I.; Lozano, L.; Bustamante, V.H.; Pérez-Morales, D. Genomic Analysis Reveals the Genetic Determinants Associated with Antibiotic Resistance in the Zoonotic Pathogen Campylobacter spp. Distributed Globally. Front. Microbiol. 2020, 11, 513070. [Google Scholar] [CrossRef]
  101. Durovic, A.; Seth-Smith, H.M.B.; Hinic, V.; Kurz, M.; Khanna, N.; Egli, A. Two simultaneous cases of disseminated infections with Campylobacter fetus Clinical characteristics and molecular comparison. Clin. Microbiol. Infect. 2021, 27, 141–143. [Google Scholar] [CrossRef]
  102. Ocejo, M.; Oporto, B.; Lavín, J.L.; Hurtado, A. Whole genome-based characterisation of antimicrobial resistance and genetic diversity in Campylobacter jejuni and Campylobacter coli from ruminants. Sci. Rep. 2021, 11, 8998. [Google Scholar] [CrossRef]
  103. Fabre, A.; Oleastro, M.; Nunes, A.; Santos, A.; Sifré, E.; Ducournau, A.; Bénéjat, L.; Buissonnière, A.; Floch, P.; Mégraud, F.; et al. Whole-Genome Sequence Analysis of Multidrug-Resistant Campylobacter Isolates: A Focus on Aminoglycoside Resistance Determinants. J. Clin. Microbiol. 2018, 56, e00390-18. [Google Scholar] [CrossRef] [Green Version]
  104. Marotta, F.; Garofolo, G.; di Marcantonio, L.; Di Serafino, G.; Neri, D.; Romantini, R.; Sacchini, L.; Alessiani, A.; Di Donato, G.; Nuvoloni, R.; et al. Antimicrobial resistance genotypes and phenotypes of Campylobacter jejuni isolated in Italy from humans, birds from wild and urban habitats, and poultry. PLoS ONE 2019, 14, e0223804. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  105. Kleinubing, N.R.; Ramires, T.; de Fátima Rauber Würfel, S.; Haubert, L.; Scheik, L.K.; Kremer, F.S.; Lopes, G.V.; da Silva, W.P. Antimicrobial resistance genes and plasmids in Campylobacter jejuni from broiler production chain in Southern Brazil. LWT 2021, 144, 111202. [Google Scholar] [CrossRef]
  106. Asakura, H.; Sakata, J.; Nakamura, H.; Yamamoto, S.; Murakami, S. Phylogenetic Diversity and Antimicrobial Resistance of Campylobacter coli from Humans and Animals in Japan. Microbes Environ. 2019, 34, 146–154. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  107. Zhao, S.; Mukherjee, S.; Hsu, C.-H.; Young, S.; Li, C.; Tate, H.; Morales, C.A.; Haro, J.; Thitaram, S.; Tillman, G.E.; et al. Genomic Analysis of Emerging Florfenicol-Resistant Campylobacter coli Isolated from the Cecal Contents of Cattle in the United States. Msphere 2019, 4, e00367-19. [Google Scholar] [CrossRef] [Green Version]
  108. Morita, D.; Arai, H.; Isobe, J.; Maenishi, E.; Kumagai, T.; Maruyama, F.; Kuroda, T. Diversity and characteristics of pTet family plasmids revealed by genomic epidemiology of Campylobacter jejuni from human patients in Toyama, Japan from 2015 to 2019. bioRxiv 2022. [Google Scholar] [CrossRef]
  109. Elhadidy, M.; Miller, W.G.; Arguello, H.; Álvarez-Ordóñez, A.; Dierick, K.; Botteldoorn, N. Molecular epidemiology and antimicrobial resistance mechanisms of Campylobacter coli from diarrhoeal patients and broiler carcasses in Belgium. Transbound. Emerg. Dis. 2019, 66, 463–475. [Google Scholar] [CrossRef] [Green Version]
Antibiotics 12 00402 g001 550
Figure 1. Various mechanisms and factors that play a significant role in the regulation of genes encoding virulence and antimicrobial resistance. (A) Conjugation; (B) transfection; (C) alteration of the antibiotic target; (D) elevated mutation rates; (E) transformation; (F) inactivation of antibiotics; (G) efflux pump; with (H) environmental factors exerting a secondary and ultimate effect on all the others. Created with Biorender.com.
Figure 1. Various mechanisms and factors that play a significant role in the regulation of genes encoding virulence and antimicrobial resistance. (A) Conjugation; (B) transfection; (C) alteration of the antibiotic target; (D) elevated mutation rates; (E) transformation; (F) inactivation of antibiotics; (G) efflux pump; with (H) environmental factors exerting a secondary and ultimate effect on all the others. Created with Biorender.com.
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Figure 2. The role of livestock in the spread of antibiotic resistance in the environment. The administration of antibiotics to both human and animal populations favours the spread of resistance-associated genes in the natural environment, hence maintaining an ongoing reciprocal transmission, regardless of host origin. Created with Biorender.com and partly generated using Servier Medical Art and Twinkl.co.uk.
Figure 2. The role of livestock in the spread of antibiotic resistance in the environment. The administration of antibiotics to both human and animal populations favours the spread of resistance-associated genes in the natural environment, hence maintaining an ongoing reciprocal transmission, regardless of host origin. Created with Biorender.com and partly generated using Servier Medical Art and Twinkl.co.uk.
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Table
Table 1. Highly prevalent virulence-associated genes detected in Campylobacter spp. isolated from various sources.
Table 1. Highly prevalent virulence-associated genes detected in Campylobacter spp. isolated from various sources.
SourceVirulence-Associated GenesGene FunctionReferences
Poultry flaA, cadF, pebA, jlpA, racR, docA, dnaJ adhesion & colonisation[18,19,40,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75,76,77,78,79]
pldA, ciaBC, iam, csrA, cbrA, ceuEinvasion
cdtABCcytotoxicity
flgSR, flgE, flgH, flgL, flhA, fliA, fliF, fliM, fliY, motA, pseG, Cj0371, Cj0358, Cj1371, cheY, cheAVWmotility & chemotaxis
luxS, eptCbiofilm formation
htrA, perR, catA stress response
neuABC, gmh, waa, kps, kpsDEFCST, Cj1420c, Cj1419c, Cj1417c, Cj1416c, kpsmCPS
hldELPS
cstII, cstIII, waaC, waaF, waaV, wlaN LOS
virB11T4SS
hcp, clpBT6SS
Wild birdsflaA, cadF, peb1, racR, docA, dnaJadhesion & colonisation[50,60,76,80,81,82]
ciaB, iam, yidC, yidDinvasion
cdtABCcytotoxicity
flhA, Trg, flgEmotility & chemotaxis
bdlAbiofilm dispersion
cgtB, wlaN LOS
virB11 T4SS
Ruminants & SwineflaA, cadF, peb1, peb3, racR, dnaJ, Cj0020c, pglGadhesion & colonisation[77,78,79,81,82,83,84,85]
iam, pldA, yidC, yidDinvasion
cdtABCcytotoxicity
trg, flgEmotility & chemotaxis
bdlAbiofilm dispersion
sodB, csrA stress response
neuABCCPS
cstII, cstIII LOS
virB11 T4SS
EnvironmentcadFadhesion[85,86,87]
iam, ciaBinvasion
cdtABCcytotoxicity
flgRmotility
pseE, luxSbiofilm formation
rrpBstress response
HumansflaA, cadF, jlpA, pebA, racR, dnaJ, aphC, panBCDadhesion & colonisation[55,56,57,63,65,69,72,79,87,88,89,90,91,92]
pldA, cbrA, ciaB, iamB, iamAinvasion
cdtABC cytotoxicity
flgE, flhB, flgB, flaB, flaC, docCmotility & chemotaxis
htrA stress response
neuA, neuB1, neuC1CPS
Cj1136, Cj1137c, Cj1138, cstII, cstIII, cgtB, wlaNLOS
porA MOMP
virB1, virB11 T4SS
clpB, hcp T6SS
Table
Table 2. Examples of antibiotic agents present in multidrug-resistant C. jejuni/C. coli recovered from clinical and animal origins.
Table 2. Examples of antibiotic agents present in multidrug-resistant C. jejuni/C. coli recovered from clinical and animal origins.
Antibiotic ClassAntibiotic Agent (Resistance-Associated Genetic Determinants)OriginReferences
Aminoglycosidesgentamicin, kanamycin, spectinomycin, streptomycin (aph(2″)-Ii1, aph(2″)-Ii2, apmA, aadE-sat4-aphA-3, aph(3′)-III, spw, aad9, aadE)Clinical[20,90,103,104]
spectinomycin, gentamicin, kanamycin, hygromycin, streptomycin (23S rRNA C1273T point mutation, cmeABC, cmeG, pmrA, hph)Animal[68,75,81,103,104,105]
Macrolideserythromycin, lincosamide (23S rRNA mutation, lnuG)Clinical[90,103,104]
erythromycin, clindamycin, azithromycin, lincosamide (lnuC, 23S rRNA A2075G mutation, ermB, cfrC)Animal[34,57,67,68,75,77,81,104,106,107]
Tetracyclinestetracycline (tetO, pTet-like plasmid)Clinical[20,57,79,90,106,108,109]
tetracycline, doxycycline (tetO, tetM, tetA, tetL, tetB)Animal[18,32,57,67,73,75,79,81,104,105,107,109]
Quinolonesciprofloxacin, nalidixic acid (gyrA gene T86I point mutation)Clinical[20,57,79,90,108,109]
ciprofloxacin, nalidixic acid (gyrA gene C257T point mutation, cmeABC, cmeG)Animal[18,32,57,58,67,68,73,75,79,81,104,105,107,109]
β-lactams ampicillin (blaOXA-193) Clinical[57,90,108]
ampicillin, ceftriaxone, cefixime, cefpodoxime, cefoxitin, oxacillin, cefepime (blaOXA-448, blaOXA-61, blaOXA-133, ykkC, yafP)Animal[57,58,67,73,81,105]
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Bunduruș, I.A.; Balta, I.; Ștef, L.; Ahmadi, M.; Peț, I.; McCleery, D.; Corcionivoschi, N. Overview of Virulence and Antibiotic Resistance in Campylobacter spp. Livestock Isolates. Antibiotics 2023, 12, 402. https://doi.org/10.3390/antibiotics12020402

AMA Style

Bunduruș IA, Balta I, Ștef L, Ahmadi M, Peț I, McCleery D, Corcionivoschi N. Overview of Virulence and Antibiotic Resistance in Campylobacter spp. Livestock Isolates. Antibiotics. 2023; 12(2):402. https://doi.org/10.3390/antibiotics12020402

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Bunduruș, Iulia Adelina, Igori Balta, Lavinia Ștef, Mirela Ahmadi, Ioan Peț, David McCleery, and Nicolae Corcionivoschi. 2023. "Overview of Virulence and Antibiotic Resistance in Campylobacter spp. Livestock Isolates" Antibiotics 12, no. 2: 402. https://doi.org/10.3390/antibiotics12020402

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