1. Introduction
Antimicrobial resistance in bacteria isolated from humans, animals and the environment is continuously rising. This problem and global issue in human and veterinary medicine is a major concern of the “One Health” initiative [
1,
2,
3,
4]. Farm animal husbandry was repeatedly criticized for contributing to the development and spread of antimicrobial resistance using antimicrobials in animal production [
5,
6,
7,
8]. In order to reduce this increase, it is important to further control the use of antimicrobials in livestock farming [
9,
10]. The restriction of certain classes of substances is also a recurring topic of discussion. Both the World Health Organization (WHO) for human health and the World Organization for Animal Health (WOAH) define individual antimicrobial agents and antimicrobial classes as “critical substances” and their use is under ongoing scrutiny [
9,
11]. Consequently, the sale and usage of these antimicrobials has decreased in recent years in Europe. Among those critical substances are enrofloxacin, ceftiofur and colistin [
12].
Enrofloxacin belongs to the quinolone group and is used as a broad-spectrum antimicrobial substance due to its bactericidal effects [
13,
14]. Ceftiofur is a third-generation cephalosporine with a long-lasting efficacy and is traditionally used as an injectable [
15,
16]. Colistin is a polymyxin antimicrobial substance changing the structure of the outer cell membrane of Gram-negative bacteria, leading to leakage and consequently to cell-death [
17]. Resistance may derive from chromosomal mutations as well as from plasmid-transmitted resistance genes [
18,
19]. Colistin is used as a last-choice therapy option in human medicine for the treatment of infections with multidrug-resistant Gram-negative bacteria. In livestock, colistin was widely used, especially for enteric infections, including prophylactic use in pigs [
20,
21,
22,
23,
24,
25,
26]. The commensal Gram-negative bacterium
Escherichia coli (
E. coli) is associated with the gastrointestinal tract. It is a widely distributed bacterium in humans and animals. Apart from this role,
E. coli may turn into an opportunistic pathogen and it is known to harbor and further transmit genetic elements of antimicrobial resistance on various routes [
27,
28,
29]. Thus,
E. coli is also used as an indicator bacterium for antimicrobial resistance surveillance programs, e.g., in surveillance programs run by the European Centre for Disease Prevention and Control (ECDC), the European Food Safety Authority (EFSA) and in national programs like GERM-Vet in Germany [
27,
30,
31].
The characterization of bacteria in terms of their susceptibility towards antimicrobial substances depends on clinical breakpoints. These were defined considering the test group, the body site and the antimicrobial agent [
32,
33,
34]. The breakpoints classify the investigated isolate as “sensitive”, “intermediate” or “resistant” against the tested agent in order to forecast the therapeutic success of the substance. However, clinical breakpoints depend on the host species as well as on the target tissue [
32]. Therefore, an extrapolation on susceptibility in a disease event for humans or another animal species is limited. Further, for some antimicrobial substances, clinical breakpoints are not available, as, for example, for colistin [
32]. As a further possibility to compare antimicrobial efficacy for bacterial species, irrespective of the individual breakpoints, the so-called epidemiological cutoffs (ECOFFS) may be applied, as defined by the European Committee on Antimicrobial Susceptibility Testing (EUCAST). Based on phenotypical characteristics in the form of minimal inhibitory concentration (MIC) distribution patterns, germs exhibiting MICs below the ECOFF are defined as “wild-type” (WT) and germs above the ECOFF are defined “non-wild-type” (NWT). As previously defined, NWT isolates predict the occurrence of acquired resistance mechanisms from the determined MIC, but do not consider the isolation origin, such as the host organism or the affected tissue [
33,
34,
35].
In Germany, the global and European requirements for antimicrobial resistance monitoring in human and veterinary medicine are mainly implemented through the “German Antibiotic Resistance Strategy” (DART). DART provides action plans, surveillance and monitoring systems, which are based on random sample surveys. The monitoring of veterinary antimicrobial resistance includes a program for commensal pathogens as well as a separate program for pathogens known as GERM-Vet. GERM-Vet yearly reports present antimicrobial resistance data for different livestock species including pigs, mainly based on clinical breakpoints, or, if no clinical breakpoint is available, based on observed MIC
90 values [
36]. These data are essential to continuously monitor and evaluate the situation of antimicrobial resistance originating from livestock. As an additional approach, the present study aimed to analyze the antimicrobial resistance of
E. coli isolates from diseased pigs in Bavaria, Germany, with a broader focus. For this purpose, the three “critical class” antimicrobial substances, enrofloxacin, ceftiofur and colistin, were chosen and antimicrobial resistance was determined using the ECOFF classification. Revealing trends in antimicrobial resistances during a certain period enables an estimation of whether current treatment recommendations may be wisely continued.
3. Discussion
Monitoring and surveillance programs for antimicrobial susceptibility are essential for assessing the continuous evolution of antimicrobial resistance on national and global scales. One example is the German program for veterinary pathogens (GERM-Vet) that observes data on various randomized samples and follows clinical breakpoints [
36]. As an addition to the results of this monitoring program, the present study aimed to evaluate the evolution of porcine NWT
E. coli isolates for critically important antibiotics (i.e., colistin, enrofloxacin, ceftiofur) in a defined epidemiological scenario over a five-year period. The ECOFF breakpoints were chosen as they offer the possibility to evaluate antimicrobial resistances under a “One Health” perspective, while CLSI breakpoints better predict therapeutic success in the target species [
32]. The selection of the investigated antimicrobials was based on their importance in both human and veterinary medicine. This importance is displayed by the categorization of all three substances as “highest priority critically important antimicrobials” according to the WHO Advisory Group on Integrated Surveillance of Antimicrobial Resistance (AGISAR) [
11], as well as for ceftiofur and enrofloxacin in “Veterinary critically important antimicrobial agents” or colistin as “Veterinary highly important antimicrobial agents” according to the OIE List of Antimicrobial Agents of Veterinary Importance [
37]. Further, all three substances are classified in Antimicrobial Advice ad hoc Expert Group, AMEG, category B, meaning that these substances are critically important in human medicine and thus their use should be restricted in animals [
38].
Various genetic elements that code for mobilized colistin resistance (mcr) were found on transferable plasmids. As a reaction to the first publication of this finding in 2015, profound restrictions were imposed on the use of colistin in animals and this was adopted in many countries worldwide [
39,
40]. Consequently, the sales and use of colistin were significantly reduced [
12,
40,
41]. Regarding our study period from 2016 to 2020, the sales of polymyxins in Germany declined by 7.59% from a total of 7.9 mg/population correction unit (PCU) to 7.3 mg/PCU [
12]. Also, the actual usage of polymyxin antimicrobials in livestock decreased by 43.6% in Germany between 2014 and 2021 [
42]. In the present study, a relative quantity of 3.01% to 6.63% of the isolates revealed a MIC value for colistin higher than 2 µg/mL. This criterion classifies the isolate as a “non-wild-type” according to the EUCAST ECOFF definition. Furthermore, the highest amount of NWT isolates was observed in 2016 (6.63% NWT
E. coli isolates) and the lowest amount in 2020 (3.01% NWT
E. coli isolates). This positive trend represents a constant decrease in the occurrence of NWT isolates. Statistical evaluation also showed a significant decrease in the probability of the occurrence of NWT isolates among all samples
E. coli for colistin between 2016 and 2020 (
Table 4). These findings are in line with other data published for Germany as data from the German monitoring system GERM-Vet show a decrease in MIC
90 values for porcine pathogenic
E. coli isolates during the same time [
36]. Further, a comparable study from north-western Germany also showed a decrease in colistin resistance among porcine
E. coli between 2015 and 2017 [
43]. In other European countries, similar results have been published. In Spain, a reduction in colistin-resistant
E. coli isolates between 2015 and 2017 [
44], as well as a significant decrease in the detection of the mcr-1 gene in
E. coli isolates in 2017 and 2021 were shown [
45]. In France, a recent study showed a decrease in colistin resistance in porcine
E. coli isolates between 2011 and 2018 [
46]. Further, the EU summary report noted a statistically significant decrease in colistin resistance among commensal porcine
E. coli isolates which were obtained from the caecum during slaughter [
47]. This significant decrease in colistin resistance following a reduction in colistin use was explained in the past. The maintenance of colistin resistance often demands high fitness costs in bacteria, meaning that resistant genotypes do not last for long in the absence of the respective antimicrobial agent [
41].
Similar to colistin, the use of enrofloxacin has been restricted in recent years. The number of sales for fluoroquinolones in Germany dropped between 2016 and 2020, from 24% from 1.0 mg/PCU to 0.8 mg/PCU [
12]. Consequently, the usage in food-producing animals in Germany decreased by 59.0% between 2014 and 2021 [
42]. The MIC values for enrofloxacin in the
E. coli isolates in the present study revealed a relative quantity of 16.50% to 29.01% isolates with a MIC value higher than 0.25 µg/mL, which then classifies the isolate as a “non-wild-type” according to the EUCAST ECOFF system. A statistical analysis revealed a significant increase in the probability of the occurrence of enrofloxacin NWT isolates when comparing the data from 2016 to those of 2020. Similarly, Moenighoff and co-workers stated a significant increase in the enrofloxacin resistance in porcine
E. coli isolates between 2006 and 2017 in north-western Germany [
43], and also the final reports of the German monitoring show an increase in published MIC
90 values for enrofloxacin between 2016 and 2020 [
42]. Reasons for the herein observed negative correlation between the use of enrofloxacin and the evolution of the resistance trend could result from different microbiological characteristics. Fluoroquinolones are known to have a high degree of stability in the environment [
48]. Further, fluoroquinolone resistance genes and resistance genes for other antimicrobials such as ß-lactams and tetracyclines can be found on the same plasmids [
49,
50,
51,
52]. Especially as tetracyclines and penicillins are the most frequently used antimicrobial classes in pig production [
53], this could lead to a co-selection between fluoroquinolone resistance genes and resistance genes for other antimicrobials such as ß-lactamases. Therefore, enrofloxacin resistance could further spread without any exposure to the substance itself. Consequently, this can lead to a formation of further resistant bacteria in the stable environment, a phenomenon that has been described by other authors before [
54,
55]. Environmental spread, inter-/intraspecies spread, trade, export, etc., may lead to a broad distribution of resistant bacteria in Bavaria, Germany, and neighboring countries, and can cause a delay in the decrease in enrofloxacin resistance rates. However, it should also be mentioned that the usage of tetracyclines and penicillins was also decreased in the livestock sector by 56.3% and 37.2% between 2014 and 2021 [
42].
Ceftiofur sales declined by 60.53% from 0.38 mg/PCU in 2016 to 0.15 mg/PCU in 2020 [
12]. However, evolution trends determined by statistical analyses did not show a significant change in ceftiofur resistance when comparing isolates from 2016 to those from 2020 in the present study [
56]. The lack of improvement regarding the susceptibility might be based on the bactericidal mode of action and may need more time to become visible [
57]. It is important to know that although ceftiofur is used only in veterinary medicine, a structurally similar drug, ceftriaxone, is extensively used in human medicine. Both substances operate using the same mechanism [
56]. Another plausible explanation for the nonexistent correlation to the massive reduction in ceftiofur sales could also be caused by the co-selection of ceftiofur resistance genes and other resistance genes, as described earlier for enrofloxacin. Further future effects on decreased usage in veterinary medicine regarding polypeptides (represented by colistin in the present study), fluoroquinolones (enrofloxacin), and 3rd + 4th generation cephalosporines (ceftiofur) will probably be more visible in the coming years.
The overall and worldwide increase in antimicrobial resistance recorded in human and veterinary medicine has led to antimicrobial stewardship programs in human medicine and antimicrobial monitoring programs, and a reduction in chemotherapeutics in agricultural animal production [
58]. In human medicine, these programs are successful if implemented [
58]. Regarding veterinary medicine, a reduction in resistance rates was observed in some cases. However, our study shows that a reduction in the antimicrobial usage of a certain antimicrobial class alone does not necessarily lead to a successful reduction in antimicrobial resistance against this antimicrobial. In addition, the substantial antimicrobial reduction cannot be continued in many countries at this rate. Animal health will be compromised if the therapeutic treatment of animals is further reduced. For this reason, further studies on the specific routes of transmission of antimicrobial resistance against different antimicrobial classes from livestock to humans need to be investigated and measures need to be developed on the herds to prevent transmission. Due to the complexity of the genesis, maintenance and spread of antimicrobial resistance, more factors need to be involved in future concepts for antimicrobial resistance reduction. Among other things, this can include internal hygiene and biosecurity measures. As an example, the occurrence and therefore also the potential spread of resistant bacteria were demonstrated on anesthetic masks for piglets [
59]. Further, animal transport might also be considered as it is well known that this can contribute to the spread of germs [
60]. While the present study indicates the occurrence of antimicrobial resistance from a total number of porcine
E. coli isolates, future studies also need to evaluate different production groups (e.g., organic vs. non-organic production) and age groups of pigs. As already requested by other authors, a closer collaboration with human medicine is also required [
4].