Location via proxy:   [ UP ]  
[Report a bug]   [Manage cookies]                
Next Article in Journal
Real-World Data on Antibiotic Group Treatment in European Livestock: Drivers, Conditions, and Alternatives
Next Article in Special Issue
Environmental Bovine Mastitis Pathogens: Prevalence, Antimicrobial Susceptibility, and Sensitivity to Thymus vulgaris L., Thymus serpyllum L., and Origanum vulgare L. Essential Oils
Previous Article in Journal
Effects of Sodium Hexametaphosphate and Fluoride on the pH and Inorganic Components of Streptococcus mutans and Candida albicans Biofilm after Sucrose Exposure
Previous Article in Special Issue
Antimicrobial Susceptibility of Streptococcus suis Isolated from Diseased Pigs in Thailand, 2018–2020
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Antibiotics
Volume 11
Issue 8
10.3390/antibiotics11081045
antibiotics-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

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

Genomic Analysis of Acinetobacter baumannii Isolates Carrying OXA-23 and OXA-58 Genes from Animals Reveals ST1 and ST25 as Major Clonal Lineages

by
Lisa Jacobmeyer
1,
Torsten Semmler
2,
Ivonne Stamm
3 and
Christa Ewers
1,*
1
Institute of Hygiene and Infectious Diseases of Animals, Department of Veterinary Medicine, Justus-Liebig University Giessen, 35392 Giessen, Germany
2
NG1 Microbial Genomics, Robert Koch Institute, 13353 Berlin, Germany
3
Vet Med Labor GmbH, 70806 Kornwestheim, Germany
*
Author to whom correspondence should be addressed.
Antibiotics 2022, 11(8), 1045; https://doi.org/10.3390/antibiotics11081045
Submission received: 31 May 2022 / Revised: 26 July 2022 / Accepted: 26 July 2022 / Published: 3 August 2022
(This article belongs to the Special Issue Antimicrobial Resistance in Animal and Zoonotic Pathogens)
Browse Figures
Versions Notes

Abstract

:
Acinetobacter baumannii is increasingly being recognized as a relevant pathogen for animals with a putative zoonotic impact. This study aimed at identifying and characterizing carbapenemase-producing A. baumannii from animals. Among 503 A. baumannii, mainly isolated from dogs/cats (75.7%) between 2013 and 2018, 42 isolates from 22 veterinary clinics (VCs) harboured blaOXA-58 (n = 29) or blaOXA-23 (n = 13). The blaOXA-58 gene was located on plasmids (11.4–21.1 kb) within different genetic surroundings (patterns A–D). BlaOXA-23 was embedded in Tn2006 on the chromosome (n = 4; pattern a) or Tn2008 on plasmids (n = 9; 41.2–71.3 kb; patterns b–e). The predominant IC1-ST1P-OXA-58 (66.7%; 96.4% cgMLST complex type (CT)-1808) was disseminated among 11 VCs in Germany. Resistance islands AbaR3-like (n = 15) and AbaR10 (n = 1) have emerged among ST1-isolates since 2016. IC7-ST25P-OXA-23 isolates (21.4%) occurred in seven VCs in Germany, France and Italy and differed in their resistance gene patterns from those of OXA-58 isolates. They were separated into six CTs, basically according to their regional origin. Other STs observed were ST10, ST578 and ST602. In conclusion, OXA-23 and OXA-58 were linked with ST1 and ST25, two globally distributed lineages in humans. The suggested transmission of certain lineages within and among VCs together with the acquisition of AbaR islands hints at a successful dissemination of multidrug-resistant strains in the VC environment.

1. Introduction

Acinetobacter baumannii is an opportunistic Gram-negative bacterium that is responsible for a wide range of healthcare-associated infections such as ventilator-associated pneumonia, wound infections or catheter-associated bloodstream infections, especially in intensive care units (ICU) [1]. The majority of hospital-acquired infections are caused by A. baumannii strains belonging to international clones IC1, IC2 and, more recently, to IC7, corresponding to clonal complexes CC1, CC2, and CC25 and to sequence types ST1, ST2 and ST25 (Pasteur scheme) [1,2,3,4]. In the case of infections with multidrug-resistant A. baumannii, therapeutic options are generally limited. Of particular concern is the emergence of A. baumannii with resistance to carbapenems, as these are the cornerstone of treatment for A. baumannii infections [5]. Carbapenem-resistant (CR) A. baumannii are among the critical-priority pathogens on the WHO priority list of antibiotic-resistant bacteria for effective drug development [6]. In addition to the presence of chromosomally located blaOXA-51-like genes that confer carbapenem-resistance when overexpressed due to insertion sequences upstream of the genes, the acquisition of plasmid-located carbapenemases, predominantly oxacillinases OXA-23, OXA-58 and NDM-like β-lactamases, represent the most common mechanisms of CR in A. baumannii [1,7]. Carbapenemase (CP)-producing A. baumannii are on a global rise in humans, and in the last decade, a growing number of studies also confirmed their dissemination in companion [8,9,10,11,12,13] and livestock animals including horses [14,15,16,17,18]. Previous reports gave evidence that A. baumannii from companion animals revealed the same clonal lineages and resistance determinants as human strains, indicating a spill-over of such strains from humans to animals [8,11,19].
The aim of this study was to determine the presence of CP-producing A. baumannii isolates among clinical isolates from animals. CP producers were assessed for their antimicrobial susceptibility and their genomes were sequenced to identify resistance genes and their genetic surroundings and to determine the phylogenetic background of the isolates by multilocus sequence typing (MLST) and core genome MLST analysis.

2. Results

2.1. Presence and Type of Carbapenemase Genes

We identified 42 isolates that carried a carbapenemase gene. Among the first collection of 473 randomly collected A. baumannii isolates, 15 (3.2%) isolates carried a CP gene: blaOXA-58 in all cases (Table 1). Nine of these isolates were from clinical specimens that had been taken from six dogs (one dog was sampled twice at an interval of five days) and two cats. Five isolates were cultivated from medical devices, i.e., from central venous catheters, that were used along with the treatment of another three dogs and two cats. Finally, one isolate was cultivated from an air conditioner in a university clinic for small animals by pure chance. Among the second collection (n = 29) of pre-selected carbapenem non-susceptible A. baumannii isolates from dogs and cats, 27 (93.1%) isolates carried acquired CP genes, namely blaOXA-58 (n = 14/48.37%) and blaOXA-23 (n = 13/44.8%). For reasons of clarity, we will refer to the CP-positive A. baumannii isolates from the first and second sample collection as one group of 42 isolates. The 42 CP positive strains of this study were obtained from 22 veterinary clinics and practices (referred to as clinic-1 to clinic-22) in Germany (31 isolates; 13 clinics), France (9 isolates; 7 clinics), and Italy (2 isolates; 2 clinics). with a maximum of nine CR A. baumannii isolates obtained from one institution, namely clinic 4 (JLU university clinic). The NDM-1-producing isolate has recently been published by our group and will not be further considered in the Results section [13].

2.2. MLST and Phylogenetic Analysis

The majority of CP-producing A. baumannii isolates belonged to the worldwide distributed sequence types ST1P/ST231Ox (66.7%; isolated from dogs and cats in Germany) and ST25P/ST229Ox (21.4%; isolated from dogs and cats in Germany, France, and Italy), representing international clones IC1 and IC7 (Table 2). Other STs determined were ST602P/ST732Ox (7.1%; isolated from three cats in France), ST10P/ST447Ox (2.4%; isolated from a dog in Italy), and ST578P/ST799Ox (2.4%; isolated from a dog in France). While ST10P belongs to IC8, the other two STs could not be grouped to IC1-IC9 based on a comparison of the genome of companion animal A. baumannii isolates with the genomes of representative members of international clones 1 to 9 (Supplementary Materials Figure S1).
A minimum spanning tree based on cgMLST complex types (CT) of 42 CP-producing isolates was created (Figure 1). The cgMLST clustering was based on 2390 genes and broadly followed the grouping of the isolates into STs. As expected, cgMLST analysis revealed a higher resolution compared to the results from the seven-gene MLST. Twelve different cgMLST CTs were determined. Eight CTs were unique, the remaining four types were assigned to four clusters. With the exception of ST1 isolate IHIT34211 (CT-2175), that was cultivated from the nose of a dog from veterinary clinic-17 in Germany in 2017, the remaining 27 ST1 isolates belonged to the predominant complex-type CT-1808, given the species-specific threshold of ≤10 alleles differences. Accordingly, all these isolates belonged to a single cluster (cluster 1). They were restricted to Germany and were obtained from twelve veterinary clinics between December 2014 and August 2018 (Figure 1B, Table 2). Cluster 2 included three ST602 isolates (CT-1368 and CT-2191) from two veterinary clinics in France, and cluster 3 comprised three ST25 isolates (CT-2184 and CT-2186), also from two clinics in France. Finally, cluster 4 was made up of three ST-25 isolates (CT-2177) from two clinics in Germany. Overall, the ST25 isolates were assigned to six different CTs that differed by 2 to 132 alleles.
A phylogenomic tree of all strains sequenced in the present study including relevant metadata is provided in the following figure (Figure 2).

2.3. Genomic Location of Carbapenemase Genes and Ttransformation Assays

Southern blot hybridization of S1-Nuclease digested whole-cell DNA together with whole-genome sequence data analysis revealed the location of blaOXA-23 and blaOXA-58 on plasmids for 38 A. baumannii isolates. The remaining four isolates, all ST25 (CT-2184, CT-2185, and CT-2186) and all from one veterinary clinic in France, carried their blaOXA-23 gene on the chromosome (Figure 3, pattern a). Data from bridging PCRs and amplicon sequencing revealed the presence of four different OXA-23 plasmids, varying from 41.2 kb (plasmid type d, 1 isolate) to 48.4 kb (b, 4 isolates), 55.8 kb (c, 1 isolate) and 71.3 kb (e, 3 isolates) in size. OXA-58 plasmids appeared in four different types with 21.1 kb (plasmid type A, 11 isolates), 11.3 kb (B, 10 isolates), 12.6 kb (C, 7 isolates), and 13.9 kb (D, 1 isolate) in size. None of the plasmids carried other antimicrobial resistance genes. The direct genetic environment of blaOXA-23 and blaOXA-58 genes in the different plasmid types is illustrated in Figure 3 and Figure 4, and the assignment of isolates to plasmid types is provided in Table 2.
Distinct plasmid types were basically linked with a certain ST and CT, but distinct STs and CTs could also reveal the presence of different plasmid types. For example, OXA-58 plasmid type A appeared solely in ST1/CT-1808 isolates. However, ST1/CT-1808 isolates carried not only OXA-58 plasmids of type A, but also of types B, C, and D. In contrast, OXA-23 plasmids were not detected among ST1/CT-1808 isolates but were distributed among ST10, ST25 and ST602 isolates in Germany, Italy and France. Notably, OXA-23 plasmid type b was detected in three ST25 isolates from Germany and in one ST10 isolate from Italy. Regarding this exception, OXA-23 and OXA-58 plasmid types differed according to STs and country of origin. Veterinary clinics where at least two CP-producing isolates were obtained mostly revealed more than one plasmid type, i.e., clinic 1 (OXA-58 plasmid type A, B and D), clinic 4 (type A and C) and clinic 6 (group C and D) (Table 2).
A total of 24 of the 38 CR-A. baumannii with plasmid-located OXA-23 (n = 8) and OXA-58 (n = 16) CP genes, representing different MLST types, animal hosts and isolation dates, were included in transformation assays. Except for three OXA-23 plasmids, the OXA-23/OXA-58 plasmids of the remaining 21 isolates were transformable. Compared with the A. baumannii recipient strain ATCC 17978, the transformants showed increased MICs for piperacillin (≥128 mg/L; 100% resistant) and imipenem (2–≥16 mg/L; 63% resistant) (Supplementary Materials Table S1).

2.4. Resistance Phenotype and Genotype

All 42 CP-producing isolates were resistant to imipenem (MIC ≥ 8 mg/L) (Supplementary Materials Table S2). According to the results from E-Test, 27 isolates were resistant to meropenem (MIC from 8 to ≥32 mg/L) and 21 isolates were resistant to doripenem (MIC from 6 to ≥32 mg/L). All isolates showed resistance (either acquired or intrinsic) to ampicillin, piperacillin, piperacillin/tazobactam, amoxicillin/clavulanate, cephalotin, cephalexin, chloramphenicol, tetracycline, and nitrofurantoin. In addition, a different number of strains was resistant to cefpirom (23.8%), gentamicin (54.8%), ciprofloxacin (90.5%), moxifloxacin (88.1%), enrofloxacin (90.5%), marbofloxacin (90.5%), and to the sulfamethoxazole–trimethoprim combination (59.5%). Colistin MICs ranged from 0.5 to 2.0 mg/L (all susceptible), while low MICs were observed for tigecycline (S MIC ≤ 0.5–1 mg/L, 100%), amikacin (S ≤ 2 mg/L, n = 40, 95.2%; I = 32mg/L, n = 2, 4.8%) and tobramycin (S ≤ 1 mg/L, n = 41; 97.6%; I = 8 mg/L, n = 1, 2.4%).
Multiple antimicrobial-resistance (AMR) genes and profiles were detected in the CP-producing A. baumannii isolates. We identified β-lactamase genes blaADC-2-like (2.4%), blaADC-11 (66.7%), blaADC-26 (21.4%), blaADC-32 (7.1%), blaADC-76 (2.4%), and blaTEM-1 (42.9%), aminoglycoside modifying enzymes aac(3)-Ia (40.5%), aac(3)-IIa (11.9%), aad(3`)-IVa (2.4%), aac(6`)-Ian (11.9%), aadA1 (40.5%), aph(3`)-Ia (2.4%), aph(3`)-VIa (4.8%), aph(3``)-Ib (21.4%), and aph(6)-Id (21.4%), tetracycline genes tet(A) (40.5%), tet(B) (14.3%) and tet(R) (54.8%), sulphonamide-resistance genes sul1 (42.9%) and sul2 (14.3%), chloramphenicol acetyltransferase gene catA1 (40.5%), and trimethoprim-resistance gene dfrA1 (2.4%). In addition, the distribution of antibiotic efflux pump genes was as follows: abeS, abaF, abaQ, amvA, adeF, adeJ, adeK, and adeL (100% each), adeC (69.0%), adeG (73.8%), adeH (69.0%), adeI (78.6%), adeN (88.1%), and adeR (97.6%). The disinfectant efflux pump gene qacE∆1 was present in 40.5% of the isolates. Acinetobacter baumannii antibiotic resistance islands (AbaR) were detected in 64.3% of the 28 ST1 isolates, whereas isolates belonging to ST10, ST25, ST578 and ST602 were AbaR-negative. Notably, ST1 isolates from earlier than 2016 were also AbaR-negative, while all isolates obtained since 2016 carried either an AbaR3-like structure (n = 17) or AbaR10 (n = 1; isolate from 2018) (Supplementary Table S2; Figure 1B). As originally described, the AbaR3-like island consisted of a Tn6019 backbone, was embedded in the chromosomal ATPase gene comM [20,21] and carried a multiple antibiotic resistance region (MARR) in the center in transposon Tn6018 containing blaTEM-1, aacC1, aadA1, tet(A), tet(R), sul1 and catA1. In contrast to the original AbaR3 island, which is 63 kb in size in the human IC1-A baumannii strain A85 [22], the AbaR3-like island lacked the Tn6020-related gene aphA1 and revealed a disruption in the ISAba1 sequences that are usually flanking both sides of the kanamycin gene. As previously described for strainAB058, the AbaR10 island was 31 kb in size and carried only sul1 in the MARR of Tn6018 [23]. OXA-58 A. baumannii strains assigned to cgMLST CT-1808 showed a very similar profile of efflux systems. All CT-1808 isolates that carried the AbaR3-like island also carried efflux genes of the major facilitator superfamily MFS (abaF, abaQ, amvA and qacE∆1), the resistance-nodulation-cell-division (RND) family (adeC, adeF, adeG, adeH, adeI, adeJ, adeK, adeL, adeN and adeR) and the small multidrug resistance (SMR) family (abeS). The AbaR10 positive strain and AbaR-negative strains of CT-1808 revealed the same efflux gene profile but lacked qacE∆1. Only one blaOXA-58 strain assigned to ST578/CT-2189 showed a unique efflux gene profile (abeS, abaF, abaQ, amvA, adeF, adeH, adeI, adeJ, adeK, adeL, adeN and adeR). None of the blaOXA-23 isolates carried either qacE∆1 or adeH. Strains of the same ST also showed a similar efflux gene profile, except for one ST25 strain, that did not possess adeN (Supplementary Materials Table S2).
All 42 isolates carried intrinsic oxacillinases that correlated well with the sequence types of the isolates: ST1P - OXA-69, ST25P - OXA-64, ST10P - OXA-68, ST578P - OXA-65, and ST602P - OXA-378. Only one ST25 strain, which was isolated from the urine of a cat from France (IHIT34502), revealed the presence of insertion sequence ISAba1 upstream of the oxacillinase gene blaOXA-64 and also upstream of its blaADC-26 gene.

2.5. Flanking Region of Carbapenemase Genes

To characterize the blaOXA-23 genomic region in the different strains, WGS contigs of 175 bp to 57,862 bp in size were used to create primer pairs for PCR mapping. In the case of blaOXA-58 plasmids, one to ten contigs between 74 bp and 21,069 bp per isolate were concatenated in silico based on PCR mapping results.
The transposons Tn2008 and Tn2006 were identified as genetic structures harbouring the blaOXA-23 gene (Figure 3). In Tn2008, the blaOXA-23 gene was flanked by the insertion sequence ISAba1 27 bp upstream, and by a putative ATPase gene downstream. Tn2006 is similar to Tn2008, but here, the blaOXA-23 gene is flanked by two copies of ISAba1, which are located in opposite orientations. In our isolates, the transposon structures Tn2008 and Tn2006 were embedded in different genomic regions (a–e), as shown in Figure 3 and Figure 1B. The blaOXA-58 genes were located on four different plasmid structures (A–D), as shown in Figure 4 and indicated in Figure 1B.
The extent and orientation of genes and open reading frames (orf) are shown by a horizontal arrow with the gene names below. The blaOXA-23 gene is shown in red, the ATPase gene in blue, orfs in grey, and other genes in light green. Insertion sequence (IS) elements are represented by a black framed box with the orientation of the transposase genes shown within. Transposons Tn2006 and Tn2008 are shown above with an arrow indicating their location. Sequences below the transposon labels indicate the distance between ISAba1 and the blaOXA-23 start codon. Primer pairs used for bridging PCRs are shown as numbers (forward primer in black, reverse primer in red) above the respective genes (Supplementary Materials Table S3). Numbers to the right indicate the size of the genetic regions displayed in the figure and the estimated total size of the plasmids (shown in brackets).

3. Discussion

A. baumannii is a globally distributed pathogen associated with clinical infections in both humans and animals. The emergence of multidrug-resistant isolates drastically limits antibiotic treatment options, particularly in intensive-care medicine [24]. Data on the antimicrobial resistance and phylogenetic background of A. baumannii isolates from diseased animals are quite limited. Only a few studies systematically screened a representative number of A. baumannii isolates for carbapenemases that are most common among humans, and even less made use of whole genome sequence analysis to provide a detailed characterization of the isolates [8,9,13,16,19,25].
In this study, we provide a comprehensive analysis of CP-producing A. baumannii isolates from animals that were either hospitalized or treated in veterinary clinics in Germany (n = 13 clinics), France (n = 7) and Italy (n = 2) during the years 2014 and 2018. We could show that OXA-23 and OXA-58, which are globally distributed CPs in humans, are frequently present in A. baumannii isolates obtained from clinical samples of cats and dogs and from medical devices used for the treatment of these animals. In contrast, none of the A. baumannii isolates from livestock animals (n = 50 isolates), horses (n = 46), small animals (n = 15), and other animals (n = 10) harboured a carbapenemase. To date, to the best of our knowledge, merely 12 studies described the occurrence of CPs, predominantly OXA-23, but also OXA-72 and NDM-1, in Acinetobacter baumannii from cats and dogs in Germany, France, Portugal, Italy, Serbia, Pakistan and Thailand [8,9,10,11,12,13,19,25,26,27,28] (Table 3).
Infrequent findings of CP-producing isolates that were clearly assigned to the species A. baumannii have been reported from livestock animals, i.e., from cattle [15,31], sheep [18] swine [14,15,32], and poultry [15] from France, Croatia, Lebanon, Pakistan, and Canada. OXA-23 was the most frequently found CP in these studies while OXA-40, OXA-58, NDM-1 and PER-1 were single findings.
We determined OXA-58 as the predominant CP type (69.1%), while about one third of the CP-producing isolates in our study carried the blaOXA-23 gene. Of note, nearly all OXA-58 isolates (96.6%) were from companion animals in Germany, while the majority of OXA-23 isolates (76.9%) were from companion animals in France and Italy, indicating a country-specific distribution. On the other hand, more than two thirds (69.2%) of the OXA-23 isolates were assigned to ST25, whereas OXA-58 was almost (96.6%) restricted to ST1 isolates.
In Europe and also worldwide, OXA-23 is by far the most common β-lactamase among A. baumannii strains from human patients, including those involved in hospital outbreaks [7,33,34,35,36,37]. In Germany, the National Reference Laboratory for multidrug-resistant Gram-negative bacteria rated OXA-23 as predominant and OXA-72 as the second most common CP among A. baumannii isolates that were sent by nationwide microbiology laboratories for clarification of phenotypic carbapenem-resistance over the last years [38]. In contrast, OXA-58 was found in significantly lower numbers ranking between the third and tenth position between 2015 and 2020 but was not detected in 2021. The fact that 11 of 13 German veterinary clinics revealed the presence of OXA-58-producing isolates suggests a different distribution of this CP type in companion animals compared to what is going on in the medical field in our country. While this could indicate different sources of infections in humans and animals, a spillover of OXA-58 plasmids from humans to animals can still not entirely be ruled out.
As the predominant ST among CP-producing A. baumannii in humans is ST2Pa and our OXA-58 isolates all belonged to ST1 and almost always to cgMLST cluster type CT-1808, a transmission of isolates from humans to animals is less likely than an initial transfer of an OXA-58 plasmid by horizontal gene transfer and a subsequent clonal dissemination of CT-1808 among companion animals in Germany.
The random finding of an OXA-58-producing A. baumannii isolate from an air conditioner in one of the veterinary clinics underlines the relevance of the clinical environment as a putative source of MDR bacteria. This has recently been shown for high-risk clone ST11 of CP-producing Klebsiella pneumoniae in a veterinary referral hospital in Switzerland. Brilhante et al. (2021) showed that clinical CP K. pneumoniae strains were highly related to those contaminating the clinical environment [39]. The strain from an air conditioner in the present study belonged to the most common cgMLST type 1808 and carried the same blaOXA-58 plasmid group C as the clinical strains detected in the same veterinary clinic. These results highlight the probability that MDR A. baumannii survive in the clinical environment and may be further dispersed and transferred to animals and humans.
Regarding France and Italy, where isolates from dogs and cats nearly always carried OXA-23, the situation appeared much more similar to that in humans in those countries. In a cross-sectional countrywide survey on the distribution of carbapenem-resistant A. baumannii in Italy, Principe et al. (2014) reported that among 25 centers, OXA-23 was the predominant CP (81.6%) followed by OXA-58 (4.5%), indicating an epidemic diffusion of OXA-23 [34]. Jeannot et al. (2014) determined blaOXA-23 in 82% of the samples that were collected along with 37 outbreaks in France, while blaOXA-58 was only present in 7% of the isolates [40]. Our group previously detected OXA-23 from an ST1P isolate originating from a cat with urinary tract infection treated in clinic 4 of the present study in the year 2000 [8,9]. This isolate belonged to cgMLST type CT-720 and revealed up to 84 different alleles to CT-1808, suggesting that it is not a direct ancestor of this epidemic lineage. In addition, we recently described OXA-23 strains isolated from two dogs treated in veterinary clinics that are not included in the current study [8]. The two isolates belonged to ST10P/585Ox and thus to the same ST that has been observed for one OXA-23 isolate of the present study, which originated from a dog in Italy (IHIT29027; ST10P/447Ox). However, the strain from Italy (CT-2190) and previous isolates from Germany (CT-717) differed in their cgMLST types by 425 alleles, indicating only moderate relatedness from a whole genome sequence perspective. As the fraction of animal isolates from France and Italy was quite low in the present study, conclusions should be considered with caution.
The majority of our OXA-23 isolates (69.2%) belonged to ST25, which is a globally distributed clone that has been associated with infections and outbreaks in humans, particularly in the ICUs, in Europe, South America, and Asia [3,41,42]. Nine ST25 isolates were separated into six CTs and revealed three antimicrobial resistance patterns, underlining the phylogenetic and genomic diversity of the ST25 lineage as previously shown for human clinical isolates [3]. In Germany, CT-2177 seems to be established in the veterinary environment, while the strains from France showed from 2 to 94 allele differences, indicating an independent spread of different CTs. In 2017, Lupo and co-workers reported that OXA-23-ST25 A. baumannii might be endemically distributed in companion animals in France [19]. They investigated 41 A. baumannii isolates from diseased pets from 2011 to 2015 and determined seven OXA-23-producing A. baumannii that belonged to ST25. As the seven isolates originated in five departments in two regions, the authors suggested a clonal dissemination among companion animals in France. In support of this, Herivaux and co-workers identified a high rate of asymptomatic dog carriers of ST25-OXA-23-A. baumannii isolates (2.7%) in France in 2015 and suggested that pets could serve as a possible reservoir of community acquired infections [12]. Notably, in Switzerland, ST25 and ST1 are also the predominant A. baumannii lineages in hospitalized animals, although OXA-23 and OXA-58-producing isolates have not been described [43].
In a previous survey on A. baumannii isolates obtained from diseased companion animals in Germany between 2000 and 2013, we could show that ST2 was the major lineage among carbapenem-susceptible isolates. A very recent report from the Netherlands described two unrelated ST2 lineages of carbapenem non-resistant A. baumannii as a cause of two outbreaks in a companion animal ICU that occurred in 2012 and 2014. This, together with sporadic findings of carbapenemase-producing ST2-A. baumannii isolates in companion animals in Portugal [11], Italy [25], Thailand [26] and Pakistan [28], underlines that, with ST2, ST1 and ST25, three of the most relevant sequence types globally distributed in the human domain are also disseminated among companion animals. In a recent study from Germany, Schleicher et al. demonstrated that the population structure of carbapenem-susceptible A. baumannii from humans is highly diverse, whereas imipenem non-susceptibility was strongly linked with the clonal lineages IC2 and IC1, suggesting a high clonality of carbapenem-resistant isolates [44].
According to cgMLST analysis, the 42 carbapenem-resistant A. baumannii isolates were assigned to 12 cluster types. Five of these CTs were assigned to four clusters (cluster 1–4), while the remaining seven CTs were unique. As already mentioned, CT-1808 was predominant in Germany, where it occurred in 11 veterinary clinics. The repeated finding of this type over longer periods in VCs 1 (n = 6; 2014–2017) and 6 (n = 9; 2015–2018) underlines a putative nosocomial spread within these clinics. Most notably, earlier ST1/CT-1808 isolates from 2014 and 2015 (n = 10) only possessed cephalosporinase gene blaADC-11 in addition to their blaOXA-58 gene. Later isolates collected between 2016 and 2018 have acquired either an AbaR3-like island (n = 16) or AbaR10 (n = 1) (Figure 1B). At least for clinic 1 and clinic 4, which yielded carbapenem-resistant ST1 isolates in both time periods, the emergence of AbaR3-like positive isolates could have occurred within the clinics, while the original entry of this resistance island into the population remains unsolved. Along with the uptake of the AbaR3-like island, the isolates gained resistance genes tet(A), tet(R), sul1 and catA1, and the cassette-associated aacC1 and aadA1 genes (Supplementary Materials Table S2). Accordingly, they showed phenotypic resistance to gentamicin and to the trimethoprim–sulfamethoxazole combination and higher MICs (≥16 mg/L) to tetracycline as compared to the earlier ST1 isolates. Additionally, AbaR10, which was first described by Adams et al. (2010), rendered isolate IHIT36988 additional resistance to the trimethoprim-sulfamethoxazole combination as it encodes the sul1 gene [23].
To date, the majority of human clinical IC1 isolates carry either AbaR0 or its derivative AbaR3, which arose around 1990, or a variant from one of them, that has evolved since then [22,45]. AbaR3 is a large genomic-resistance island within a complex transposon that is located at a specific position in the ATPase-encoding comM gene, which is involved in natural transformation of A. baumannii [21,46,47]. Previous variants arose by different mechanisms, including recombination events, gene cassette addition or replacement, and what also happened in our isolates: deletions caused by one of three internal IS26 sequences [22,45]. We could show that complex A. baumannii resistance islands are not only globally distributed in IC1-A. baumannii isolates from humans but that they occur frequently among veterinary isolates and may undergo evolutionary changes. By that, the isolates might gain a selective advantage towards a certain antimicrobial selective environment in a VC, similar to what has happened in the medical field. Here, the selective advantage provided by AbaR3 or its variants could have played a role in the spread of IC1 in European hospitals in the 1980s, as the resistance mechanisms encoded by AbaR3 were effective against many antibiotics used at that time [46]. Most notably, a number of other variants of the A. baumannii resistance island arisen since then confer resistance to critical important antibiotics including fluoroquinolones, cephalosporins, and aminoglycosides [22,45] and thus contribute to the emergence of multi-drug-resistant strains [21,22,45].
All 29 OXA-58 positive isolates carried blaOXA-58 on a plasmid, almost always embedded in a previously described genetic context in human isolates with ISAba3, araC and lysE [48,49]. However, when determining the wider environment, we identified four different patterns (A–D) around the blaOXA-58 gene, indicating different origins and evolutions of plasmids or genetic fragments. The patterns were always identical among isolates of the same complex-type but were not restricted to one CT. This could suggest both a clonal distribution of plasmids but also a spread by horizontal gene transfer. The genetic contexts of blaOXA-58 genes in our isolates shared high similarity with plasmids from human patients, such as pAba3207a of A. baumannii 3207 that was detected in Mexico [50], pWA3 of A. baumannii WA3 isolated in China [51], and pABIR of A. baumannii ABIR found in a patient in the Lebanon [52]. Tn2008 of the OXA-23-positive A. baumannii isolates from our study shared high similarity (99.96%) with the same genetic region that was determined in A. baumannii isolate IHIT7853 (ST1, CT-720), which was isolated from a cat treated in VC4 in 2010 [8]. Furthermore, A. baumannii DU202, detected in a patient in Korea [52] and A. baumannii K50 that was isolated from a wound in a human patient in Kuwait, showed 99.9% identity with the transposon structure of our blaOXA-23-positive A. baumannii isolates [53]. This, together with the sharing of clonal lineages of A. baumannii isolates maintaining the OXA-23 and OXA-58 plasmids, suggests at least partial overlaps between certain groups of carbapenemase-producing A. baumannii isolates from humans and animals. High-resolution genomic and plasmidomic analysis including combined short- and long-read sequencing techniques will help to further elucidate the similarities and differences between these bacteria in the different populations. It may also help to infer whether transmission events could have occurred between humans and animals and in which direction they have taken place.

4. Materials and Methods

4.1. Bacterial Strains and DNA Isolation

Acinetobacter baumannii strains were collected during routine microbiology investigations in two veterinary diagnostic laboratories in Germany. The first collection of 473 strains was isolated from clinical specimens (n = 398) or from different organs during necropsy (n = 40) obtained from dogs/cats (n = 351), livestock animals (n = 50), horses (n = 46), pets (n = 15), zoo animals (n = 7), and birds (n = 3) (Table 4). The samples were provided by 85 veterinary clinics and practices and by a university Institute of Veterinary Pathology in Germany between January 2013 and August 2018. Another 34 isolates of this first collection were obtained from clinical devices, such as catheter, tubes, and implants, used during therapeutic or surgical treatment of dogs and cats in three veterinary clinics; one strain was isolated from an air conditioner in a veterinary hospital. The 398 A. baumannii strains (all from Germany) from clinical specimens were isolated from wounds and abscesses (31.4%), respiratory tract and nasopharynx (21.1%), skin and hair (13.1%), the urinary tract (10.6%), and from various other body sites, as detailed in Supplementary Table S1.
The second collection included carbapenem non-susceptible (imipenem MIC ≥ 2 mg/L) A. baumannii (n = 29) strains provided by an external veterinary diagnostic laboratory in Germany (Table 4). These isolates were collected from the urinary tract (n = 14), wounds (n = 7), and from other clinical sites from dogs (n = 19) and cats (n = 10) in veterinary clinics in Germany (n = 18), France (n = 9), and Italy (n = 2).
All samples were initially cultivated on blood agar plates without antibiotics. Species identification was performed with MALDI-TOF MS using a Microflex LT/SH mass spectrometer and the biotyper database (Maldi Biotyper 3.0, V. 7.0) (both from Bruker Daltonics, Bremen, Germany) and by performing gyrB multiplex PCR [53].
To extract genomic DNA, late log-phase cells were harvested and lysed with EDTA, lysozyme, and detergent treatment, followed by proteinase K and RNase digestion using the DNeasy Blood & Tissue Kit (Qiagen, Hilden, Germany) according to the manufacturer’s recommendation. The DNA was stored at −20 °C until further use.

4.2. Detection of Carbapenemase Genes

Acinetobacter baumannii strains were screened for β-lactamase genes coding for CPs of the families OXA-23/-40/-58/-143/-235, VIM, NDM, KPC, OXA-48, GES, GIM, and IMP by PCR [54,55,56,57,58,59] using previously published primers and protocols (Supplementary Materials Table S4). The genomes of strains that possessed an acquired CP gene were further sequenced.

4.3. Antimicrobial Susceptibility Testing

A. baumannii strains that carried an acquired CP gene were tested for their antimicrobial susceptibility to 27 antimicrobial agents by using the VITEK 2 system (bioMérieux→, Nuertingen, Germany; AST cards GN38 and GN238). Antibiotic gradient strips (Liofilchem®, Roseto degli Abruzzi, Italy) were additionally used to test the susceptibility of the strains to imipenem, meropenem and doripenem. Susceptibility to colistin was determined by using the E1-102-040 plate of the MICRONAUT system (Merlin Diagnostics, Bornheim-Hersel, Germany). MICs were interpreted according to breakpoints defined for human Acinetobacter spp. by CLSI (Clinical and Laboratory Standards Institute. Performance standards for antimicrobial susceptibility testing. 29th ed. Document M100S.Wayne, PA: CLSI; 2019). For antibiotics without a defined breakpoint for Acinetobacter spp., breakpoints of agents belonging to the same antibiotic class or breakpoints for Enterobacterales were used for interpretation.

4.4. Genome Sequencing and Annotation

Sequencing of A. baumannii genomes was performed using Illumina MiSeq 300 bp paired-end sequencing with an obtained coverage > 90×. After quality control using the NGS tool kit13 (70% of bases with a phred score > 20), high-quality filtered reads were used for de novo assembly into contiguous sequences (contigs) and subsequently into scaffolds using SPAdes v3.9 (http://bioinf.spbau.ru/spades, accessed on 8 February 2022) [26]. Assembled draft genomes were annotated using Prodigal [27].

4.5. MLST, cgMLST and Phylogenetic Comparison

Multilocus sequence types were deduced from whole genome sequence data using MLST 2.0 (https://cge.cbs.dtu.dk/services/MLST/, accessed on 10 February 2022) and the MLST scheme developed by the Pasteur Institute [60]. To determine the clonal relationship of CR-A. baumannii strains, core genome MLST (cgMLST) implemented in Ridom SeqSphere + version 7.7.0 (Ridom GmbH, Germany) was performed [61]. Allelic profiles were compared by using the “pairwise ignoring missing values” parameter during distance calculation. The cluster definition threshold was set at a maximum difference of 10 alleles in a pairwise comparison.
Phylogenetic relationships were determined by applying a gene-by-gene approach on the dataset to generate a core genome alignment and subsequently a phylogenetic tree. The core genome alignment was assembled by a gene-wise alignment with Mafft v7.407 (http://mafft.cbrc.jp/alignment/server/, accessed on 2 June 2022) of 2646 core genes that were present in at least 99% of the strains (sequence similarity min. 70%, sequence coverage min. 90%) and were concatenated afterwards. The resulting alignment was used to infer a phylogeny with 100 bootstrap replicates using RAxML v.8.2.10 (https://github.com/stamatak/standard-RAxML, accessed on 2 June 2022) with a general time-reversible model and gamma correction for site rate variation. iTOL v5 (https://itol.embl.de/, accessed on 2 June 2022) was used to visualize the population structure in the context of available metadata.

4.6. Identification of Antimicrobial Resistance Genes and Islands and of Genetic Regions Flanking Carbapenemase Genes

Services provided by the Center of Genomic Epidemiology (https://cge.cbs.dtu.dk/services/, accessed on 10 February 2022) were used to identify resistance genes (ResFinder v4.1). To investigate the genetic region surrounding CP genes, contigs that contained such genes were first compared with public sequences by BLASTn analysis, using Geneious v. R8.1 (Biomatters Ldt, Auckland, New Zealand). The same contigs and all remaining contigs of an isolate were then mapped to the identified reference sequences using the “Map to reference tool” of Geneious v R8.1. In silico mapped contigs were ordered and oriented relative to one another with bridging PCRs and amplicon sequencing by using different primer pairs designed in the present study or previously published (Supplementary Materials Table S3) [62,63]. Insertion sequences (IS) were detected using ISfinder (http://www-is.biotoul.fr, France, accessed on 10 February 2022). A. baumannii resistance (AbaR) islands were initially identified based on the presence of antimicrobial resistance genes in the genome sequences by using ResFinder. PCR mapping was performed to confirm the genetic arrangements of AbaR in case the genome contigs did not comprise the entire island structure. Primers and expected amplicon sequences of mapping PCRs are given in Supplementary Materials Table S5).

4.7. Southern Blot Hybridization Analysis

The genomic location of CP genes was verified by S1-Nuclease digestion of whole-cell DNA, pulsed-field gel electrophoresis (PFGE) and Southern hybridisation with DNA probes consisting of a 642-bp internal PCR fragment specific for the blaOXA-23 gene (primers OXA23-FWD/OXA23-REV), a 456-bp internal PCR fragment specific for the blaOXA-58 gene (primers OXA58-FWD/OXA58-REV) [13,54] (Supplementary Materials Table S4).

4.8. Transformation of Plasmids Carrying Carbapenemase Genes

For transformation of blaOXA-23 and blaOXA-58 encoding plasmids of A. baumannii isolates electrocompetent cells of A. baumannii strain ATCC 17978 were prepared as described previously [62]. Plasmid DNA of donor strains was isolated using the QIAprep Mini-spin kit (Qiagen GmbH, Hilden, Germany). Electroporation was carried out with the Eppendorf Eporator® (Eppendorf, Hamburg, Germany) using the adjustments of 25 µF, 200 Ω and 2.5 kV. The transformants were selected on Mueller–Hinton agar plates containing 4 µg/mL meropenem [62]. The identity of transformants was tested by PCR targeting the CP genes, by PFGE of ApaI-restricted genomes and by phenotypic susceptibility testing using the VITEK 2 system (bioMérieux, Nuertingen, Germany; AST cards GN38 and GN238).

5. Conclusions

Here, we describe the occurrence and molecular characteristics of OXA-23- and OXA-58-producing A. baumannii isolates obtained from clinical samples of companion animals belonging to the international successful clonal lineages ST1 and ST25. Together with the findings that blaOXA-23 was integrated into the transposon structures Tn2006 and Tn2008 as well as blaOXA-58 embedded in a previously described genetic context, our data suggest a transfer of acquired carbapenemases and multidrug-resistant A. baumannii lineages between humans and companion animals. These findings warrant further investigations on the epidemiology and underlying genetic mechanisms of carbapenem resistance in Acinetobacter spp. strains from animals and on the processes that may favour the emergence and spread of such bacteria in veterinary settings.

Supplementary Materials

The following are available online at https://www.mdpi.com/article/10.3390/antibiotics11081045/s1, Figure S1: Neighbor Joining Tree of 28 Acinetobacter baumannii isolates based on 2.390 genes included in the cgMLST scheme of Ridom SeqSphere+. Table S1: MICs (mg/L) of A. baumannii recipient strain ATCC 17978 after transformation of blaOXA plasmids from A. baumannii. Table S2: Antimicrobial resistance genes and antimicrobial susceptibility of carbapenemase-producing A. baumannii isolates from cats and dogs. Table S3: Primers used for the determination of genetic regions flanking the blaOXA-23 and blaOXA-58 genes in Acinetobacter baumannii. Table S4: Oligonucleotide primers used for single and multiplex PCRs to detect β-lactamase genes in Acinetobacter baumannii isolates. Table S5: Oligonucleotide primers used for PCR mapping of A. baumannii resistance island AbaR3.

Author Contributions

Conceptualization, L.J., C.E. and T.S.; methodology, C.E. and L.J.; software, C.E., L.J. and T.S.; validation, C.E. and L.J.; formal analysis, C.E., L.J. and I.S.; investigation, C.E. and L.J.; resources, C.E., T.S. and I.S.; data curation, C.E. and L.J.; writing—original draft preparation, L.J. and C.E.; writing—review and editing, C.E., I.S., T.S. and L.J.; visualization, C.E. and L.J.; supervision, C.E.; project administration, C.E.; funding acquisition, C.E. and L.J. All authors have read and agreed to the published version of the manuscript.

Funding

L.J. was financially supported by the “Akademie für Tiergesundheit e.V.” The APC was funded by the Open Access Publication Funds of the Justus Liebig University Giessen, granted by the German Research Foundation.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

All relevant data are provided in the paper and its Supplements. Raw sequence reads of 42 A. baumannii genomes are provided under NCBI Bioproject ID PRJNA857701. Further raw data can be made available on reasonable request.

Acknowledgments

We would like to thank Ursula Leidner for her excellent technical support and our colleagues from the microbiological diagnostic laboratory of the Institute of Hygiene and Infectious Diseases, JLU Giessen, for collecting Acinetobacter baumannii isolates from veterinary clinical samples.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Higgins, P.G.; Dammhayn, C.; Hackel, M.; Seifert, H. Global spread of carbapenem-resistant Acinetobacter baumannii. J. Antimicrob. Chemother. 2010, 65, 233–238. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Adams-Haduch, J.M.; Onuoha, E.O.; Bogdanovich, T.; Tian, G.B.; Marschall, J.; Urban, C.M.; Spellberg, B.J.; Rhee, D.; Halstead, D.C.; Pasculle, A.W.; et al. Molecular epidemiology of carbapenem-nonsusceptible Acinetobacter baumannii in the United States. J. Clin. Microbiol. 2011, 49, 3849–3854. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. Sahl, J.W.; Del Franco, M.; Pournaras, S.; Colman, R.E.; Karah, N.; Dijkshoorn, L.; Zarrilli, R. Phylogenetic and genomic diversity in isolates from the globally distributed Acinetobacter baumannii ST25 lineage. Sci. Rep. 2015, 5, 15188. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Belmonte, O.; Pailhories, H.; Kempf, M.; Gaultier, M.P.; Lemarie, C.; Ramont, C.; Joly-Guillou, M.L.; Eveillard, M. High prevalence of closely-related Acinetobacter baumannii in pets according to a multicentre study in veterinary clinics, Reunion Island. Vet. Microbiol. 2014, 170, 446–450. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Goettig, S.; Gruber, T.M.; Higgins, P.G.; Wachsmuth, M.; Seifert, H.; Kempf, V.A. Detection of pan drug-resistant Acinetobacter baumannii in Germany. J. Antimicrob. Chemother. 2014, 69, 2578–2579. [Google Scholar] [CrossRef]
  6. Tacconelli, E.; Carrara, E.; Savoldi, A.; Harbarth, S.; Mendelson, M.; Monnet, D.L.; Pulcini, C.; Kahlmeter, G.; Kluytmans, J.; Carmeli, Y.; et al. Discovery, research, and development of new antibiotics: The WHO priority list of antibiotic-resistant bacteria and tuberculosis. Lancet Infect. Dis. 2018, 18, 318–327. [Google Scholar] [CrossRef]
  7. Nguyen, M.; Joshi, S.G. Carbapenem resistance in Acinetobacter baumannii, and their importance in hospital-acquired infections: A scientific review. J. Appl. Microbiol. 2021, 131, 2715–2738. [Google Scholar] [CrossRef] [PubMed]
  8. Ewers, C.; Klotz, P.; Leidner, U.; Stamm, I.; Prenger-Berninghoff, E.; Gottig, S.; Semmler, T.; Scheufen, S. OXA-23 and ISAba1-OXA-66 class D beta-lactamases in Acinetobacter baumannii isolates from companion animals. Int. J. Antimicrob. Agents 2017, 49, 37–44. [Google Scholar] [CrossRef]
  9. Ewers, C.; Klotz, P.; Scheufen, S.; Leidner, U.; Gottig, S.; Semmler, T. Genome sequence of OXA-23 producing Acinetobacter baumannii IHIT7853, a carbapenem-resistant strain from a cat belonging to international clone IC1. Gut Pathog. 2016, 8, 37. [Google Scholar] [CrossRef] [Green Version]
  10. Endimiani, A.; Hujer, K.M.; Hujer, A.M.; Bertschy, I.; Rossano, A.; Koch, C.; Gerber, V.; Francey, T.; Bonomo, R.A.; Perreten, V. Acinetobacter baumannii isolates from pets and horses in Switzerland: Molecular characterization and clinical data. J. Antimicrob. Chemother. 2011, 66, 2248–2254. [Google Scholar] [CrossRef] [PubMed]
  11. Pomba, C.; Endimiani, A.; Rossano, A.; Saial, D.; Couto, N.; Perreten, V. First report of OXA-23-mediated carbapenem resistance in sequence type 2 multidrug-resistant Acinetobacter baumannii associated with urinary tract infection in a cat. Antimicrob. Agents Chemother. 2014, 58, 1267–1268. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  12. Herivaux, A.; Pailhories, H.; Quinqueneau, C.; Lemarie, C.; Joly-Guillou, M.L.; Ruvoen, N.; Eveillard, M.; Kempf, M. First report of carbapenemase-producing Acinetobacter baumannii carriage in pets from the community in France. Int. J. Antimicrob. Agents 2016, 48, 220–221. [Google Scholar] [CrossRef] [PubMed]
  13. Jacobmeyer, L.; Stamm, I.; Semmler, T.; Ewers, C. First report of NDM-1 in an Acinetobacter baumannii strain from a pet animal in Europe. J. Glob. Antimicrob. Resist. 2021, 26, 128–129. [Google Scholar] [CrossRef] [PubMed]
  14. Zhang, W.J.; Lu, Z.; Schwarz, S.; Zhang, R.M.; Wang, X.M.; Si, W.; Yu, S.; Chen, L.; Liu, S. Complete sequence of the blaNDM-1-carrying plasmid pNDM-AB from Acinetobacter baumannii of food animal origin. J. Antimicrob. Chemother. 2013, 68, 1681–1682. [Google Scholar] [CrossRef] [Green Version]
  15. Al Bayssari, C.; Dabboussi, F.; Hamze, M.; Rolain, J.M. Emergence of carbapenemase-producing Pseudomonas aeruginosa and Acinetobacter baumannii in livestock animals in Lebanon. J. Antimicrob. Chemother. 2015, 70, 950–951. [Google Scholar] [CrossRef] [Green Version]
  16. Pailhories, H.; Belmonte, O.; Kempf, M.; Lemarie, C.; Cuziat, J.; Quinqueneau, C.; Ramont, C.; Joly-Guillou, M.L.; Eveillard, M. Diversity of Acinetobacter baumannii strains isolated in humans, companion animals, and the environment in Reunion Island: An exploratory study. Int. J. Infect. Dis. 2015, 37, 64–69. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  17. van Spijk, J.N.; Schmitt, S.; Furst, A.E.; Schoster, A. A retrospective analysis of antimicrobial resistance in bacterial pathogens in an equine hospital (2012–2015). Schweiz. Arch. Tierheilkd. 2016, 158, 433–442. [Google Scholar] [CrossRef] [Green Version]
  18. Linz, B.; Mukhtar, N.; Shabbir, M.Z.; Rivera, I.; Ivanov, Y.V.; Tahir, Z.; Yaqub, T.; Harvill, E.T. Virulent Epidemic Pneumonia in Sheep Caused by the Human Pathogen Acinetobacter baumannii. Front. Microbiol. 2018, 9, 2616. [Google Scholar] [CrossRef]
  19. Lupo, A.; Chatre, P.; Ponsin, C.; Saras, E.; Boulouis, H.J.; Keck, N.; Haenni, M.; Madec, J.Y. Clonal Spread of Acinetobacter baumannii Sequence Type 25 Carrying blaOXA-23 in Companion Animals in France. Antimicrob. Agents Chemother. 2017, 61, e01881-16. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  20. Post, V.; White, P.A.; Hall, R.M. Evolution of AbaR-type genomic resistance islands in multiply antibiotic-resistant Acinetobacter baumannii. J. Antimicrob. Chemother. 2010, 65, 1162–1170. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  21. Hamidian, M.; Hall, R.M. The AbaR antibiotic resistance islands found in Acinetobacter baumannii global clone 1-Structure, origin and evolution. Drug Resist. Updates Rev. Comment. Antimicrob. Anticancer Chemother. 2018, 41, 26–39. [Google Scholar] [CrossRef] [PubMed]
  22. Hamidian, M.; Hawkey, J.; Wick, R.; Holt, K.E.; Hall, R.M. Evolution of a clade of Acinetobacter baumannii global clone 1, lineage 1 via acquisition of carbapenem- and aminoglycoside-resistance genes and dispersion of ISAba1. Microb. Genom. 2019, 5, e000242. [Google Scholar] [CrossRef] [PubMed]
  23. Adams, M.D.; Chan, E.R.; Molyneaux, N.D.; Bonomo, R.A. Genomewide analysis of divergence of antibiotic resistance determinants in closely related isolates of Acinetobacter baumannii. Antimicrob. Agents Chemother. 2010, 54, 3569–3577. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  24. Wong, D.; Nielsen, T.B.; Bonomo, R.A.; Pantapalangkoor, P.; Luna, B.; Spellberg, B. Clinical and Pathophysiological Overview of Acinetobacter Infections: A Century of Challenges. Clin. Microbiol. Rev. 2017, 30, 409–447. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Gentilini, F.; Turba, M.E.; Pasquali, F.; Mion, D.; Romagnoli, N.; Zambon, E.; Terni, D.; Peirano, G.; Pitout, J.D.D.; Parisi, A.; et al. Hospitalized Pets as a Source of Carbapenem-Resistance. Front. Microbiol. 2018, 9, 2872. [Google Scholar] [CrossRef]
  26. Chanchaithong, P.; Prapasarakul, N.; Sirisopit Mehl, N.; Suanpairintr, N.; Teankum, K.; Collaud, A.; Endimiani, A.; Perreten, V. Extensively drug-resistant community-acquired Acinetobacter baumannii sequence type 2 in a dog with urinary tract infection in Thailand. J. Glob. Antimicrob. Resist. 2018, 13, 33–34. [Google Scholar] [CrossRef] [PubMed]
  27. Misic, D.; Asanin, J.; Spergser, J.; Szostak, M.; Loncaric, I. OXA-72-Mediated Carbapenem Resistance in Sequence Type 1 Multidrug (Colistin)-Resistant Acinetobacter baumannii Associated with Urinary Tract Infection in a Dog from Serbia. Antimicrob. Agents Chemother. 2018, 62, e00219-18. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  28. Taj, Z.; Rasool, M.H.; Almatroudi, A.; Saqalein, M.; Khurshid, M. Extensively Drug-resistant Acinetobacter baumannii Belonging to International Clone II from A Pet Cat with Urinary Tract Infection; The First Report from Pakistan. Pol. J. Microbiol. 2020, 69, 231–234. [Google Scholar] [CrossRef]
  29. Zordan, S.; Prenger-Berninghoff, E.; Weiss, R.; van der Reijden, T.; van den Broek, P.; Baljer, G.; Dijkshoorn, L. Multidrug-resistant Acinetobacter baumannii in veterinary clinics, Germany. Emerg. Infect. Dis. 2011, 17, 1751–1754. [Google Scholar] [CrossRef] [PubMed]
  30. Klotz, P.; Jacobmeyer, L.; Stamm, I.; Leidner, U.; Pfeifer, Y.; Semmler, T.; Prenger-Berninghoff, E.; Ewers, C. Carbapenem-resistant Acinetobacter baumannii ST294 harbouring the OXA-72 carbapenemase from a captive grey parrot. J. Antimicrob. Chemother. 2018, 73, 1098–1100. [Google Scholar] [CrossRef] [PubMed]
  31. Pailhories, H.; Kempf, M.; Belmonte, O.; Joly-Guillou, M.L.; Eveillard, M. First case of OXA-24-producing Acinetobacter baumannii in cattle from Reunion Island, France. Int. J. Antimicrob. Agents 2016, 48, 763–764. [Google Scholar] [CrossRef] [PubMed]
  32. Hrenovic, J.; Seruga Music, M.; Durn, G.; Dekic, S.; Hunjak, B.; Kisic, I. Carbapenem-Resistant Acinetobacter baumannii Recovered from Swine Manure. Microb. Drug Resist. 2019, 25, 725–730. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Kohlenberg, A.; Brummer, S.; Higgins, P.G.; Sohr, D.; Piening, B.C.; de Grahl, C.; Halle, E.; Ruden, H.; Seifert, H. Outbreak of carbapenem-resistant Acinetobacter baumannii carrying the carbapenemase OXA-23 in a German university medical centre. J. Med. Microbiol. 2009, 58, 1499–1507. [Google Scholar] [CrossRef] [PubMed]
  34. Principe, L.; Piazza, A.; Giani, T.; Bracco, S.; Caltagirone, M.S.; Arena, F.; Nucleo, E.; Tammaro, F.; Rossolini, G.M.; Pagani, L.; et al. Epidemic diffusion of OXA-23-producing Acinetobacter baumannii isolates in Italy: Results of the first cross-sectional countrywide survey. J. Clin. Microbiol. 2014, 52, 3004–3010. [Google Scholar] [CrossRef] [Green Version]
  35. Hsu, L.Y.; Apisarnthanarak, A.; Khan, E.; Suwantarat, N.; Ghafur, A.; Tambyah, P.A. Carbapenem-Resistant Acinetobacter baumannii and Enterobacteriaceae in South and Southeast Asia. Clin. Microbiol. Rev. 2017, 30, 1–22. [Google Scholar] [CrossRef] [Green Version]
  36. Lukovic, B.; Gajic, I.; Dimkic, I.; Kekic, D.; Zornic, S.; Pozder, T.; Radisavljevic, S.; Opavski, N.; Kojic, M.; Ranin, L. The first nationwide multicenter study of Acinetobacter baumannii recovered in Serbia: Emergence of OXA-72, OXA-23 and NDM-1-producing isolates. Antimicrob. Resist. Infect. Control 2020, 9, 101. [Google Scholar] [CrossRef] [PubMed]
  37. Mugnier, P.D.; Poirel, L.; Naas, T.; Nordmann, P. Worldwide dissemination of the blaOXA-23 carbapenemase gene of Acinetobacter baumannii. Emerg. Infect. Dis. 2010, 16, 35–40. [Google Scholar] [CrossRef]
  38. Pfennigwerth, N.; Schauer, J. Bericht des Nationalen Referenzzentrums für gramnegative Krankenhauserreger-Zeitruam 1. Januar 2021 bis 31. Dezember 2021. Epidemiol. Bull. 2022, 19, 3–9. [Google Scholar] [CrossRef]
  39. Jeannot, K.; Diancourt, L.; Vaux, S.; Thouverez, M.; Ribeiro, A.; Coignard, B.; Courvalin, P.; Brisse, S. Molecular Epidemiology of Carbapenem Non-Susceptible Acinetobacter baumannii in France. PLoS ONE 2014, 9, e115452. [Google Scholar] [CrossRef]
  40. Giannouli, M.; Antunes, L.C.; Marchetti, V.; Triassi, M.; Visca, P.; Zarrilli, R. Virulence-related traits of epidemic Acinetobacter baumannii strains belonging to the international clonal lineages I-III and to the emerging genotypes ST25 and ST78. BMC Infect. Dis. 2013, 13, 282. [Google Scholar] [CrossRef] [Green Version]
  41. da Silva, K.E.; Maciel, W.G.; Croda, J.; Cayo, R.; Ramos, A.C.; de Sales, R.O.; Kurihara, M.N.L.; Vasconcelos, N.G.; Gales, A.C.; Simionatto, S. A high mortality rate associated with multidrug-resistant Acinetobacter baumannii ST79 and ST25 carrying OXA-23 in a Brazilian intensive care unit. PLoS ONE 2018, 13, e0209367. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  42. Puentener-Simmen, S.; Zurfluh, K.; Schmitt, S.; Stephan, R.; Nuesch-Inderbinen, M. Phenotypic and Genotypic Characterization of Clinical Isolates Belonging to the Acinetobacter calcoaceticus-Acinetobacter baumannii (ACB) Complex Isolated From Animals Treated at a Veterinary Hospital in Switzerland. Front. Vet. Sci. 2019, 6, 17. [Google Scholar] [CrossRef]
  43. Schleicher, X.; Higgins, P.G.; Wisplinghoff, H.; Korber-Irrgang, B.; Kresken, M.; Seifert, H. Molecular epidemiology of Acinetobacter baumannii and Acinetobacter nosocomialis in Germany over a 5-year period (2005–2009). Clin. Microbiol. Infect. Off. Publ. Eur. Soc. Clin. Microbiol. Infect. Dis. 2013, 19, 737–742. [Google Scholar] [CrossRef] [Green Version]
  44. Bi, D.; Zheng, J.; Xie, R.; Zhu, Y.; Wei, R.; Ou, H.Y.; Wei, Q.; Qin, H. Comparative Analysis of AbaR-Type Genomic Islands Reveals Distinct Patterns of Genetic Features in Elements with Different Backbones. mSphere 2020, 5, e00349-20. [Google Scholar] [CrossRef] [PubMed]
  45. Krizova, L.; Dijkshoorn, L.; Nemec, A. Diversity and evolution of AbaR genomic resistance islands in Acinetobacter baumannii strains of European clone I. Antimicrob. Agents Chemother. 2011, 55, 3201–3206. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Godeux, A.S.; Svedholm, E.; Lupo, A.; Haenni, M.; Venner, S.; Laaberki, M.H.; Charpentier, X. Scarless Removal of Large Resistance Island AbaR Results in Antibiotic Susceptibility and Increased Natural Transformability in Acinetobacter baumannii. Antimicrob. Agents Chemother. 2020, 64, e00951-20. [Google Scholar] [CrossRef]
  47. Evans, B.A.; Hamouda, A.; Towner, K.J.; Amyes, S.G. Novel genetic context of multiple blaOXA-58 genes in Acinetobacter genospecies 3. J. Antimicrob. Chemother. 2010, 65, 1586–1588. [Google Scholar] [CrossRef] [PubMed]
  48. Ayibieke, A.; Kobayashi, A.; Suzuki, M.; Sato, W.; Mahazu, S.; Prah, I.; Mizoguchi, M.; Moriya, K.; Hayashi, T.; Suzuki, T.; et al. Prevalence and Characterization of Carbapenem-Hydrolyzing Class D beta-Lactamase-Producing Acinetobacter Isolates From Ghana. Front. Microbiol. 2020, 11, 587398. [Google Scholar] [CrossRef] [PubMed]
  49. Castro-Jaimes, S.; Salgado-Camargo, A.D.; Grana-Miraglia, L.; Lozano, L.; Bocanegra-Ibarias, P.; Volkow-Fernandez, P.; Silva-Sanchez, J.; Castillo-Ramirez, S.; Cevallos, M.A. Complete Genome Sequence of a Multidrug-Resistant Acinetobacter baumannii Isolate Obtained from a Mexican Hospital (Sequence Type 422). Genome Announc. 2016, 4, e00583-16. [Google Scholar] [CrossRef] [Green Version]
  50. Fu, Y.; Jiang, J.; Zhou, H.; Jiang, Y.; Fu, Y.; Yu, Y.; Zhou, J. Characterization of a novel plasmid type and various genetic contexts of blaOXA-58 in Acinetobacter spp. from multiple cities in China. PLoS ONE 2014, 9, e84680. [Google Scholar] [CrossRef] [Green Version]
  51. Zarrilli, R.; Vitale, D.; Di Popolo, A.; Bagattini, M.; Daoud, Z.; Khan, A.U.; Afif, C.; Triassi, M. A plasmid-borne blaOXA-58 gene confers imipenem resistance to Acinetobacter baumannii isolates from a Lebanese hospital. Antimicrob. Agents Chemother. 2008, 52, 4115–4120. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Higgins, P.G.; Lehmann, M.; Wisplinghoff, H.; Seifert, H. gyrB multiplex PCR to differentiate between Acinetobacter calcoaceticus and Acinetobacter genomic species 3. J. Clin. Microbiol. 2010, 48, 4592–4594. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Groebner, S.; Linke, D.; Schutz, W.; Fladerer, C.; Madlung, J.; Autenrieth, I.B.; Witte, W.; Pfeifer, Y. Emergence of carbapenem-non-susceptible extended-spectrum beta-lactamase-producing Klebsiella pneumoniae isolates at the university hospital of Tubingen, Germany. J. Med. Microbiol. 2009, 58, 912–922. [Google Scholar] [CrossRef] [Green Version]
  54. Higgins, P.G.; Lehmann, M.; Seifert, H. Inclusion of OXA-143 primers in a multiplex polymerase chain reaction (PCR) for genes encoding prevalent OXA carbapenemases in Acinetobacter spp. Int. J. Antimicrob. Agents 2010, 35, 305. [Google Scholar] [CrossRef] [PubMed]
  55. Higgins, P.G.; Zander, E.; Seifert, H. Identification of a novel insertion sequence element associated with carbapenem resistance and the development of fluoroquinolone resistance in Acinetobacter radioresistens. J. Antimicrob. Chemother. 2013, 68, 720–722. [Google Scholar] [CrossRef] [Green Version]
  56. Pfeifer, Y.; Witte, W.; Holfelder, M.; Busch, J.; Nordmann, P.; Poirel, L. NDM-1-producing Escherichia coli in Germany. Antimicrob. Agents Chemother. 2011, 55, 1318–1319. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  57. Poirel, L.; Dortet, L.; Bernabeu, S.; Nordmann, P. Genetic features of blaNDM-1-positive Enterobacteriaceae. Antimicrob. Agents Chemother. 2011, 55, 5403–5407. [Google Scholar] [CrossRef] [Green Version]
  58. Poirel, L.; Walsh, T.R.; Cuvillier, V.; Nordmann, P. Multiplex PCR for detection of acquired carbapenemase genes. Diagn. Microbiol. Infect. Dis. 2011, 70, 119–123. [Google Scholar] [CrossRef]
  59. Hujer, K.M.; Hujer, A.M.; Hulten, E.A.; Bajaksouzian, S.; Adams, J.M.; Donskey, C.J.; Ecker, D.J.; Massire, C.; Eshoo, M.W.; Sampath, R.; et al. Analysis of antibiotic resistance genes in multidrug-resistant Acinetobacter sp. isolates from military and civilian patients treated at the Walter Reed Army Medical Center. Antimicrob. Agents Chemother. 2006, 50, 4114–4123. [Google Scholar] [CrossRef] [Green Version]
  60. Diancourt, L.; Passet, V.; Nemec, A.; Dijkshoorn, L.; Brisse, S. The population structure of Acinetobacter baumannii: Expanding multiresistant clones from an ancestral susceptible genetic pool. PloS ONE 2010, 5, e10034. [Google Scholar] [CrossRef] [Green Version]
  61. Higgins, P.G.; Prior, K.; Harmsen, D.; Seifert, H. Development and evaluation of a core genome multilocus typing scheme for whole-genome sequence-based typing of Acinetobacter baumannii. PLoS ONE 2017, 12, e0179228. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  62. Grimm, V.; Ezaki, S.; Susa, M.; Knabbe, C.; Schmid, R.D.; Bachmann, T.T. Use of DNA microarrays for rapid genotyping of TEM beta-lactamases that confer resistance. J. Clin. Microbiol. 2004, 42, 3766–3774. [Google Scholar] [CrossRef] [Green Version]
  63. Choi, K.H.; Kumar, A.; Schweizer, H.P. A 10-min method for preparation of highly electrocompetent Pseudomonas aeruginosa cells: Application for DNA fragment transfer between chromosomes and plasmid transformation. J. Microbiol. Methods 2006, 64, 391–397. [Google Scholar] [CrossRef]
Antibiotics 11 01045 g001 550
Figure 1. Minimum spanning tree based on cgMLST allelic profiles of 42 CP-producing A. baumannii isolates. (A) Distribution of cgMLST clusters with respect to the source of isolates regarding veterinary clinic and country (Germany = DE, France = F, and Italy = IT); (B) multilocus sequence type and presence of A. baumannii resistance islands. Each circle represents an allelic profile, i.e., complex type (CT), based on sequence analysis of 2390 target genes (pairwise ignoring missing values). The numbers inside the circles represent isolate designation. The numbers on the connecting lines illustrate the number of target genes with different alleles. Clonally related CTs (≤10 allele differences) are grey shaded and numbers of clusters are indicated. The presence of CPs OXA-23 and OXA-58 and their location (P = plasmid; CH = chromosomal) as well as the year of strain isolation are indicated. Patterns of flanking regions of the blaOXA-58 (A–D) and blaOXA-23 regions (a–e) are given above the strain names in part B of the figure.
Figure 1. Minimum spanning tree based on cgMLST allelic profiles of 42 CP-producing A. baumannii isolates. (A) Distribution of cgMLST clusters with respect to the source of isolates regarding veterinary clinic and country (Germany = DE, France = F, and Italy = IT); (B) multilocus sequence type and presence of A. baumannii resistance islands. Each circle represents an allelic profile, i.e., complex type (CT), based on sequence analysis of 2390 target genes (pairwise ignoring missing values). The numbers inside the circles represent isolate designation. The numbers on the connecting lines illustrate the number of target genes with different alleles. Clonally related CTs (≤10 allele differences) are grey shaded and numbers of clusters are indicated. The presence of CPs OXA-23 and OXA-58 and their location (P = plasmid; CH = chromosomal) as well as the year of strain isolation are indicated. Patterns of flanking regions of the blaOXA-58 (A–D) and blaOXA-23 regions (a–e) are given above the strain names in part B of the figure.
Antibiotics 11 01045 g001
Antibiotics 11 01045 g002 550
Figure 2. Maximum-likelihood tree of 42 genomes of carbapenemase-producing A. baumannii isolates. The phylogeny is based on 2,646 orthologous genes and was calculated by RAxML v8. Graphical visualization was achieved by iTOL v5. Colored rings represent (from inner to outer ring the (i) year of isolation, (ii) veterinary clinic, (iii) country of isolation, (iv) multilocus sequence type (Pasteur scheme), (v) international clone, (vi) core genome MLST complex type, (vii) core genome MLST cluster, (viii) OXA-51-like type, (ix) acquired oxacillinase type, and (x) A. baumannni resistance island type. Color of strain numbers indicates the origin of the isolates (green = cats; black = dogs; red = environment).
Figure 2. Maximum-likelihood tree of 42 genomes of carbapenemase-producing A. baumannii isolates. The phylogeny is based on 2,646 orthologous genes and was calculated by RAxML v8. Graphical visualization was achieved by iTOL v5. Colored rings represent (from inner to outer ring the (i) year of isolation, (ii) veterinary clinic, (iii) country of isolation, (iv) multilocus sequence type (Pasteur scheme), (v) international clone, (vi) core genome MLST complex type, (vii) core genome MLST cluster, (viii) OXA-51-like type, (ix) acquired oxacillinase type, and (x) A. baumannni resistance island type. Color of strain numbers indicates the origin of the isolates (green = cats; black = dogs; red = environment).
Antibiotics 11 01045 g002
Antibiotics 11 01045 g003 550
Figure 3. Genetic environment of blaOXA-23 genes in 13 A. baumannii from dogs and cats. (a): Chromosomally located blaOXA-23; (be): blaOXA-23 located on plasmids (partially shown).
Figure 3. Genetic environment of blaOXA-23 genes in 13 A. baumannii from dogs and cats. (a): Chromosomally located blaOXA-23; (be): blaOXA-23 located on plasmids (partially shown).
Antibiotics 11 01045 g003
Antibiotics 11 01045 g004 550
Figure 4. Genetic environment of blaOXA-58 genes in 29 A. baumannii isolates from dogs and cats. (AD) blaOXA-58 located on different plasmids. Extent and orientation of genes and open reading frames (orf) are shown by a horizontal arrow with the gene names below. The blaOXA-58 gene is shown in red, araC1 in yellow, lysE in blue, orfs in grey and other genes in light green. Insertion sequence (IS) elements are represented by a black framed box with the orientation of the transposase genes shown within. Primer pairs used for bridging PCRs are shown as numbers (forward primer in black, reverse primer in red) above the respective genes (Supplementary Materials Table S3). Numbers to the right indicate the size of the genetic regions displayed in the figure and the estimated total size of the plasmids (shown in brackets).
Figure 4. Genetic environment of blaOXA-58 genes in 29 A. baumannii isolates from dogs and cats. (AD) blaOXA-58 located on different plasmids. Extent and orientation of genes and open reading frames (orf) are shown by a horizontal arrow with the gene names below. The blaOXA-58 gene is shown in red, araC1 in yellow, lysE in blue, orfs in grey and other genes in light green. Insertion sequence (IS) elements are represented by a black framed box with the orientation of the transposase genes shown within. Primer pairs used for bridging PCRs are shown as numbers (forward primer in black, reverse primer in red) above the respective genes (Supplementary Materials Table S3). Numbers to the right indicate the size of the genetic regions displayed in the figure and the estimated total size of the plasmids (shown in brackets).
Antibiotics 11 01045 g004
Table
Table 1. Distribution of carbapenemase genes among A. baumannii isolates from animal sources.
Table 1. Distribution of carbapenemase genes among A. baumannii isolates from animal sources.
Sample
Collection *		blaOXA-23blaOXA-58Carbapenemase Positive Ab Isolates
Host/OriginCountryICSTPa
n (%)n (%)(n Isolates)
1 (n = 473
Ab Isolates)		015 (3.2)dog (10), cat (4), air con-ditioner (1)GER (15)IC1 (15)ST1 (15)
2 (n = 30
Ab Isolates)		1314dog/cat (18/10)GER (16), FRA (9), ITA (3)IC1 (13), IC7 (10), IC10 (1), n.a. (4)ST1 (13), ST10 (1), ST25 (10), ST578 (1), ST602 (3)
* Sample collection 1: isolates not pre-selected for susceptibility to carbapenems or any other antibiotic class; sample collection 2: isolates pre-selected for carbapenem non-susceptibility by VITEK 2 (MICs ≥ 2 mg/L for imipenem). Abbreviations: Ab, A. baumannii n, number; n.a., not assigned; GER, Germany; FRA, France; ITA, Italy; STPa, multilocus sequence type according to the Pasteur scheme (https://pubmlst.org/bigsdb?db=pubmlst_abaumannii_pasteur_seqdef; access on 20 May 2022).
Table
Table 2. Characteristics of 42 carbapanemase-producing Acinetobacter baumannii isolates, sorted by STPa.
Table 2. Characteristics of 42 carbapanemase-producing Acinetobacter baumannii isolates, sorted by STPa.
Strain IDHostSourceDate of IsolationCountryICSTPaSTOxcgMLSTVC aAcquired OXA bOXA-Flanking Pattern cOXA-51 Type
CTCluster
IHIT28446CatUrine12/2014DE1123118081158PLB69
IHIT29418DogWound06/2015DE1123118081358PLC69
IHIT29480CatCVC06/2015DE1123118081458PLC69
IHIT29548Env.Air cond.06/2015DE1123118081458PLC69
IHIT29580CatPhlegmon06/2015DE1123118081458PLC69
IHIT29983CatNose 06/2015DE1123118081658PLD69
IHIT29985DogAbdomen03/2015DE1123118081158PLD69
IHIT30000DogNose 05/2015DE1123118081158PLB69
IHIT33215DogUrine11/2015DE1123118081658PLC69
IHIT32291DogWound12/2015DE1123118081158PLB69
IHIT31605DogWound05/2016DE1123118081458PLA69
IHIT31634DogCVC06/2016DE1123118081458PLA69
IHIT31820DogCVC06/2016DE1123118081458PLA69
IHIT32293DogWound01/2016DE11231180811358PLA69
IHIT32295DogUrine 03/2016DE11231180811458PLA69
IHIT32298CatUrine 05/2016DE1123118081158PLA69
IHIT32299CatWound06/2016DE11231180811558PLA69
IHIT33967CatCVC02/2017DE1123118081458PLA69
IHIT34210DogThroat04/2017DE11231180811758PLB69
IHIT34211DogNose04/2017DE112312175S1758PLB69
IHIT34212DogBAL04/2017DE11231180811758PLB69
IHIT34531DogWound05/2017DE1123118081158PLA69
IHIT34607DogAbdomen05/2017DE11231180811758PLB69
IHIT35448CatSkin10/2017DE11231180812058PLB69
IHIT36934DogCVC04/2018DE1123118081458PLA69
IHIT36988DogWound03/2018DE11231180812158PLB69
IHIT37071DogBAL05/2018DE1123118081458PLA69
IHIT38001DogSkin08/2018DE11231180812258PLB69
IHIT29027DogUrine07/2015IT8104472190S223PLb68
IHIT29982DogUrine 07/2015FR72522921843523CHa64
IHIT29995DogEar 07/2015FR7252292185S723CHa64
IHIT30557DogUrine 09/2015FR72522921843523CHa64
IHIT32250CatUrine08/2016FR725229218631023CHa64
IHIT32292DogPaw 01/2016DE725229217741223PLb64
IHIT32297DogTrachea 04/2016DE725229217741223PLb64
IHIT32362DogUrine10/2016DE725229217741623PLb64
IHIT34486CatWound05/2017IT7252292182S1823PLc64
IHIT34502CatUrine05/2017FR7252292181S1923PLd64
IHIT29997DogBAL08/2015FRn.t.5787992189S958PLE65
IHIT29996CatTissue 06/2015FRn.t.60273213682823PLe378
IHIT30558CatUrine 09/2015FRn.t.60273221912823PLe378
IHIT32289CatUrine01/2016FRn.t.602732219121123PLe378
a VC = veterinary clinic; different veterinary clinics are indicated by numbers 1–22. b Location of gene on plasmid (PL) or chromosome (CH) is indicated. c: as illustrated in Figure 3 and Figure 4. Abbreviations: n.t., not typeable; Air cond., Air conditioner; BAL, bronchoalveolar lavage; CVC, central venous catheter; Env, environment; DE, Germany; IT, Italy; FR, France; IC, international clone; STPa, multilocus sequence type according to the Pasteur scheme; STOx, MLST type according to the Oxford scheme. CT, cluster type; S, singleton.
Table
Table 3. Carbapenemase-positive A. baumannii from small animals according to the current literature.
Table 3. Carbapenemase-positive A. baumannii from small animals according to the current literature.
HostCountryYearSourceCP TypeCR Isolates/Total No. of IsolatesLocalization of CPCarbapenem ResistanceICSTPa/OxRef.
CatDE2000Urn.s.1/52n.s.IMPn.s.n.s.[29]
CatDE2000UrOXA-231/1P, Tn2008IMP11/231[9]
Cat, dogCH2005, 2009Ur, Wo, BlISAba1-OXA-512/19CIMP, MER1, 212Ox
& 15Ox		[10]
CatPT2009UrOXA-231/1C, Tn2006IMP, MER22Past[11]
DogDE2011Ur, SkOXA-233/223P, Tn2008IMP, MER1, 810/585[8]
Cat, dogFR2011–2015UrOXA-237/41CIMP, MER725Past[19]
Cat, dogIT2014, 2015FeNDM-15/5C, Tn125IMP, MER22Past[25]
DogFR2015Or, ReOXA-232/4 CR n.s.IMP, MER, DOR725Past[12]
DogRS2016UrOXA-721/1PIMP, MER11Past[27]
DogTH2017UrOXA-231/1Tn2006IMP, MER22Past[26]
Grey ParrotLUX2016ChoOXA-721/1PIMP, MERn.s.294Past[30]
CatPK2020UrOXA-231/1n.s.IMP, MER22Past[28]
CatIT2021UrNDM-11/1Cnone725Past[13]
CP: carbapenemase; CR: carbapenem-resistant; IC: international clone, ST: sequence type. CH: Switzerland, DE: Germany, FR: France, IT: Italy, PK: Pakistan, PT: Portugal, RS: Serbia, TH: Thailand. UR: urine, Wo: wound, Bl: blood, Sk: skin, Fe: feces, Or, oral, Re, rectal, Cho, Choane. P: plasmid, C: chromosome, Tn: Transposon. DOR: doripenem, IMP: imipenem, MER: meropenem, n.s.: not specified, Ref.: reference. Multilocus sequence types are provided according to the schemes used in the original publications (Past = Pasteur; Ox = Oxford).
Table
Table 4. Sample collection of A. baumannii isolates investigated in this study.
Table 4. Sample collection of A. baumannii isolates investigated in this study.
Collection 1 *
(n = 473)		Collection 2 *
(n = 29)
Host/Source
Dog and cat351 **29
Horse460
Rabbit, guinea pig, mouse150
Livestock500
Wild and zoo animals70
Birds30
Environment10
Sample Source
Wound, abscess, fistula1257
Respiratory tract, nasopharynx834
Skin, hair523
Urinary tract4214
Eye, ear251
Faeces, gastrointestinal tract180
Genital tract170
Other clinical sites360
Organ (after necropsy)400
Catheter, implant, tube340
Air conditioner10
Country
Germany47318
France09
Italy02
* Sample collection 1: isolates not pre-selected for susceptibility to carbapenems or any other antibiotic class; sample collection 2: isolates pre-selected for carbapenem non-susceptibility by VITEK 2 (MICs ≥ 2 mg/L for imipenem). ** 34 of 351 isolates were obtained from catheters, implants and tubes.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Jacobmeyer, L.; Semmler, T.; Stamm, I.; Ewers, C. Genomic Analysis of Acinetobacter baumannii Isolates Carrying OXA-23 and OXA-58 Genes from Animals Reveals ST1 and ST25 as Major Clonal Lineages. Antibiotics 2022, 11, 1045. https://doi.org/10.3390/antibiotics11081045

AMA Style

Jacobmeyer L, Semmler T, Stamm I, Ewers C. Genomic Analysis of Acinetobacter baumannii Isolates Carrying OXA-23 and OXA-58 Genes from Animals Reveals ST1 and ST25 as Major Clonal Lineages. Antibiotics. 2022; 11(8):1045. https://doi.org/10.3390/antibiotics11081045

Chicago/Turabian Style

Jacobmeyer, Lisa, Torsten Semmler, Ivonne Stamm, and Christa Ewers. 2022. "Genomic Analysis of Acinetobacter baumannii Isolates Carrying OXA-23 and OXA-58 Genes from Animals Reveals ST1 and ST25 as Major Clonal Lineages" Antibiotics 11, no. 8: 1045. https://doi.org/10.3390/antibiotics11081045

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

Article Metrics

Back to TopTop