Achromobacter xylosoxidans: An Emerging Pathogen Carrying Different Elements Involved in Horizontal Genetic Transfer

In the last few years, numerous cases of multidrug-resistant Achromobacter xylosoxidans infections have been documented in immunocompromised and cystic fibrosis patients. To gain insights into the molecular mechanisms and mobile elements related to multidrug resistance in this bacterium, we studied 24 non-epidemiological A. xylosoxidans clinical isolates from Argentina. Specific primers for plasmids, transposons, insertion sequences, bla ampC, intI1, and intI2 genes were used in PCR reactions. The obtained results showed the presence of wide host range IncP plasmids in ten isolates and a high dispersion of class 1 integrons (n = 10) and class 2 integrons (n = 3). Four arrays in the variable region (vr) of class 1 integrons were identified carrying different gene cassettes as the aminoglycoside resistance aac(6′)-Ib and aadA1, the trimethoprim resistance dfrA1 and dfrA16, and the β-lactamase bla OXA-2. In only one of the class 2 integrons, a vr was amplified that includes sat2-aadA1. The bla ampC gene was found in all isolates, confirming its ubiquitous nature. Our results show that A. xylosoxidans clinical isolates contain a rich variety of genetic elements commonly associated with resistance genes and their dissemination. This supports the hypothesis that A. xylosoxidans is becoming a reservoir of horizontal genetic transfer elements commonly involved in spreading antibiotic resistance. Electronic supplementary material The online version of this article (doi:10.1007/s00284-012-0213-5) contains supplementary material, which is available to authorized users.


Introduction
Achromobacter spp. is a rarely nosocomial and community pathogen, being Achromobacter xylosoxidans the most frequent species among Achromobacter spp. isolates [6,8,18]. Many reports of A. xylosoxidans infections are documented in immunocompromised and cystic fibrosis (CF) patients, where its pathogenic role has not yet been properly clarified [7,8]. In Argentina, the relative frequency of A. xylosoxidans among the uncommon non-glucose-fermenting gram-negative bacilli infections has been increasing reaching 66 % of total non-glucose-fermenting gram-negative bacilli infection isolates [18].
Although clinical A. xylosoxidans isolates usually show multiple drug resistance, the relative low attention paid to this pathogen resulted in poor understanding of their resistance mechanisms. Little is known about molecular mechanisms and transferable elements contributing to the acquisition and dissemination of antibiotic resistance determinants in A. xylosoxidans clinical isolates.
The aim of this study was to explore the occurrence of mobile elements related to antibiotic-resistance determinants among a collection of 24 non-epidemiological-related clinical isolates of A. xylosoxidans recovered in Argentina from six centers.

Bacterial Strains
Twenty-four non-epidemiological-related clinical isolates of A. xylosoxidans recovered in Argentina from six centers were used (Table 1). All isolates were identified using standard biochemical tests and API 20NE (Biomeriux), and the species level was confirmed by sequencing the 16S rRNA gene [19]. Clonal relationships analysis, using the macrorestriction technique, showed the presence of 15 different clones among the isolates included in the study (data not shown). The antibiotic susceptibility was performed by agar dilution method following the general recommendations of the Clinical and Laboratory Standards Institute (CLSI) [4].

Results and Discussion
The 24 A. xylosoxidans isolates studied exhibited the typical multiresistance profile previously described for this species, being the third and fourth-generation cephalosporins, fluoroquinolones, and aminoglycosides not active against Achromobacter spp. [18]. All isolates were susceptible to tazobactam, imipenem, and meropenem (Table  S1 in Supplementary material). Among the PCR reactions performed for the selected transferable elements, positive results were obtained in ten isolates (42 %) for the IncP plasmids, a wide host range and self-transmissible plasmid important in the dissemination of resistant genes around the world [11] (Table 1). Negative results were obtained for the other Inc groups searched (IncW, IncA/C, IncN, IncFII). Sequence analysis of the amplification products showed 99 % of identity in 200-bp length with the replication gene trfA (AN GU186864). The GC% of the trfA replication gene of IncP plasmid is 60.5 %, which is very similar to the GC% (67 %) of A. xylosoxidans. We also noticed in this study that most isolates containing IncP plasmids corresponded to nosocomial isolates (n = 9). In only one CF patient isolate (Ax72), an IncP plasmid was identified.
In addition, a high dispersion of class 1 integrons was found (42 %). Most of the positive isolates corresponded to nosocomial patient samples (n = 9), being only one positive isolate from a CF patient sample (Ax72). To  characterize the vr of class 1 integrons, PCR cartography was carried out as previously described [12]. Four vr were identified, being all the arrays different to the previous arrays reported in this species (Table 1; Fig. 1). Among the gene cassettes identified in the class 1 integron context, aminoglycosides-resistance genes aac(6 0 )-Ib and aadA1, the trimethoprim-resistance genes dfrA1 and dfrA16, and the b-lactamase bla OXA-2 were found. The obtained MICs in the positive integron isolates to several antibiotics are exposed in Table 3. No clear contribution of gene cassettes could be established in the studied isolates. Only in the strain Ax44, harboring the gene cassette dfrA16, a contribution to the MIC to TMS (256 lg/ml) could be suggested, as it corresponded to the highest value among isolates under scrutiny (Table S1 in Supplementary material). Furthermore, three nosocomial isolates apart from harboring class 1 integrons also have class 2 integrons (Ax79, Ax126, and Ax169) ( Table 1). To identify the gene cassette content found in the variable region of class 2 integrons, PCR cartography was performed using different combinations of primers [5,14,16]. Only positive amplifications were obtained for the Ax126 showing the presence of the array intI2-sat2-aadA1. The occurrence of the Tn7 transposition gene was also searched, showing that the tnsE gene was present in all isolates, being the tnsB also present in the Ax126 isolate. The rest of the genes gave negative results. To the best of our knowledge, this is the first description of class 2 integrons in Achromobacter spp. [16]. No association of integrons with IS26 and IS440 was found in this study.
In relation with the bla ampC gene previously described in this species [17], it was found in all isolates, confirming its ubiquitous nature.
The exposed results showed that almost all isolates (17/24) included in this study have the capability of carrying ISs, R plasmids, and integrons, associated to horizontal gene transfer usually found in gram-negative clinical isolates. Moreover, the similar GC% between the trfA replicon of the IncP plasmid and the A. xylosoxidans genome reinforces the argument that A. xylosoxidans could be considered as a reservoir of transferable elements. It is likely that its intrinsic antibiotic multidrug resistant profile that ensures its selection under antibiotic pressure, along with its ability to survive in fluids and in the environment [18], makes A. xylosoxidans a reservoir of transferable elements that could contribute to the dissemination and acquisition of antimicrobial resistance mechanisms within the nosocomial environment.