Characterisation of an early South African multiply antibiotic-resistant global clone 1 Acinetobacter baumannii isolate.

OBJECTIVES: The aim of this study was to characterise an early clinical multiply antibiotic resistant Acinetobacter baumannii global clone 1 (GC1) isolate from Africa. METHODS: The draft genome sequence was determined using short-read (Illumina MiSeq) sequence data and compared to other early GC1 isolates. Resistance genes and other features were identified using various bioinformatics tools. Plasmids were visualised. RESULTS: LUH6050, recovered in South Africa between January 1997 and January 1999, is ST1IP:ST231Ox:KL1:OCL1. Several antibiotic resistance genes (aacC1, aadA2, aphA1, catA1, sul1, and tetA(A)) reside in AbaR32. LUH6050 also includes the plasmid pRAY*, carrying the aadB gentamicin and tobramycin resistance gene, and a 29.9 kb plasmid, pLUH6050-3, carrying the msrE-mphE (macrolide resistance) and dfrA44 (trimethoprim resistance) genes and a small cryptic Rep_1 plasmid. Plasmid pLUH6050-3, a cointegrate of pA1-1 (R3-T1; RepAci1) with an R3-T33 type plasmid encoding a different Rep_3 family Rep, carries 15 pdif sites and 13 dif modules, including those that carry the mrsE-mphE and dfrA44 genes and three that include toxin-antitoxin gene pairs. The closest relative of pLUH6050-3 found in GenBank was from an unrelated 2013 Tanzanian A. baumannii isolate. The chromosome has an AbaR0-type region in comM and includes no ISAba1 copies. Similar features were found in most other sequenced lineage 1 GC1 isolates recovered prior to 2000. CONCLUSION: LUH6050 represents an early form of the GC1 lineage 1, supplementing limited information about early isolates and isolates from Africa. These data contribute to the understanding of the emergence, evolution, and dissemination of the A. baumannii GC1 clonal complex.

Insertion sequences related to ISAjo2 target pdif and dif sites and belong to a new IS family, the IS1202 family.

Several insertion sequences (IS) found in various Acinetobacter species exhibit target specificity. They are found, in the same orientation, 5 bp from the XerC binding site of the pdif sites associated with dif modules in Acinetobacter plasmids, and searches revealed they are also found near chromosomal dif sites of Acinetobacter species. These IS are 1.5 kb long, bounded by 24-26 bp imperfect terminal inverted repeats (TIRs) and encode a large transposase of 441-457 aa. They generate 5 bp target site duplications (TSDs). Structural predictions of the ISAjo2 transposase, TnpAjo2, modelled on TnsB of Tn7 revealed two N-terminal HTH domains followed by an RNaseH fold (DDE domain), a ß barrel and a C-terminal domain. Similar to Tn7, the outer IS ends are 5'-TGT and ACA-3', and an additional Tnp binding site, corresponding to the internal portion of the IR, is found near each end. However, the Acinetobacter IS do not encode further proteins related to those required by Tn7 for targeted transposition, and the transposase may interact directly with XerC bound to a dif-like site. We propose that these IS, currently in the IS1202 group in the not characterized yet (NCY) category in ISFinder, are part of a distinct IS1202 family. Other IS listed as in the IS1202 group encode transposases related to TnpAjo2 (25-56 % amino acid identity) and have similar TIRs but fall into three groups based on the TSD length (3-5, >15, 0 bp). Those with 3-5 bp TSDs may also target dif-like sites but targets were not found for the other groups.

The tet39 Determinant and the msrE-mphE Genes in Acinetobacter Plasmids Are Each Part of Discrete Modules Flanked by Inversely Oriented pdif (XerC-XerD) Sites.

The tet39 tetracycline resistance determinant and the macrolide resistance genes msrE and mphE were found in an 18.2-kb plasmid, pS30-1, recovered from a global clone 2 (GC2) Acinetobacter baumannii isolate from Singapore, that conferred resistance to tetracycline and erythromycin. pS30-1 also contains mobA and mobC genes encoding MOBQ family proteins, but attempts to mobilize pS30-1 utilizing a coresident conjugative repAci6 plasmid were unsuccessful. Eight pdif sites, consisting of inversely oriented binding sites for the XerC and XerD recombinases separated by 6 bp, were detected in pS30-1. The tet39 determinant and the msrE-mphE gene pair are each surrounded by two pdif sites in inverse orientation. Identical regions in different contexts and many previously unnoticed pdif sites were found in a number of different plasmids in GenBank, showing that the tet39 and msrE-mphE dif modules are mobile. A putative toxin/antitoxin system, a gene encoding a serine recombinase, and open reading frames of unknown function were also part of dif modules in pS30-1. In general, modules with internal XerC or XerD sites alternate. Two copies of ISAjo2-1 (94% identical to ISAjo2) in pS30-1 were inserted 5 bp from a XerC site, and this appears to be the preferred insertion site for this insertion sequence (IS) group. Apparently, Acinetobacter plasmids exploit the Acinetobacter XerC-XerD recombinases to mobilize DNA units containing resistance and other genes, via an uncharacterized mechanism. The tet39 and msrE-mphE dif modules add to the oxa24 module and the oxa58 module redefined here, bringing the total of resistance gene-containing dif modules in Acinetobacter plasmids to four.