resulted in seven clusters (data not shown). The nine blood isolates were distributed among six clusters. No correlation was observed between the clusters and the presence of any OXA-like gene type, biofilm forming ability or meropenem resistance. Though carbapenemase resistance among Acinetobacters spp. in India has been reported (9, 10), the genes involved and their association with ISAba1 have not been elucidated.
In this study, multiplex PCR was used to characterize the species and examine the prevalence of OXA-type genes. The blaOXA-51-like gene is intrinsic to A. baumannii and is chromosomal (22). The G+C content of OXA-51 closely matches that of the A. baumannii genome (39–40%) and has been used for the identification of this species. OXA-23 Doramapimod is encoded either chromosomally or in plasmids and has been found to have a global distribution, accounting for carbapenemase resistance in most clinical isolates of A. baumannii LY2157299 concentration (1). The results of Mendes et al. (23) and our study corroborate the above findings (Table 2). blaOXA-24-like gene, which has been reported for isolates from Europe, the USA (1) and Thailand, Indonesia and Taiwan in the Asia Pacific region (23) has not previously been recorded in Indian isolates. However, our results
for samples from India reveal the presence of this gene in both A. baumannii (22.9%) and other Acinetobacter spp. (64.3%), suggesting the possible acquisition of this gene from other sources. blaOXA-58-like genes have been reported from Europe, North and South America, and West Asia (1, 7).The low prevalence in India evident in our study is in agreement with the report of Mendes et al. (23). Resistance to meropenem according to MIC assay was 39.6% in A. baumannii and 14.2% in other Acinetobacter spp. (Table 2) which is higher than the reported resistance (25%) for Asia (1) and could be a reflection of the increasing use of meropenem in the clinical setting. The insertion sequence ISAba1 observed in 33.3% of the isolates presents sequence similarity to that reported previously
(18). The presence of ISAba1 upstream of blaOXA-23 gene is in accordance with earlier reports (1, 18) wherein the insertion sequence was generally associated with blaOXA-23 gene. Further, the presence of ISAba1 in A. baumannii only in our isolates (Fig. 2) confirms the earlier Montelukast Sodium finding that this insertion sequence is unique to this species (1). The presence of ISAba1 in the promoter region has been thought to cause over-expression of genes (17). However, in our study, we identified some isolates that were resistant to meropenem, but did not have ISAba1 upstream of OXA genes, suggesting there may be other mechanisms of over-expression of these genes in such strains. Recent findings have suggested that over-expression of the naturally occurring blaOXA-51 gene is mediated by the novel insertion sequence ISAba9 (24) and the blaOXA-23 gene to ISAba4 (25), providing evidence for other mechanisms of resistance.