Two distinct eukaryotic cell types were used to examine adherence, and potentially invasion and intracellular replication, of a selected number of A. baumannii isolates. Detroit 562 human nasopharyngeal cells were chosen to mimic adherence/carriage of
A. baumannii strains in the nasal pharyngeal cavity. The second cell line employed was A549 Autophagy assay human type 2 pneumocytes, that has previously been used to mimic adherence to the human lung and as such represents a potential model for pneumonia caused by A. baumannii (March et al., 2010). The A. baumannii isolates selected for cell adherence studies displayed differential abiotic surface adherence and motility characteristics. These studies also included a number of previously studied and published strains. Similar to our data on abiotic adherence, there were significant differences between Acinetobacter strains in their capacity to adhere to eukaryotic cells (Fig. 2). For example, differences of more than 17-fold were seen between ATCC 19606 and WM99c when investigating binding to A549 cells. A more than 60-fold difference in adherence to Detroit 562 cells was observed between strains D1279779 and WM97a. Examination of the ability of differing clonal groups to adhere to the eukaryotic cells revealed no clonal specific trends. In this study, a significant difference between binding to A549 and Detroit 562 cells was observed for A. baumannii strains D1279779 and ATCC 17978 (P < 0.05,
two-tailed Student’s t-test). Both of these A. baumannii strains showed a higher level of adherence to lung epithelial cells compared to nasopharyngeal
p38 inhibitors clinical trials cells. All other strains examined have similar levels of binding to the two distinct epithelial cell lines. The complete genome of a number of A. baumannii strains has been sequenced and six of these fully sequenced strains were included in this study. Genomic Metformin supplier comparison may prove useful for the identification of the molecular mechanisms involved in the characteristics studied herein. Although limited information is available on the molecular mechanism, type IV pili may play a role in A. baumannii motility, based on for example, the correlation between the presence of fimbriae and motility in A. calcoaceticus (Henrichsen & Blom, 1975) and transcriptional and phenotypic analysis of A. baumannii under iron limiting conditions (Eijkelkamp et al., 2011). Moreover, a role for type IV pili in motility of other nonflagellated gamma-proteobacteria, such as Xylella fastidiosa, has been reported (Meng et al., 2005; De La Fuente et al., 2007). Comparative genomic analysis using Mauve (Darling et al., 2004) showed that the genes encoding different subunits or regulators as part of the type IV pili were present in all fully sequenced A. baumannii isolates included (data not shown). Most genes encoding type IV pili showed a high level of conservation, except for pilA, the gene encoding the pilin subunit PilA. In P.