Abstract
Bacterial pathogens assemble adhesive surface structures termed pili or fimbriae to initiate and sustain infection of host tissues. Uropathogenic Escherichia coli, the primary causative agent of urinary tract infections, expresses type 1 and P pili required for colonization of the bladder and kidney, respectively. These pili are assembled by the conserved chaperone-usher (CU) pathway, in which a periplasmic chaperone works together with an outer membrane (OM) usher protein to build and secrete the pilus fiber. Previously, we found that the small molecule and antiparasitic drug nitazoxanide (NTZ) inhibits CU pathway-mediated pilus biogenesis in E. coli by specifically interfering with proper maturation of the usher protein in the OM. The usher is folded and inserted into the OM by the β-barrel assembly machine (BAM) complex, which in E. coli comprises five proteins, BamA-E. Here, we show that sensitivity of the usher to NTZ is modulated by BAM expression levels and requires the BamB and BamE lipoproteins. Furthermore, a genetic screen for NTZ-resistant bacterial mutants isolated a mutation in the essential BamD lipoprotein. These findings suggest that NTZ selectively interferes with an usher-specific arm of the BAM complex, revealing new details of the usher folding pathway and BAM complex function. Evaluation of a set of NTZ derivatives identified compounds with increased potency and disclosed that NTZ's nitrothiazole ring is critical for usher inhibition. In summary, our findings indicate highly specific effects of NTZ on the usher folding pathway and have uncovered NTZ analogs that specifically decrease usher levels in the OM.
Highlights
Bacterial pathogens assemble adhesive surface structures termed pili or fimbriae to initiate and sustain infection of host tissues
The tissue tropic type 1 (Fim) and P (Pap) pili expressed by uropathogenic Escherichia coli (UPEC) are prototypical examples of pili assembled by the chaperone– usher (CU) pathway
If the barrel assembly machine (BAM) machinery is the direct target of NTZ, we should observe altered NTZ activity in bacterial strains with increased or decreased levels of the BAM complex; increased BAM expression should confer resistance to NTZ, whereas decreased BAM expression should potentiate NTZ activity
Summary
We hypothesized that NTZ interferes with folding of the usher in the OM by altering activity of the BAM complex. The changes in PapC and BamA levels in the different strain backgrounds and NTZ treatment conditions were apparent in Coomassie Blue–stained gels of the OM fractions Taken together, these experiments show an inverse correlation between BAM expression levels and the activity of NTZ; BAM overexpression resulted in increased resistance of the usher to NTZ, and BAM underexpression resulted in increased sensitivity of the usher to NTZ. In contrast to the ⌬bamC mutant, the ⌬bamB and ⌬bamE strains appeared resistant to NTZ, with growth in the presence of the drug no longer causing a decrease in PapC levels (Fig. 3) This suggests that BamB and BamE are required for NTZ activity against the usher. These results implicate BamE in the mechanism of action of NTZ and reveal a previously unknown role for BamE in the usher folding pathway
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