Effect of chaperone-adhesin complex on plug release by the PapC usher

Nitazoxanide inhibits pili assembly by targeting BamB to synergize with polymyxin B against drug-resistant Escherichia coli

Gram-negative bacteria rely on pili assembly for pathogenicity, with the chaperone-usher (CU) pathway regulating pilus biogenesis. Nitazoxanide (NTZ) inhibits CU pathway-mediated P pilus biogenesis by specifically interfering with the proper folding of the outer membrane protein (OMP) usher, primarily mediated by the β-barrel assembly machinery (BAM) complex. In this study, we identified the BAM complex components BamB and the BamA POTRA2 domain as key binding targets for NTZ. Molecular dynamics simulations and Bio-Layer Interferometry revealed that BamB residues S61 and R195 are critical for NTZ binding. NTZ activated the Cpx two-component system and induced inner membrane perturbations, which resulted from the accumulation of misfolded P pilus subunits. Upregulation of the ibpAB gene, which protects the bacteria against NTZ-induced oxidative stress, was also observed. Importantly, NTZ combined with polymyxin B enhanced the latter's antibacterial activity against both susceptible and MCR-positive E. coli strains. This enhancement was achieved through NTZ-induced increases in inner membrane permeability, oxidative stress, and inhibition of efflux pump activity and biofilm formation. This study provides new insights into the antimicrobial mechanism of NTZ and highlights its potential as an antibiotic adjuvant by targeting BamB to inhibit the CU pathway, restoring the efficacy of polymyxin B against multidrug-resistant bacteria.

The Small Regulatory Antisense RNA PilR Affects Pilus Formation and Cell Motility by Negatively Regulating pilA11 in Synechocystis sp. PCC 6803

Pili are found on the surface of many bacteria and play important roles in cell motility, pathogenesis, biofilm formation, and sensing and reacting to environmental changes. Cell motility in the model cyanobacterium Synechocystis sp. PCC 6803 relies on expression of the putative pilA9-pilA10-pilA11-slr2018 operon. In this study, we identified the antisense RNA PilR encoded in the noncoding strand of the prepilin-encoding gene pilA11. Analysis of overexpressor [PilR(+)] and suppressor [PilR(-)] mutant strains revealed that PilR is a direct negative regulator of PilA11 protein. Although overexpression of PilR did not affect cell growth, it greatly reduced levels of pilA11 mRNA and protein and decreased both the thickness and number of pili, resulting in limited cell motility and small, distinct colonies. Suppression of PilR had the opposite effect. A hypothetical model on the regulation of pilA9-pilA10-pilA11-slr2018 operon expression by PilR was proposed. These results add a layer of complexity to the mechanisms controlling pilA11 gene expression and cell motility, and provide novel insights into how sRNA and the intergenic region secondary structures can work together to discoordinatly regulate target gene in an operon in cyanobacterium.

Structural and Molecular Biology of a Protein-Polymerizing Nanomachine for Pilus Biogenesis

Bacteria produce protein polymers on their surface called pili or fimbriae that serve either as attachment devices or as conduits for secreted substrates. This review will focus on the chaperone-usher pathway of pilus biogenesis, a widespread assembly line for pilus production at the surface of Gram-negative bacteria and the archetypical protein-polymerizing nanomachine. Comparison with other nanomachines polymerizing other types of biological units, such as nucleotides during DNA replication, provides some unifying principles as to how multidomain proteins assemble biological polymers.