In the pIII-mutant strain, the only clear difference in 2D gel analysis was a defective localization for the NG1873 protein. Interestingly, NG1873 has a LysM domain (in position 35–83), with a peptidoglycan binding function [24]. We can speculate that NG1873 is able to reach the outer
membrane only when PIII is acting as a bridge between the outer membrane and the peptidoglycan layer. Further studies will be needed to evaluate the role of this interaction AZD5582 in the context of peptidoglycan and outer membrane architecture and to explore the involvement of other proteins in the NG1873 bacterial localization. The crystal structure of the C – terminal domain of the meningococcal RmpM has been solved [20]. The authors have identified a number of residues which may participate in the non-covalent binding of peptidoglycan. They envisage a model in which the C-terminal domain RmpM interacts with peptidoglycan stabilizing oligomers of porins in the outer membrane.
Since the peptidoglycan of Gram-negative bacteria is located in the periplasmic space, this model in ON-01910 manufacturer combination with the evidence that the N-terminal part of RmpM is associated to the OMP complexes but is too short to cross the membrane [16], would imply a periplasmic localization for the entire protein. However the proposed periplasmic localization is not supported by the evidence that the RmpM/PIII protein is an immuno-dominant antigen with surface-exposed epitopes [1]. In this study we confirmed the surface exposure of PIII by Tolmetin confocal microscopy
analysis. The similarity between PIII and proteins belonging to the OmpA family, known www.selleckchem.com/products/pd-1-pd-l1-inhibitor-2.html to have a role in adhesion in many bacterial species, has driven the investigation on the potential contribution of PIII in adhesion process. Here we provide evidences that gonococcal pIII mediates bacterial adhesion to human epithelial cells, derived from the female and male genital tracts. The choice of a cellular model to study factors and mechanisms involved in the gonococcal pathogenesis is a crucial topic of debate. The data obtained from in vitro models of infection can lead to conclusions not fully relevant with respect to the natural infection. In fact, whereas by the bacterial side, gonococcus undergoes antigenic and phase variation depending on the particular selective pressure induced by cellular contact, by the cellular side, the cell lines can substantially differ from the parental tissue in terms of membrane receptors and functional responses. Although the relevance of any model of infection is not exactly predictable, we limited the possible biases by examining the expression of pili and Opa proteins in the wild-type and pIII-deficient strains used in the infection assays. Moreover, to simulate the female and male infection, we used primary immortalized cell lines obtained from ectocervix, endocervix and urethra.