Showing papers by "Scott J. Hultgren published in 1996"

Molecular basis of two subfamilies of immunoglobulin-like chaperones.

Abstract: The initial encounter of a microbial pathogen with the host often involves the recognition of host receptors by different kinds of bacterial adhesive organelles called pili, fimbriae, fibrillae or afimbrial adhesins. The development of over 26 of these architecturally diverse adhesive organelles in various Gram-negative pathogens depends on periplasmic chaperones that are comprised of two immunoglobulin-like domains. All of the chaperones possess a highly conserved sheet in domain 1 and a conserved interdomain hydrogen-bonding network. Chaperone-subunit complex formation depends on the anchoring of the carboxylate group of the subunit into the conserved crevice of the chaperone cleft and the subsequent positioning of the COOH terminus of subunits along the exposed edge of the conserved sheet of the chaperone. We discovered that the chaperones can be divided into two distinct subfamilies based upon conserved structural differences that occur in the conserved sheet. Interestingly, a subdivision of the chaperones based upon whether they assemble rod-like pili or non-pilus organelles that have an atypical morphology defines the same two subgroups. The molecular dissection of the two chaperone subfamilies and the adhesive fibers that they assemble has advanced our understanding of the development of virulence-associated organelles in pathogenic bacteria.

Development of Pilus Organelle Subassemblies in vitro Depends on Chaperone Uncapping of a Beta Zipper

Abstract: The major subassemblies of virulence-associated P pili, the pilus rod (comprised of PapA) and tip fibrillum (comprised of PapE), were reconstituted from purified chaperone-subunit complexes in vitro. Subunits are held in assembly-competent conformations in chaperone-subunit complexes prior to their assembly into mature pili. The PapD chaperone binds, in part, to a conserved motif present at the C terminus of the subunits via a beta zippering interaction. Amino acid residues in this conserved motif were also found to be essential for subunit–subunit interactions necessary for the formation of pili, thus revealing a molecular mechanism whereby the PapD chaperone may prevent premature subunit–subunit interactions in the periplasm. Uncapping of the chaperone-protected C terminus of PapA and PapE was mimicked in vitro by freeze–thaw techniques and resulted in the formation of pilus rods and tip fibrillae, respectively. A mutation in the leading edge of the beta zipper of PapA produces pilus rods with an altered helical symmetry and azimuthal disorder. This change in the number of subunits per turn of the helix most likely reflects involvement of the leading edge of the beta zipper in forming a right-handed helical cylinder. Organelle development is a fundamental process in all living cells, and these studies shed new light on how immunoglobulin-like chaperones govern the formation of virulence-associated organelles in pathogenic bacteria.

Haemophilus influenzae pili are composite structures assembled via the HifB chaperone

Abstract: Haemophilus influenzae is a Gram-negative bacterium that represents a common cause of human disease. Disease due to this organism begins with colonization of the upper respiratory mucosa, a process facilitated by adhesive fibers called pili. In the present study, we investigated the structure and assembly of H. influenzae pili. Examination of pili by electron microscopy using quick-freeze, deep-etch and immunogold techniques revealed the presence of two distinct subassemblies, including a flexible two-stranded helical rod comprised of HifA and a short, thin, distal tip structure containing HifD. Genetic and biochemical studies demonstrated that the biogenesis of H. influenzae pili is dependent on a periplasmic chaperone called HifB, which belongs to the PapD family of immunoglobulin-like chaperones. HifB bound directly to HifA and HifD, forming HifB-HifA and HifB-HifD complexes, which were purified from periplasmic extracts by ion-exchange chromatography. Continued investigation of the biogenesis of H. influenzae pili should provide general insights into organelle development and may suggest novel strategies for disease prevention.