Frederic G. Sauer scite author profile

Many Gram-negative pathogens assemble architecturally and functionally diverse adhesive pili on their surfaces by the chaperone-usher pathway. Immunoglobulin-like periplasmic chaperones escort pilus subunits to the usher, a large protein complex that facilitates the translocation and assembly of subunits across the outer membrane. The crystal structure of the PapD-PapK chaperone-subunit complex, determined at 2.4 angstrom resolution, reveals that the chaperone functions by donating its G(1) beta strand to complete the immunoglobulin-like fold of the subunit via a mechanism termed donor strand complementation. The structure of the PapD-PapK complex also suggests that during pilus biogenesis, every subunit completes the immunoglobulin-like fold of its neighboring subunit via a mechanism termed donor strand exchange.

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Chaperone Priming of Pilus Subunits Facilitates a Topological Transition that Drives Fiber Formation

Sauer

Pinkner

Waksman

et al. 2002

Cell

249

393

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Periplasmic chaperones direct the assembly of adhesive, multi-subunit pilus fibers that play critical roles in bacterial pathogenesis. Pilus assembly occurs via a donor strand exchange mechanism in which the N-terminal extension of one subunit replaces the chaperone G(1) strand that transiently occupies a groove in the neighboring subunit. Here, we show that the chaperone primes the subunit for assembly by holding the groove in an open, activated conformation. During donor strand exchange, the subunit undergoes a topological transition that triggers the closure of the groove and seals the N-terminal extension in place. It is this topological transition, made possible only by the priming action of the chaperone that drives subunit assembly into the fiber.

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Fiber assembly by the chaperone–usher pathway

Sauer

Remaut

Hultgren

et al. 2004

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

179

155

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Bacterial pathogens utilize the chaperone-usher pathway to assemble extracellular multi-subunit fibers essential for virulence. The periplasmic chaperone facilitates the initial folding of fiber subunits but then traps them in activated folding transition states. Chaperone dissociation releases the folding energy that drives subunit incorporation into the fiber, which grows through a pore formed by the outer-membrane usher.

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PapD-like chaperones provide the missing information for folding of pilin proteins

Barnhart

Pinkner

Soto

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

167

155

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A fundamental question in molecular biology is how proteins fold into domains that can serve as assembly modules for building up large macromolecular structures. The biogenesis of pili on the surface of Gram-negative bacteria requires the orchestration of a complex process that includes protein synthesis, folding via small chaperones, secretion, and assembly. The results presented here support the hypothesis that pilus subunit folding and biogenesis proceed via mechanisms termed donor strand complementation and donor strand exchange. Here we show that the steric information necessary for pilus subunit folding is not contained in one polypeptide sequence. Rather, the missing information is transiently donated by a strand of a small chaperone to allow folding. Providing the missing information for folding, via a 13-amino acid peptide extension to the C-terminal end of a pilus subunit, resulted in the production of a protein that no longer required the chaperone to fold. This mechanism of small periplasmic chaperone function described here deviates from classical hsp60 chaperoneassisted folding.

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Bacterial pili: molecular mechanisms of pathogenesis

et al. 2000

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Frederic G. Sauer

Structural Basis of Chaperone Function and Pilus Biogenesis

Chaperone Priming of Pilus Subunits Facilitates a Topological Transition that Drives Fiber Formation

Fiber assembly by the chaperone–usher pathway

PapD-like chaperones provide the missing information for folding of pilin proteins

Bacterial pili: molecular mechanisms of pathogenesis

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