Preclusion of Irreversible Destruction of Dr Adhesin Structures by a High Activation Barrier for the Unfolding Stage of the Fimbrial DraE Subunit

Abstract: Dr fimbriae of uropathogenic Eschericha coli strains are an example of surface-located adhesive structures assembled via the chaperone-usher pathway. These structures are crucial for specific attachment of bacteria to host receptors. Dr fimbriae are linear associates of DraE proteins, the structure of which is determined by a donor strand complementation between the consecutive subunits. The biogenesis of these structures is dependent on a function of the specific periplasmic chaperone and outer membrane usher… Show more

“…The self-complemented construct FimAa, in which antiparallel donor strand insertion is enforced (see below), shows the same nonequilibrium behavior in protein folding (unattained two-state equilibrium) that has so far been observed for all other pilus subunit constructs with artificial C-terminal donor strand. 15,20,[33][34][35] However, FimAa shows by far the highest stability and slowest folding and unfolding kinetics relative to the other self-complemented pilus domains investigated so far. 15,20,[33][34][35] NMR structure of FimAa Based on the stability data above on FimAwt and FimAt, the construct FimAa has alternative folding possibilities in that it can incorporate either its N-or C-terminal donor strand segment into its tertiary structure.…”

“…15,20,[33][34][35] However, FimAa shows by far the highest stability and slowest folding and unfolding kinetics relative to the other self-complemented pilus domains investigated so far. 15,20,[33][34][35] NMR structure of FimAa Based on the stability data above on FimAwt and FimAt, the construct FimAa has alternative folding possibilities in that it can incorporate either its N-or C-terminal donor strand segment into its tertiary structure. To confirm the anticipated incorporation of the C-terminal extension into the donor strand binding groove and to study the structural details of donor strand complementation in the type 1 pilus rod, we solved the solution structure of FimAa with NMR spectroscopy.…”

“…, showing that FimAa is a thermodynamically extremely stable protein with very high activation energy barriers for unfolding and refolding, analogous to previously characterized, selfcomplemented pilus subunits with C-terminal donor strand. 15,20,[33][34][35] The thermal unfolding transition of FimAa shows a very high melting temperature (T m ) of 87.8°C, while the moderately stable FimAwt exhibits a T m of 46.1°C (Fig. 4d).…”

“…4,[13][14][15][16][17][18][19][20]35 The artificial C-terminal extension (G-strand in the solved NMR structure) complements the Ig-fold in a canonical manner (i.e., runs antiparallel with the F-strand). The fold is mainly determined by two β-sheets, the first being composed of strand A (29)(30)(31)(32)(33)(34)(35)(36)(37)(38), the donor strand G (167-182), strand F (146-159) and strand C (67-75), and the second being composed of strands B′ (45)(46)(47)(48)(49), B″ (52-62), E (127-141), D′ (99-105) and D″ (122-124), that are packed against each other in a wound fashion (Fig. 5b and c).…”

Structure, Folding and Stability of FimA, the Main Structural Subunit of Type 1 Pili from Uropathogenic Escherichia coli Strains

“…The self-complemented construct FimAa, in which antiparallel donor strand insertion is enforced (see below), shows the same nonequilibrium behavior in protein folding (unattained two-state equilibrium) that has so far been observed for all other pilus subunit constructs with artificial C-terminal donor strand. 15,20,[33][34][35] However, FimAa shows by far the highest stability and slowest folding and unfolding kinetics relative to the other self-complemented pilus domains investigated so far. 15,20,[33][34][35] NMR structure of FimAa Based on the stability data above on FimAwt and FimAt, the construct FimAa has alternative folding possibilities in that it can incorporate either its N-or C-terminal donor strand segment into its tertiary structure.…”

“…15,20,[33][34][35] However, FimAa shows by far the highest stability and slowest folding and unfolding kinetics relative to the other self-complemented pilus domains investigated so far. 15,20,[33][34][35] NMR structure of FimAa Based on the stability data above on FimAwt and FimAt, the construct FimAa has alternative folding possibilities in that it can incorporate either its N-or C-terminal donor strand segment into its tertiary structure. To confirm the anticipated incorporation of the C-terminal extension into the donor strand binding groove and to study the structural details of donor strand complementation in the type 1 pilus rod, we solved the solution structure of FimAa with NMR spectroscopy.…”

“…, showing that FimAa is a thermodynamically extremely stable protein with very high activation energy barriers for unfolding and refolding, analogous to previously characterized, selfcomplemented pilus subunits with C-terminal donor strand. 15,20,[33][34][35] The thermal unfolding transition of FimAa shows a very high melting temperature (T m ) of 87.8°C, while the moderately stable FimAwt exhibits a T m of 46.1°C (Fig. 4d).…”

“…4,[13][14][15][16][17][18][19][20]35 The artificial C-terminal extension (G-strand in the solved NMR structure) complements the Ig-fold in a canonical manner (i.e., runs antiparallel with the F-strand). The fold is mainly determined by two β-sheets, the first being composed of strand A (29)(30)(31)(32)(33)(34)(35)(36)(37)(38), the donor strand G (167-182), strand F (146-159) and strand C (67-75), and the second being composed of strands B′ (45)(46)(47)(48)(49), B″ (52-62), E (127-141), D′ (99-105) and D″ (122-124), that are packed against each other in a wound fashion (Fig. 5b and c).…”

Structure, Folding and Stability of FimA, the Main Structural Subunit of Type 1 Pili from Uropathogenic Escherichia coli Strains

“…3a). In contrast to subunit:subunit interactions that have been suggested to have dissociation halftimes in the order of billions of years, 22,23 Caf1M-Caf1 binding is highly dynamic and is not exceptionally tight ( Table 1, mutations in the Caf1M chaperone).…”

Large Is Fast, Small Is Tight: Determinants of Speed and Affinity in Subunit Capture by a Periplasmic Chaperone

Protein kinetic stability