Prefoldin (PFD) is a jellyfish-shaped molecular chaperone that has been proposed to play a general role in de novo protein folding in archaea and is known to assist the biogenesis of actins, tubulins, and potentially other proteins in eukaryotes. Using point mutants, chimeras, and intradomain swap variants, we show that the six coiledcoil tentacles of archaeal PFD act in concert to bind and stabilize nonnative proteins near the opening of the cavity they form. Importantly, the interaction between chaperone and substrate depends on the mostly buried interhelical hydrophobic residues of the coiled coils. We also show by electron microscopy that the tentacles can undergo an en bloc movement to accommodate an unfolded substrate. Our data reveal how archael PFD uses its unique architecture and intrinsic coiled-coil properties to interact with nonnative polypeptides.C oiled coils consist of two or more parallel or antiparallel amphipathic ␣-helices that twist around one another to form supercoils (1). The primary sequences of the helices display a heptad repeat (abcdefg), where apolar residues are found preferentially in the first (a) and fourth (d) positions. Although the knobs-into-holes packing of the hydrophobic residues is the predominant stabilizing force for a coiled coil, inter-and intrahelical ionic interactions can act to further stabilize or destabilize its supersecondary structure (1). Coiled coils are found in several molecular chaperones, a diverse family of proteins whose collective cellular role is to ensure the quality control (e.g., folding, assembly, and transport) of nonnative proteins (2, 3). Archaeal prefoldin (PFD) is a chaperone that contains six canonical antiparallel coiled coils whose N-and C-terminal helices project outward from a double -barrel oligomerization domain; the overall shape of the hexameric protein complex, assembled from two PFD␣ and four PFD subunits (␣ 2  4 ), resembles a jellyfish with six tentacles (4). In solution, its tentacles are likely to be fully solvated and independently mobile (4). A lower-resolution electron microscope image of recombinant human PFD, which consists of six different proteins (two ␣ class and four  class subunits), reveals that it possesses the same overall structure (5).Like other chaperones, archaeal PFD can selectively interact with and stabilize nonnative (unfolded) polypeptides that expose hydrophobic surfaces in vitro, helping to prevent their aggregation (4, 6, 7). Preliminary studies have shown that deletion of the distal coiled-coil regions in either the ␣ or  subunit abrogates chaperone activity in vitro, implying that PFD grasps its substrates in a multivalent manner (4). Similarly, the eukaryotic PFD-actin complex recently visualized by EM shows that nonnative actin, one of its substrates, makes multiple contacts with the distal regions of the tentacles (5).In the crowded cellular environment, eukaryotic PFD is likely to transiently stabilize ribosome-bound nascent polypeptides (8) before shuttling them to a chaperonin (an ATP-depe...
