Wayne A. Fenton scite author profile

The chaperonin GroEL is a double-ring structure with a central cavity in each ring that provides an environment for the efficient folding of proteins when capped by the co-chaperone GroES in the presence of adenine nucleotides. Productive folding of the substrate rhodanese has been observed in cis ternary complexes, where GroES and polypeptide are bound to the same ring, formed with either ATP, ADP or non-hydrolysable ATP analogues, suggesting that the specific requirement for ATP is confined to an action in the trans ring that evicts GroES and polypeptide from the cis side. We show here, however, that for the folding of malate dehydrogenase and Rubisco there is also an absolute requirement for ATP in the cis ring, as ADP and AMP-PNP are unable to promote folding. We investigated the specific roles of binding and hydrolysis of ATP in the cis and trans rings using mutant forms of GroEL that bind ATP but are defective in its hydrolysis. Binding of ATP and GroES in cis initiated productive folding inside a highly stable GroEL-ATP-GroES complex. To discharge GroES and polypeptide, ATP hydrolysis in the cis ring was required to form a GroEL-ADP-GroES complex with decreased stability, priming the cis complex for release by ATP binding (without hydrolysis) in the trans ring. These observations offer an explanation of why GroEL functions as a double-ring complex.

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Mechanism of GroEL action: Productive release of polypeptide from a sequestered position under groes

Weissman

Hohl

Коваленко

et al. 1995

Cell

416

421

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The chaperonin GroEL is a large, double-ring structure that, together with ATP and the cochaperonin GroES, assists protein folding in vivo. GroES forms an asymmetric complex with GroEL in which a single GroES ring binds one end of the GroEL cylinder. Cross-linking studies reveal that polypeptide binding occurs exclusively to the GroEL ring not occupied by GroES (trans). During the folding reaction, however, released GroES can rebind to the GroEL ring containing polypeptide (cis). The polypeptide is held tightly in a proteolytically protected environment in cis complexes, in the presence of ADP. Single turnover experiments with ornithine transcarbamylase reveal that polypeptide is productively released from the cis but not the trans complex. These observations suggest a two-step mechanism for GroEL-mediated folding. First, GroES displaces the polypeptide from its initial binding sites, sequestering it in the GroEL central cavity. Second, ATP hydrolysis induces release of GroES and productive release of polypeptide.

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Characterization of the Active Intermediate of a GroEL–GroES-Mediated Protein Folding Reaction

Weissman

Rye

Fenton

et al. 1996

Cell

384

375

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Recent studies of GroE-mediated protein folding indicate that substrate proteins are productively released from a cis ternary complex in which the nonnative substrate is sequestered within the GroEL channel underneath GroES. Here, we examine whether protein folding can occur in this space. Stopped-flow fluorescence anisotropy of a pyrene-rhodanese-GroEl complex indicates that addition of GroES and ATP (but not ADP) leads to a rapid change in substrate flexibility at GroEL. Strikingly, when GroES release is blocked by the use of either a nonhydrolyzable ATP analog or a single-ring GroEL mutant, substrates complete folding while remaining associated with chaperonin. We conclude that the cis ternary complex, in the presence of ATP, is the active state intermediate in the GroE-mediated folding reaction: folding is initiated in this state and for some substrates may be completed prior to the timed release of GroES triggered by ATP hydrolysis.

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STRUCTURE AND FUNCTION IN GroEL-MEDIATED PROTEIN FOLDING

Sigler

Rye

et al. 1998

Annu. Rev. Biochem.

536

387

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Recent structural and biochemical investigations have come together to allow a better understanding of the mechanism of chaperonin (GroEL, Hsp60)-mediated protein folding, the final step in the accurate expression of genetic information. Major, asymmetric conformational changes in the GroEL double toroid accompany binding of ATP and the cochaperonin GroES. When a nonnative polypeptide, bound to one of the GroEL rings, is encapsulated by GroES to form a cis ternary complex, these changes drive the polypeptide into the sequestered cavity and initiate its folding. ATP hydrolysis in the cis ring primes release of the products, and ATP binding in the trans ring then disrupts the cis complex. This process allows the polypeptide to achieve its final native state, if folding was completed, or to recycle to another chaperonin molecule, if the folding process did not result in a form committed to the native state. CONTENTS

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Wayne A. Fenton

Distinct actions of cis and trans ATP within the double ring of the chaperonin GroEL

Mechanism of GroEL action: Productive release of polypeptide from a sequestered position under groes

Characterization of the Active Intermediate of a GroEL–GroES-Mediated Protein Folding Reaction

STRUCTURE AND FUNCTION IN GroEL-MEDIATED PROTEIN FOLDING

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