Basis of Substrate Binding by the Chaperonin GroEL

Wang, Zhong Lin; Feng, Hwa‐Ping; Landry, Samuel J.; Maxwell, Jennifer P.; Gierasch, Lila M.

doi:10.1021/bi991070p

Cited by 64 publications

(45 citation statements)

References 72 publications

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“…6 and 7). For substrates that are more tightly bound, however, presumably via a greater amount of exposed hydrophobic surface (8), a subsequent step of ATP/GroES binding to the substrate-bound ring ejects the substrate off the cavity wall into a now GroES-encapsulated and hydrophilic so-called cis cavity, where folding commences (9)(10)(11)(12). The reaction proceeds for Ϸ10 seconds before ATP hydrolysis in the cis ring followed by trans ring ATP binding ejects the cis ligands, including substrate polypeptide whether folded or not (11,13,14).…”

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confidence: 99%

Perturbed ATPase activity and not “close confinement” of substrate in the cis cavity affects rates of folding by tail-multiplied GroEL

Farr

Fenton

Horwich

2007

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

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Folding of substrate proteins inside the sequestered and hydrophilic GroEL-GroES cis cavity favors production of the native state. Recent studies of GroEL molecules containing volume-occupying multiplications of the flexible C-terminal tail segments have been interpreted to indicate that close confinement of substrate proteins in the cavity optimizes the rate of folding: the rate of folding of a larger protein, Rubisco (51 kDa), was compromised by multiplication, whereas that of a smaller protein, rhodanese (33 kDa), was increased by tail duplication. Here, we report that this latter effect does not extend to the subunit of malate dehydrogenase (MDH), also 33 kDa. In addition, single-ring versions of tailduplicated and triplicated molecules, comprising stable cis complexes, did not produce any acceleration of folding of rhodanese or MDH, nor did they show significant retardation of the folding of Rubisco. Tail quadruplication produced major reduction in recovery of native protein with both systems, the result of strongly reduced binding of all three substrates. When steady-state ATPase of the tail-multiplied double-ring GroELs was examined, it scaled directly with the number of tail segments, with more than double the normal ATPase rate upon tail triplication. As previously observed, disturbance of ATPase activity of the cycling double-ring system, and thus of ''dwell time'' for the folding protein in the cis cavity, produces effects on folding rates. We conclude that, within the limits of the Ϸ10% decrease of cavity volume produced by tail triplication, there does not appear to be an effect of ''close confinement'' on folding in the cis cavity.chaperonin ͉ protein folding ͉ single ring

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confidence: 99%

Perturbed ATPase activity and not “close confinement” of substrate in the cis cavity affects rates of folding by tail-multiplied GroEL

Farr

Fenton

Horwich

2007

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

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“…Results from peptide studies using transferred nuclear Overhauser effects (15)(16)(17) or crystallography (18) have established that various conformations can bind to GroEL; the common feature that mediates binding is exposure of a patch of hydrophobic surface (complementary to the binding surfaces on the apical domains of GroEL). Atomic structures (18,19) implicated two helices on the inner binding surfaces of the apical domains in polypeptide binding, and mutagenesis results (20) also suggest that hydrophobic residues on an underlying extended segment are crucial for substrate binding.…”

Section: The Trapped Folding Intermediatementioning

confidence: 99%

First glimpses of a chaperonin-bound folding intermediate

Swain

Gierasch

2005

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

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“…Additionally, the GroEL apical domain residues implicated in substrate binding are largely hydrophobic (14). Finally, previous studies on the basis of substrate interaction with GroEL using short model peptides have concluded that the most important determinant of substrate binding is the presentation of a cluster of hydrophobic residues (15)(16)(17).…”

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confidence: 95%

“…The only evidence addressing the chiral specificity of GroEL/ ES comes from a study that qualitatively demonstrated binding of a short D-peptide to GroEL (16). However, this NMR study required peptide concentrations that greatly exceed physiologic levels and did not localize the interaction to the substratebinding region of GroEL.…”

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confidence: 99%

Synthesis and folding of a mirror-image enzyme reveals ambidextrous chaperone activity

Weinstock

Jacobsen

Kay

2014

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

125

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Mirror-image proteins (composed of D-amino acids) are promising therapeutic agents and drug discovery tools, but as synthesis of larger D-proteins becomes feasible, a major anticipated challenge is the folding of these proteins into their active conformations. In vivo, many large and/or complex proteins require chaperones like GroEL/ES to prevent misfolding and produce functional protein.The ability of chaperones to fold D-proteins is unknown. Here we examine the ability of GroEL/ES to fold a synthetic D-protein. We report the total chemical synthesis of a 312-residue GroEL/ESdependent protein, DapA, in both L-and D-chiralities, the longest fully synthetic proteins yet reported. Impressively, GroEL/ES folds both L-and D-DapA. This work extends the limits of chemical protein synthesis, reveals ambidextrous GroEL/ES folding activity, and provides a valuable tool to fold D-proteins for drug development and mirror-image synthetic biology applications.

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Basis of Substrate Binding by the Chaperonin GroEL

Cited by 64 publications

References 72 publications

Perturbed ATPase activity and not “close confinement” of substrate in the cis cavity affects rates of folding by tail-multiplied GroEL

Perturbed ATPase activity and not “close confinement” of substrate in the cis cavity affects rates of folding by tail-multiplied GroEL

First glimpses of a chaperonin-bound folding intermediate

Synthesis and folding of a mirror-image enzyme reveals ambidextrous chaperone activity

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