A Gradient of ATP Affinities Generates an Asymmetric Power Stroke Driving the Chaperonin TRIC/CCT Folding Cycle

Stefanie Reissmann; Lukasz A. Joachimiak; Bryan Chen; Anne S. Meyer; Anthony Nguyen; Judith Frydman

doi:10.1016/j.celrep.2012.08.036

A Gradient of ATP Affinities Generates an Asymmetric Power Stroke Driving the Chaperonin TRIC/CCT Folding Cycle

Stefanie Reissmann, Lukasz A. Joachimiak, Bryan Chen, Anne S. Meyer, Anthony Nguyen, Judith Frydman

Research output: Contribution to journal › Article › peer-review

77 Scopus citations

Abstract

The eukaryotic chaperonin TRiC/CCT uses ATP cycling to fold many essential proteins that other chaperones cannot fold. This 1 MDa hetero-oligomer consists of two identical stacked rings assembled from eight paralogous subunits, each containing a conserved ATP-binding domain. Here, we report a dramatic asymmetry in the ATP utilization cycle of this ring-shaped chaperonin, despite its apparently symmetric architecture. Only four of the eight different subunits bind ATP at physiological concentrations. ATP binding and hydrolysis by the low-affinity subunits is fully dispensable for TRiC function in vivo. The conserved nucleotide-binding hierarchy among TRiC subunits is evolutionarily modulated through differential nucleoside contacts. Strikingly, high- and low-affinity subunits are spatially segregated within two contiguous hemispheres in the ring, generating an asymmetric power stroke that drives the folding cycle. This unusual mode of ATP utilization likely serves to orchestrate a directional mechanism underlying TRiC/CCT@s unique ability to fold complex eukaryotic proteins

Original language	English (US)
Pages (from-to)	866-877
Number of pages	12
Journal	Cell Reports
Volume	2
Issue number	4
DOIs	https://doi.org/10.1016/j.celrep.2012.08.036
State	Published - Oct 25 2012
Externally published	Yes

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology(all)

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10.1016/j.celrep.2012.08.036

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@article{ce67e99472534a05b3d6bc427ef7b274,

title = "A Gradient of ATP Affinities Generates an Asymmetric Power Stroke Driving the Chaperonin TRIC/CCT Folding Cycle",

abstract = "The eukaryotic chaperonin TRiC/CCT uses ATP cycling to fold many essential proteins that other chaperones cannot fold. This 1 MDa hetero-oligomer consists of two identical stacked rings assembled from eight paralogous subunits, each containing a conserved ATP-binding domain. Here, we report a dramatic asymmetry in the ATP utilization cycle of this ring-shaped chaperonin, despite its apparently symmetric architecture. Only four of the eight different subunits bind ATP at physiological concentrations. ATP binding and hydrolysis by the low-affinity subunits is fully dispensable for TRiC function in vivo. The conserved nucleotide-binding hierarchy among TRiC subunits is evolutionarily modulated through differential nucleoside contacts. Strikingly, high- and low-affinity subunits are spatially segregated within two contiguous hemispheres in the ring, generating an asymmetric power stroke that drives the folding cycle. This unusual mode of ATP utilization likely serves to orchestrate a directional mechanism underlying TRiC/CCT@s unique ability to fold complex eukaryotic proteins",

author = "Stefanie Reissmann and Joachimiak, {Lukasz A.} and Bryan Chen and Meyer, {Anne S.} and Anthony Nguyen and Judith Frydman",

note = "Funding Information: We thank Raul Andino, Dan Gestaut, and Martin Thanbichler for critical readings of the manuscript, and Andreas Bracher for useful discussions. This work was supported by grants from the National Institutes of Health to J.F. L.A.J. is funded by a National Institutes of Health Fellowship. S.R. was funded by the Studienstiftung des Deutschen Volkes. S.R. and A.S.M. purified proteins. S.R. performed the crosslink-HPLC experiments, ATPase assays, and in vivo pulse-chase experiments. A.S.M. performed the stoichiometry experiments. L.A.J. performed the homology model building, conservation score calculations, docking calculations, mutant design, and structural analysis. A.N. and B.C. generated the yeast cctx mutants. B.C. performed the yeast genetic experiments and the native-PAGE experiments to analyze ATP-induced TRiC closure. J.F. designed and interpreted experiments. S.R., L.A.J., and J.F. wrote the manuscript. All authors contributed to preparation of the manuscript. ",

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T1 - A Gradient of ATP Affinities Generates an Asymmetric Power Stroke Driving the Chaperonin TRIC/CCT Folding Cycle

AU - Reissmann, Stefanie

AU - Joachimiak, Lukasz A.

AU - Chen, Bryan

AU - Meyer, Anne S.

AU - Nguyen, Anthony

AU - Frydman, Judith

N1 - Funding Information: We thank Raul Andino, Dan Gestaut, and Martin Thanbichler for critical readings of the manuscript, and Andreas Bracher for useful discussions. This work was supported by grants from the National Institutes of Health to J.F. L.A.J. is funded by a National Institutes of Health Fellowship. S.R. was funded by the Studienstiftung des Deutschen Volkes. S.R. and A.S.M. purified proteins. S.R. performed the crosslink-HPLC experiments, ATPase assays, and in vivo pulse-chase experiments. A.S.M. performed the stoichiometry experiments. L.A.J. performed the homology model building, conservation score calculations, docking calculations, mutant design, and structural analysis. A.N. and B.C. generated the yeast cctx mutants. B.C. performed the yeast genetic experiments and the native-PAGE experiments to analyze ATP-induced TRiC closure. J.F. designed and interpreted experiments. S.R., L.A.J., and J.F. wrote the manuscript. All authors contributed to preparation of the manuscript.

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N2 - The eukaryotic chaperonin TRiC/CCT uses ATP cycling to fold many essential proteins that other chaperones cannot fold. This 1 MDa hetero-oligomer consists of two identical stacked rings assembled from eight paralogous subunits, each containing a conserved ATP-binding domain. Here, we report a dramatic asymmetry in the ATP utilization cycle of this ring-shaped chaperonin, despite its apparently symmetric architecture. Only four of the eight different subunits bind ATP at physiological concentrations. ATP binding and hydrolysis by the low-affinity subunits is fully dispensable for TRiC function in vivo. The conserved nucleotide-binding hierarchy among TRiC subunits is evolutionarily modulated through differential nucleoside contacts. Strikingly, high- and low-affinity subunits are spatially segregated within two contiguous hemispheres in the ring, generating an asymmetric power stroke that drives the folding cycle. This unusual mode of ATP utilization likely serves to orchestrate a directional mechanism underlying TRiC/CCT@s unique ability to fold complex eukaryotic proteins

AB - The eukaryotic chaperonin TRiC/CCT uses ATP cycling to fold many essential proteins that other chaperones cannot fold. This 1 MDa hetero-oligomer consists of two identical stacked rings assembled from eight paralogous subunits, each containing a conserved ATP-binding domain. Here, we report a dramatic asymmetry in the ATP utilization cycle of this ring-shaped chaperonin, despite its apparently symmetric architecture. Only four of the eight different subunits bind ATP at physiological concentrations. ATP binding and hydrolysis by the low-affinity subunits is fully dispensable for TRiC function in vivo. The conserved nucleotide-binding hierarchy among TRiC subunits is evolutionarily modulated through differential nucleoside contacts. Strikingly, high- and low-affinity subunits are spatially segregated within two contiguous hemispheres in the ring, generating an asymmetric power stroke that drives the folding cycle. This unusual mode of ATP utilization likely serves to orchestrate a directional mechanism underlying TRiC/CCT@s unique ability to fold complex eukaryotic proteins

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ER -

A Gradient of ATP Affinities Generates an Asymmetric Power Stroke Driving the Chaperonin TRIC/CCT Folding Cycle

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