Shiou‐Ru Tzeng scite author profile

How the interplay between protein structure and internal dynamics regulates protein function is poorly understood. Often, ligand binding, post-translational modifications and mutations modify protein activity in a manner that is not possible to rationalize solely on the basis of structural data. It is likely that changes in the internal motions of proteins have a major role in regulating protein activity, but the nature of their contributions remains elusive, especially in quantitative terms. Here we show that changes in conformational entropy can determine whether protein-ligand interactions will occur, even among protein complexes with identical binding interfaces. We have used NMR spectroscopy to determine the changes in structure and internal dynamics that are elicited by the binding of DNA to several variants of the catabolite activator protein (CAP) that differentially populate the inactive and active DNA-binding domain states. We found that the CAP variants have markedly different affinities for DNA, despite the CAP−DNA-binding interfaces being essentially identical in the various complexes. Combined with thermodynamic data, the results show that conformational entropy changes can inhibit the binding of CAP variants that are structurally poised for optimal DNA binding or can stimulate the binding activity of CAP variants that only transiently populate the DNA-binding-domain active state. Collectively, the data show how changes in fast internal dynamics (conformational entropy) and slow internal dynamics (energetically excited conformational states) can regulate binding activity in a way that cannot be predicted on the basis of the protein's ground-state structure.

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Dynamic activation of an allosteric regulatory protein

Tzeng

Kalodimos

2009

Nature

360

351

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Allosteric regulation is used as a very efficient mechanism to control protein activity in most biological processes, including signal transduction, metabolism, catalysis and gene regulation. Allosteric proteins can exist in several conformational states with distinct binding or enzymatic activity. Effectors are considered to function in a purely structural manner by selectively stabilizing a specific conformational state, thereby regulating protein activity. Here we show that allosteric proteins can be regulated predominantly by changes in their structural dynamics. We have used NMR spectroscopy and isothermal titration calorimetry to characterize cyclic AMP (cAMP) binding to the catabolite activator protein (CAP), a transcriptional activator that has been a prototype for understanding effector-mediated allosteric control of protein activity. cAMP switches CAP from the 'off' state (inactive), which binds DNA weakly and non-specifically, to the 'on' state (active), which binds DNA strongly and specifically. In contrast, cAMP binding to a single CAP mutant, CAP-S62F, fails to elicit the active conformation; yet, cAMP binding to CAP-S62F strongly activates the protein for DNA binding. NMR and thermodynamic analyses show that despite the fact that CAP-S62F-cAMP(2) adopts the inactive conformation, its strong binding to DNA is driven by a large conformational entropy originating in enhanced protein motions induced by DNA binding. The results provide strong evidence that changes in protein motions may activate allosteric proteins that are otherwise structurally inactive.

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Structural basis for cAMP-mediated allosteric control of the catabolite activator protein

Popovych

Tzeng

Tonelli

et al. 2009

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

203

281

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Protein dynamics and allostery: an NMR view

Tzeng¹,

Kalodimos²

2011

Current Opinion in Structural Biology

235

227

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Structure of the ubiquitin‐binding zinc finger domain of human DNA Y‐polymerase η

et al. 2007

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The ubiquitin-binding zinc finger (UBZ) domain of human DNA Y-family polymerase (pol) g is important in the recruitment of the polymerase to the stalled replication machinery in translesion synthesis. Here, we report the solution structure of the pol g UBZ domain and its interaction with ubiquitin. We show that the UBZ domain adopts a classical C 2 H 2 zinc-finger structure characterized by a bba fold. Nuclear magnetic resonance titration maps the binding interfaces between UBZ and ubiquitin to the a-helix of the UBZ domain and the canonical hydrophobic surface of ubiquitin defined by residues L8, I44 and V70. Although the UBZ domain binds ubiquitin through a single a-helix, in a manner similar to the inverted ubiquitin-interacting motif, its structure is distinct from previously characterized ubiquitin-binding domains. The pol g UBZ domain represents a novel member of the C 2 H 2 zinc finger family that interacts with ubiquitin to regulate translesion synthesis.

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Shiou‐Ru Tzeng

Protein activity regulation by conformational entropy

Dynamic activation of an allosteric regulatory protein

Structural basis for cAMP-mediated allosteric control of the catabolite activator protein

Protein dynamics and allostery: an NMR view

Structure of the ubiquitin‐binding zinc finger domain of human DNA Y‐polymerase η

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