Severing of a hydrogen bond disrupts amino acid networks in the catalytically active state of the alpha subunit of tryptophan synthase

Axe, Jennifer M.; O’Rourke, Kathleen F.; Kerstetter, Nicole E.; Yezdimer, Eric M.; Chan, Yan Mei; Chasin, Alexander; Boehr, David D.

doi:10.1002/pro.2598

Cited by 19 publications

(25 citation statements)

References 63 publications

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“…Our analysis revealed that there are two networks of residues [colored orange and blue in Fig. (B)], and the residues involved in these networks change depending on what is bound to the protein . Intriguingly, Glu49, a residue directly involved in catalysis, belongs to different networks when comparing the apo resting state and when the enzyme is actively turning over substrate/products (i.e., the working state) .…”

Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 95%

“…These networks may also be important for how αTS communicates and coordinates channeling of its product indole into the active site of the beta subunit of tryptophan synthase (βTS). An amino acid substitution known to disrupt direct channeling of indole from the α‐ to β‐active sites also disrupts networks that might transmit structural dynamic information from the α‐active site to the α/β binding interface …”

Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 99%

“…3(B)], and the residues involved in these networks change depending on what is bound to the protein. [110][111][112] Intriguingly, Glu49, a residue directly involved in catalysis, belongs to different networks when comparing the apo resting state and when the enzyme is actively turning over substrate/products (i.e., the working state). 111 Molecular dynamics (MD) simulations also indicated that the motions of Glu49 are correlated to different sets of residues in these states.…”

Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 99%

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Engineered control of enzyme structural dynamics and function

2018

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Enzymes undergo a range of internal motions from local, active site fluctuations to large-scale, global conformational changes. These motions are often important for enzyme function, including in ligand binding and dissociation and even preparing the active site for chemical catalysis. Protein engineering efforts have been directed towards manipulating enzyme structural dynamics and conformational changes, including targeting specific amino acid interactions and creation of chimeric enzymes with new regulatory functions. Post-translational covalent modification can provide an additional level of enzyme control. These studies have not only provided insights into the functional role of protein motions, but they offer opportunities to create stimulus-responsive enzymes. These enzymes can be engineered to respond to a number of external stimuli, including light, pH, and the presence of novel allosteric modulators. Altogether, the ability to engineer and control enzyme structural dynamics can provide new tools for biotechnology and medicine.

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Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 95%

Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 99%

Section: Enzymes As Amino Acid Interaction Networkmentioning

confidence: 99%

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Engineered control of enzyme structural dynamics and function

2018

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“…Other NMR studies on the enzyme tryptophan synthase have identified long-range allosteric pathways and have mechanistically investigated these pathways by mutations that disrupt critical interactions. 77,78 …”

Section: Nmr Spectroscopy In the Study Of Allosterymentioning

confidence: 99%

Solution NMR Spectroscopy for the Study of Enzyme Allostery

2016

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Allostery is a ubiquitous biological regulatory process in which distant binding sites within a protein or enzyme are functionally and thermodynamically coupled. Allosteric interactions play essential roles in many enzymological mechanisms, often facilitating formation of enzyme-substrate complexes and/or product release. Thus, elucidating the forces that drive allostery is critical to understanding the complex transformations of biomolecules. Currently, a number of models exist to describe allosteric behavior, taking into account energetics as well as conformational rearrangements and fluctuations. In the following review, we discuss the use of solution NMR techniques designed to probe allosteric mechanisms in enzymes. NMR spectroscopy is unequaled in its ability to detect structural and dynamical changes in biomolecules, and the case studies presented herein demonstrate the range of insights to be gained from this valuable method. We also provide a detailed technical discussion of several specialized NMR experiments that are ideally suited for the study of enzymatic allostery.

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“…NMR chemical shift covariance analyses (CHESCA) and MD simulations are powerful tools to detect such amino acid networks when substrates or products are absent (resting state) and present (working state) in the active site [95–97]. We investigated TRPS in its resting and working states to identify the correlation networks from a cluster of residues.…”

Section: Examples Of Modeling Enzymes and Substratesmentioning

confidence: 99%

Investigation of Structural Dynamics of Enzymes and Protonation States of Substrates Using Computational Tools

et al. 2016

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This review discusses the use of molecular modeling tools, together with existing experimental findings, to provide a complete atomic-level description of enzyme dynamics and function. We focus on functionally relevant conformational dynamics of enzymes and the protonation states of substrates. The conformational fluctuations of enzymes usually play a crucial role in substrate recognition and catalysis. Protein dynamics can be altered by a tiny change in a molecular system such as different protonation states of various intermediates or by a significant perturbation such as a ligand association. Here we review recent advances in applying atomistic molecular dynamics (MD) simulations to investigate allosteric and network regulation of tryptophan synthase (TRPS) and protonation states of its intermediates and catalysis. In addition, we review studies using quantum mechanics/molecular mechanics (QM/MM) methods to investigate the protonation states of catalytic residues of β-Ketoacyl ACP synthase I (KasA). We also discuss modeling of large-scale protein motions for HIV-1 protease with coarse-grained Brownian dynamics (BD) simulations.

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Severing of a hydrogen bond disrupts amino acid networks in the catalytically active state of the alpha subunit of tryptophan synthase

Cited by 19 publications

References 63 publications

Engineered control of enzyme structural dynamics and function

Engineered control of enzyme structural dynamics and function

Solution NMR Spectroscopy for the Study of Enzyme Allostery

Investigation of Structural Dynamics of Enzymes and Protonation States of Substrates Using Computational Tools

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