Mg<sup>2+</sup> Binds to the Surface of Thymidylate Synthase and Affects Hydride Transfer at the Interior Active Site

Wang, Zhen; Sapienza, Paul J.; Abeysinghe, Thelma; Luzum, Calvin; Lee, Andrew L.; Finer-Moore, J.; Stroud, Robert M.; Kohen, Amnon

doi:10.1021/ja400761x

Cited by 23 publications

(46 citation statements)

References 80 publications

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“…We have recently studied the ion’s mechanism of action through comprehensive kinetic, structural, and dynamics analyses [72]. Fluorescence assays, crystal structures, and NMR chemical shift changes show that Mg 2+ loosely binds (K d =3.7 mM) to the surface of TSase and forms a bridge between the glutamyl moiety of the folate cofactor and the enzyme through an H-bonding network.…”

Section: Folate In Thymidylate Synthasementioning

confidence: 99%

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Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Roston

Islam

Kohen

2014

Archives of Biochemistry and Biophysics

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Enzymes use a number of common cofactors as sources of hydrogen to drive biological processes, but the physics of the hydrogen transfers to and from these cofactors is not fully understood. Researchers study the mechanistically important contributions from quantum tunneling and enzyme dynamics and connect those processes to the catalytic power of enzymes that use these cofactors. Here we describe some progress that has been made in studying these reactions, particularly through the use of kinetic isotope effects (KIEs). We first discuss the general theoretical framework necessary to interpret experimental KIEs, and then describe practical uses for KIEs in the context of two case studies. The first example is alcohol dehydrogenase, which uses a nicotinamide cofactor to catalyze a hydride transfer, and the second example is thymidylate synthase, which uses a folate cofactor to catalyze both a hydride and a proton transfer.

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Section: Folate In Thymidylate Synthasementioning

confidence: 99%

“…(C) Change in chemical shift of each residue shown from white (no change) to red (maximum change). Reproduced from ref [72] with permission from ACS.…”

Section: Figurementioning

confidence: 99%

Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Roston

Islam

Kohen

2014

Archives of Biochemistry and Biophysics

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“…Furthermore, both our experiments and computations suggest TSase exploits concerted protein motions in catalyzing chemical transformations. [65][66][67][68] Particularly, our experiments with Y209W ecTSase demonstrated that protein motions at various time calculations. 23,108,[130][131][132] Compared with the extensively studied "model protein" DHFR, most enzymes are more similar to TSase, which have more rigid structures and sophisticated mechanisms.…”

Section: Chapter VII Summary Impact and Future Directionsmentioning

confidence: 69%

“…65 Chapter IV extends this methodology to investigate the effects of Mg 2+ on the catalytic mechanism of TSase, which complements the studies in Chapter III and highlights the importance of long-range interactions in TSase-catalyzed reaction. 66 Chapter V presents our QM/MM calculations on the proton transfer step and compares the results with the previously calculated hydride transfer step, providing molecular details underlying the experimental KIE results. 67 It is noteworthy that our computational results not only illustrate functionalities of specific protein residues that reconcile many previous experimental observations, but also provide new insights into the catalytic mechanism that can be examined by future experiments.…”

Section: "Case Study": Thymidylate Synthasementioning

confidence: 99%

“…We found that the stability of CH 2 H 4 folate is dependent on its own concentration, and are currently performing molecular dynamics (MD) simulations to understand this phenomenon. 220 The experimental-theoretical interactive approach taken in this project has not only assisted in understanding the catalytic mechanisms of TSase, but also provided insights into the relationship between protein structures, motions, and catalytic activity. We also studied the effects of Mg 2+ on the catalytic mechanism of TSase, which is the first attempt to resolve the mechanism of interaction between Mg 2+ and TSase.…”

Section: Chapter VII Summary Impact and Future Directionsmentioning

confidence: 99%

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Catalytic mechanisms of thymidylate synthases

Wang¹

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The relationship between protein structure, motions, and catalytic activity is an evolving perspective in enzymology. An interactive approach, where experimental and theoretical studies examine the same catalytic mechanism, is instrumental in addressing this issue. We combine various techniques, including steady state and pre-steady state kinetics, temperature dependence of kinetic isotope effects (KIEs), site-directed mutagenesis, Xray crystallography, and quantum mechanics/molecular mechanics (QM/MM) calculations, to study the catalytic mechanisms of thymidylate synthase (TSase). Since TSase catalyzes the last step of the sole intracellular de novo synthesis of thymidylate (i.e. the DNA base T), it is a common target for antibiotic and anticancer drugs. The proposed catalytic mechanism for TSase comprises a series of bond cleavages and formations including activation of two C-H bonds: a rate-limiting C-H!C hydride transfer and a faster C-H!O proton transfer. This provides an excellent model system to examine the structural and dynamic effects of the enzyme on different C-H cleavage steps in the same catalyzed reaction. Our experiments found that the KIE on the hydride transfer is temperature independent while the KIE on the proton transfer is temperature dependent, implying the protein environment is better organized for H-tunneling in the former. Our QM/MM calculations revealed that the hydride transfer has a transition state (TS) that is invariable with temperature while the proton transfer has multiple subsets of TS structures, which corroborates with our experimental results. The calculations also suggest that collective protein motions rearrange the network of H-bonds to accompany structural changes in the ligands during and between chemical transformations. These computational results not only illustrate functionalities of specific protein residues that reconcile many previous experimental observations, but also provide guidance for future experiments to verify the proposed mechanisms. In addition, we conducted experiments to examine the importance of long-range interactions in TSase-catalyzed reaction, using Quinn, Prof. Claudio Margulis, Prof. Sara Mason, Prof. Lei Geng, and Prof. Alexei Tivanski. I have also received enormous help from the front office (Sharon Robertson), the Chem Store (Tim Koon and Andy Lynch), the mechanic shop (Frank Turner), the electronic shop (Mike Estenson), the IT center (David Sansbury, Jeff Miller, Jon Yates, Chris McGee, and Brenna Faler), the Chem Center (Janet Kugley and Jessica R. Alberhasky), and the Teaching labs (Earlene Erbe) et al. It would be impossible for me to accomplish anything in the past six years if you were not there to help, so thanks a lot to all of you. It is a wonderful department and I will miss you all.

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Examinations of the Chemical Step in Enzyme Catalysis

Singh

Islam

Kohen

2016

Methods in Enzymology

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Advances in computational and experimental methods in enzymology have aided comprehension of enzyme-catalyzed chemical reactions. The main difficulty in comparing computational findings to rate measurements is that the first examines a single energy barrier while the second frequently reflects a combination of many microscopic barriers. We present here intrinsic kinetic isotope effects and their temperature dependence as a useful experimental probe of a single chemical step in a complex kinetic cascade. Computational predictions are tested by this method for two model enzymes: dihydrofolate reductase (DHFR) and thymidylate synthase (TSase). The description highlights the significance of collaboration between experimentalists and theoreticians to develop a better understanding of enzyme-catalyzed chemical conversions.

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Mg²⁺ Binds to the Surface of Thymidylate Synthase and Affects Hydride Transfer at the Interior Active Site

Cited by 23 publications

References 80 publications

Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Catalytic mechanisms of thymidylate synthases

Examinations of the Chemical Step in Enzyme Catalysis

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Mg2+ Binds to the Surface of Thymidylate Synthase and Affects Hydride Transfer at the Interior Active Site

Cited by 23 publications

References 80 publications

Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Kinetic isotope effects as a probe of hydrogen transfers to and from common enzymatic cofactors

Catalytic mechanisms of thymidylate synthases

Examinations of the Chemical Step in Enzyme Catalysis

Contact Info

Product

Resources

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Mg²⁺ Binds to the Surface of Thymidylate Synthase and Affects Hydride Transfer at the Interior Active Site