Solvent Structure and Hammerhead Ribozyme Catalysis

Martick, Monika; T, Lee; York, Darrin M.; Scott, William G.

doi:10.1016/j.chembiol.2008.03.010

Cited by 105 publications

(205 citation statements)

References 59 publications

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“…Results are compared to the recent 2.2 Å crystal structure of the full-length hammerhead in the presence of Mg 2+ ions,20 and to the 2.0 Å crystal structure with resolved Mn 2+ binding sites and solvent structure. 24 The present simulations results are consistent with a hammerhead ribozyme model whereby the active site forms a region of local negative charge that requires electrostatic stabilization to preserve its structural integrity, and whereby this stabilization can be effected by divalent metal binding at the C-site or in a bridging position in the ground (pre-reactive) state. An Mg 2+ ion is observed to weakly bind at the C-site position at solvent separation with G10.1, facilitating the formation of near in-line attack conformations, particularly when in the bridging position where there is increased interaction between the nucleophile (C17:O 2′ ) and the implicated general base (G12).…”

Section: Discussionsupporting

confidence: 86%

“…15,20,24 The first initial Mg 2+ binding site, designated the "C-site'', is an implicated metal-ion binding site based on a very recent hammerhead RNA structure with resolved metal and solvent positions24 in which a Mn 2+ cation directly coordinates to both A9:O 2P and G10.1:N 7 . The second initial Mg 2+ binding site, designated the "Bridging'' site, is one in which the Mg 2+ ion bridges the A9 and scissile phosphates, directly coordinating the two nonbridging O P2 atoms that are 4.3 Å apart in the crystal structure.20 This type of coordination was inferred both from the O-O distance in the crystal structure and also the thio/rescue effect experiments that suggest a single divalent metal might bridge these positions in the transition state.…”

Section: Mg 2+ Ion Binding Modes In the Active Sitementioning

confidence: 99%

“…This stabilization can be effected by divalent metal ion binding24,29 or likely by high concentrations of monovalent cations (Li + , Na + or NH 4 + cations required concentrations 400-fold higher than those used in Mg 2+ to achieve comparable rates of cleavage).66-68 In the ground state, a divalent metal ion can occupy the C-site to effect such electrostatic stabilization. 24 In the case of Mn 2+ , the C-site formed by A9/G10.1 is a high-affinity binding site, as recently characterized by electron spin-echo envelope modulation spectroscopy.69 On the other hand, in the case of Mg 2+ , binding at the C-site does not appear to be strong, as suggested by the molecular simulations and the observed absence of resolved metal cations in that site in the full-length hammerhead crystal obtained in the presence of 1 mM Mg 2+ and > 1 M NH 4 +. 20 However, upon crystallization in the presence of 10 mM Mn 2+ , metal binding was observed in the C-site position,24 likely because the softer Mn 2+ has higher affinity than Mg 2+ for binding the N 7 of G10.1, as discussed in the section presenting results of DFT calculations.…”

Section: Mechanistic Interpretationmentioning

confidence: 99%

“…Very recently, a crystal structure was obtained in the presence of the softer divalent cation Mn 2+ that allowed the identification of a divalent binding site involving A9 and G10.1 near the active site. 24 It remains an open question, however, as to what conformational events and changes in metal binding may occur in proceeding to the transition state from a precatalytic active conformation. Molecular simulation offers a powerful tool to probe the structure and dynamics along the chemical reaction coordinate and the role played by divalent metal ions in stabilizing the transition state.…”

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Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation

et al. 2008

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Molecular dynamics simulations have been performed to investigate the role of Mg 2+ in the fulllength hammerhead ribozyme cleavage reaction. In particular, the aim of this work is to characterize the binding mode and conformational events that give rise to catalytically active conformations and stabilization of the transition state. Toward this end, a series of eight 12 ns molecular dynamics simulations have been performed with different divalent metal binding occupations for the reactant, early and late transition state using recently developed force field parameters for metal ions and reactive intermediates in RNA catalysis. In addition, hybrid QM/ MM calculations of the early and late transition state were performed to study the proton-transfer step in general acid catalysis that is facilitated by the catalytic Mg 2+ ion. The simulations suggest that Mg 2+ is profoundly involved in the hammerhead ribozyme mechanism both at structural and catalytic levels. Binding of Mg 2+ in the active site plays a key structural role in the stabilization of stem I and II and to facilitate formation of near attack conformations and interactions between the nucleophile and G12, the implicated general base catalyst. In the transition state, Mg 2+ binds in a bridging position where it stabilizes the accumulated charge of the leaving group while interacting with the 2′OH of G8, the implicated general acid catalyst. The QM/MM simulations provide support that, in the late transition state, the 2′OH of G8 can transfer a proton to the leaving group while directly coordinating the bridging Mg 2+ ion. The present study provides evidence for the role of Mg 2+ in hammerhead ribozyme catalysis. The proposed simulation model reconciles the interpretation of available experimental structural and biochemical data, and provides a starting point for more detailed investigation of the chemical reaction path with combined QM/MM methods.

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Section: Discussionsupporting

confidence: 86%

Section: Mg 2+ Ion Binding Modes In the Active Sitementioning

confidence: 99%

Section: Mechanistic Interpretationmentioning

confidence: 99%

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Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation

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“…These tertiary interactions result in a higher population of functionally folded ribozymes, leading to higher observed rates at significantly lower divalent metal concentrations in vitro, as well as activity in vivo (Khvorova et al 2003). New structures of constructs based on native HHRz's (2GOZ, 2OEU, 2QUS) largely satisfy predictions based on previous mutations and also provide new hypotheses concerning players in the HHRz mechanism (Martick and Scott 2006;Lee et al 2007;Chi et al 2008;Martick et al 2008). The conformation of the native HHRz in crystalforming conditions is significantly different from that of the truncated HHRz.…”

Section: Introductionmentioning

confidence: 85%

Ground-state coordination of a catalytic metal to the scissile phosphate of a tertiary-stabilized Hammerhead ribozyme

Ward¹,

DeRose²

2011

RNA

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Although the Hammerhead ribozyme (HHRz) has long been used as a model system in the field of ribozyme enzymology, several details of its mechanism are still not well understood. In particular, significant questions remain concerning the disposition and role of catalytic metals in the HHRz. Previous metal-rescue experiments using a ''minimal'' HHRz resulted in prediction of a catalytic metal that is bound in the A9/G10.1 site in the ground state of the reaction and that bridges to the scissile phosphate further along the reaction pathway. ''Native'' or extended HHRz constructs contain tertiary contacts that stabilize a more compact structure at moderate ionic strength. We performed Cd 2+ rescue experiments on an extended HHRz from Schistosoma mansoni using stereo-pure scissile phosphorothioate-substituted substrates in order to determine whether a metal ion makes contact with the scissile phosphate in the ground state or further along the reaction coordinate. Inhibition in Ca 2+ /Mg 2+ and rescue by thiophilic Cd 2+ was specific for the R p -S stereoisomer of the scissile phosphate. The affinity of the rescuing Cd 2+ , measured in two different ionic strength backgrounds, increased fourfold to 17-fold when the pro-R p oxygen is replaced by sulfur. These data support a model in which the rescuing metal ion makes a ground-state interaction with the scissile phosphate in the native HHRz. The resulting model for Mg 2+ activation in the HHRz places a metal ion in contact with the scissile phosphate, where it may provide ground-state electrostatic activation of the substrate.

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Solvent Structure and Hammerhead Ribozyme Catalysis

Cited by 105 publications

References 59 publications

Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation

Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation

Ground-state coordination of a catalytic metal to the scissile phosphate of a tertiary-stabilized Hammerhead ribozyme

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Solvent Structure and Hammerhead Ribozyme Catalysis

Cited by 105 publications

References 59 publications

Role of Mg2+ in Hammerhead Ribozyme Catalysis from Molecular Simulation

Role of Mg2+ in Hammerhead Ribozyme Catalysis from Molecular Simulation

Ground-state coordination of a catalytic metal to the scissile phosphate of a tertiary-stabilized Hammerhead ribozyme

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Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation

Role of Mg²⁺ in Hammerhead Ribozyme Catalysis from Molecular Simulation