Jihyun Kim scite author profile

Multidimensional NOESY experiments targeting correlations between exchangeable imino and amino protons provide valuable information about base pairing in nucleic acids. It has been recently shown that the sensitivity of homonuclear correlations involving RNA’s labile imino protons can be significantly enhanced, by exploiting the repolarization brought about by solvent exchanges. Homonuclear correlations, however, are of limited spectral resolution, and usually incapable of tackling relatively large homopolymers with repeating structures like RNAs. This study presents a heteronuclear-resolved version of those NOESY experiments, in which magnetization transfers between the aqueous solvent and the nucleic acid protons are controlled by selecting specific chemical shift combinations of a coupled 1 H– 15 N spin pair. This selective control effectively leads to a pseudo-3D version of HSQC-NOESY, but with cross-peaks enhanced by ∼2–5× as compared with conventional 2D NOESY counterparts. The enhanced signal sensitivity as well as access to both 15 N– 1 H and 1 H– 1 H NOESY dimensions can greatly facilitate RNA assignments and secondary structure determinations, as demonstrated here with the analysis of genome fragments derived from the SARS-CoV-2 virus.

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Time- and site-resolved kinetic NMR for real-time monitoring of off-equilibrium reactions by 2D spectrotemporal correlations

Jaroszewicz

Liu

Kim

et al. 2022

Nat Commun

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Nuclear magnetic resonance (NMR) spectroscopy provides detailed information about dynamic processes through line-shape changes, which are traditionally limited to equilibrium conditions. However, a wealth of information is available by studying chemical reactions under off-equilibrium conditions—e.g., in states that arise upon mixing reactants that subsequently undergo chemical changes—and in monitoring the reactants and products in real time. Herein, we propose and demonstrate a time-resolved kinetic NMR experiment that combines rapid mixing techniques, continuous flow, and single-scan spectroscopic imaging methods, leading in unison to a 2D spectrotemporal NMR correlation that provides high-quality kinetic information of off-equilibrium chemical reactions. These kinetic 2D NMR spectra possess a high-resolution spectral dimension revealing the individual chemical sites, correlated with a time-independent, steady-state spatial axis that delivers information concerning temporal changes along the reaction coordinate. A comprehensive description of the kinetic, spectroscopic, and experimental features associated with these spectrotemporal NMR analyses is presented. Experimental demonstrations are carried out using an enzymatically catalyzed reaction leading to site- and time-resolved kinetic NMR data, that are in excellent agreement with control experiments and literature values.

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The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs

et al. 2022

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Hadamard encoded saturation transfer can significantly improve the efficiency of NOE-based NMR correlations from labile protons in proteins, glycans and RNAs, increasing the sensitivity of cross-peaks by an order of magnitude and shortening experimental times by � 100-fold. These schemes, however, fail when tackling correlations within a pool of labile protons -for instance imino-imino correlations in RNAs or amide-amide correlations in proteins. Here we analyze the origin of the artifacts appearing in these experiments and propose a way to obtain artifact-free correlations both within the labile pool as well as between labile and non-labile 1 Hs, while still enjoying the gains arising from Hadamard encoding and solvent repolarizations. The principles required for implementing what we define as the extended Hadamard scheme are derived, and its clean, artifact-free, sensitivity-enhancing performance is demonstrated on RNA fragments derived from the SARS-CoV-2 genome. Sensitivity gains per unit time approaching an order of magnitude are then achieved in both imino-imino and iminoamino/aromatic protons 2D correlations; similar artifact-free sensitivity gains can be observed when carrying out extended Hadamard encodings of 3D NOESY/HSQC-type experiments. The resulting spectra reveal significantly more correlations than their conventionally acquired counterparts, which can support the spectral assignment and secondary structure determination of structured RNA elements.

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Cover Feature: The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs (ChemPhysChem 4/2022)

et al. 2022

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The Cover Feature illustrates how artifact‐free 2D NOE correlations between labile protons can be obtained from an extended Hadamard encoding/decoding matrix, which supersedes problems in conventional Hadamard schemes. The sensitivity‐enhancing abilities of extended Hadamard encoding operating in conjunction with solvent repolarization mechanisms are demonstrated on GHz NMR studies on SARS‐CoV‐2 RNA fragments. More information can be found in the Article by Lucio Frydman and co‐workers.

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Jihyun Kim

Heteronuclear transfers from labile protons in biomolecular NMR: Cross polarization, revisited

3D Heteronuclear Magnetization Transfers for the Establishment of Secondary Structures in SARS-CoV-2-Derived RNAs

Time- and site-resolved kinetic NMR for real-time monitoring of off-equilibrium reactions by 2D spectrotemporal correlations

The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs

Cover Feature: The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs (ChemPhysChem 4/2022)

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Jihyun Kim

Heteronuclear transfers from labile protons in biomolecular NMR: Cross polarization, revisited

3D Heteronuclear Magnetization Transfers for the Establishment of Secondary Structures in SARS-CoV-2-Derived RNAs

Time- and site-resolved kinetic NMR for real-time monitoring of off-equilibrium reactions by 2D spectrotemporal correlations

The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile 1Hs of SARS‐CoV‐2‐derived RNAs

Cover Feature: The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile 1Hs of SARS‐CoV‐2‐derived RNAs (ChemPhysChem 4/2022)

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Product

Resources

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The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs

Cover Feature: The Extended Hadamard Transform: Sensitivity‐Enhanced NMR Experiments Among Labile and Non‐Labile ¹Hs of SARS‐CoV‐2‐derived RNAs (ChemPhysChem 4/2022)