Analysis of Artifacts Caused by Pulse Imperfections in CPMG Pulse Trains in NMR Relaxation Dispersion Experiments

Konuma, Tsuyoshi; Nagadoi, Aritaka; Kurita, Jun

doi:10.3390/magnetochemistry4030033

Cited by 6 publications

(2 citation statements)

References 39 publications

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“…This is likely, in large part, from the large number of pulses increasing the coil temperature, which, in turn, reduces the RF performance. However, the artefacts may also arise due to offset dependent artefacts (which have been noted in various biomolecular analyses) or due to complications from J‐modulation . In relation to coil heating, these artefacts are likely to be probe‐dependent, especially as the power required to perform 180 o inversions will vary from probe to probe.…”

Section: Resultsmentioning

confidence: 99%

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Hassan

Majumdar

et al. 2019

Magnetic Reson in Chemistry

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Proton nuclear magnetic resonance (NMR) spectra of intact biological samples often show strong contributions from lipids, which overlap with signals of interest from small metabolites. Pioneering work by Diserens et al. demonstrated that the relative differences in diffusivity and relaxation of lipids versus small metabolites could be exploited to suppress lipid signals, in high‐resolution magic angle spinning (HR‐MAS) NMR spectroscopy. In solution‐state NMR, suspended samples can exhibit very broad water signals, which are challenging to suppress. Here, improved water suppression is incorporated into the sequence, and the Carr‐Purcell‐Meiboom‐Gill sequence (CPMG) train is replaced with a low‐power adiabatic spinlock that reduces heating and spectral artefacts seen with longer CPMG filters. The result is a robust sequence that works well in both HR‐MAS as well as static solution‐state samples. Applications are also extended to include in vivo organisms. For solution‐state NMR, samples containing significant amount of fats such as milk and hemp hearts seeds are used to demonstrate the technique. For HR‐MAS, living earthworms (Eisenia fetida) and freshwater shrimp (Hyalella azteca) are used for in vivo applications. Lipid suppression techniques are essential for non‐invasive NMR‐based analysis of biological samples with a high‐lipid content and adds to the suite of experiments advantageous for in vivo environmental metabolomics.

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Section: Resultsmentioning

confidence: 99%

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Hassan

Majumdar

et al. 2019

Magnetic Reson in Chemistry

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“…The 13 C single quantum relaxation dispersion experiments were recorded at 30 °C, using a TROSY-based pulse sequence 23 with a phase modification in the spin-state selective inversion element during the Carr-Purcell-Meiboom-Gill (CPMG) pulse train 48 . The R ex values were obtained at the 13 C frequency of 200 MHz with the constant time CPMG relaxation periods were set to 30 ms for the StA SL domain and 40 ms for the J domain, respectively.…”

Section: Nmr Spectroscopymentioning

confidence: 99%

Dynamically regulated two-site interaction of viral RNA to capture host translation initiation factor

Imai,

Suzuki,

Fujiyoshi

et al. 2023

Nat Commun

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Many RNA viruses employ internal ribosome entry sites (IRESs) in their genomic RNA to commandeer the host’s translational machinery for replication. The IRES from encephalomyocarditis virus (EMCV) interacts with eukaryotic translation initiation factor 4 G (eIF4G), recruiting the ribosomal subunit for translation. Here, we analyze the three-dimensional structure of the complex composed of EMCV IRES, the HEAT1 domain fragment of eIF4G, and eIF4A, by cryo-electron microscopy. Two distinct eIF4G-interacting domains on the IRES are identified, and complex formation changes the angle therebetween. Further, we explore the dynamics of these domains by using solution NMR spectroscopy, revealing conformational equilibria in the microsecond to millisecond timescale. In the lowly-populated conformations, the base-pairing register of one domain is shifted with the structural transition of the three-way junction, as in the complex structure. Our study provides insights into the viral RNA’s sophisticated strategy for optimal docking to hijack the host protein.

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Numerical investigating the low field NMR response of representative pores at different pulse sequence parameters

Fan

Liu

et al. 2021

Computers & Geosciences

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Analysis of Artifacts Caused by Pulse Imperfections in CPMG Pulse Trains in NMR Relaxation Dispersion Experiments

Cited by 6 publications

References 39 publications

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Dynamically regulated two-site interaction of viral RNA to capture host translation initiation factor

Numerical investigating the low field NMR response of representative pores at different pulse sequence parameters

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Analysis of Artifacts Caused by Pulse Imperfections in CPMG Pulse Trains in NMR Relaxation Dispersion Experiments

Cited by 6 publications

References 39 publications

Improvements in lipid suppression for 1H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Improvements in lipid suppression for 1H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Dynamically regulated two-site interaction of viral RNA to capture host translation initiation factor

Numerical investigating the low field NMR response of representative pores at different pulse sequence parameters

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Product

Resources

About

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples

Improvements in lipid suppression for ¹H NMR‐based metabolomics: Applications to solution‐state and HR‐MAS NMR in natural and in vivo samples