How the Ligand Field in Lanthanide Coordination Complexes Determines Magnetic Susceptibility Anisotropy, Paramagnetic NMR Shift, and Relaxation Behavior

Parker, David; Suturina, Elizaveta A.; Kuprov, Ilya; Chilton, Nicholas F.

doi:10.1021/acs.accounts.0c00275

Cited by 138 publications

(170 citation statements)

References 96 publications

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“…CCR are relevant when the Curie spin relaxation from Equation (9) becomes the dominant contribution to transverse relaxation, as it typically occurs for systems with large S values and high molecular mass and at very high magnetic fields. Finally, for paramagnetic systems characterized by strong magnetic anisotropy, the scenario can be further complicated: a substantial angular dependence of nuclear relaxation rates has been observed due to relaxation anisotropy [34,35], while significant additional contribution to relaxation have been observed from other cross correlation mechanisms, such as those involving Curie spin relaxation and chemical shift anisotropy [36]. Moreover, in several cases a substantial deviation from the r −6 dependency of PREs has been observed and interpreted as due to non-specific intermolecular PREs [37].…”

Section: Paramagnetic Nmrmentioning

confidence: 99%

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Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein–Protein Interactions of Metalloproteins: The Case of Iron–Sulfur Proteins

Piccioli¹

2020

Magnetochemistry

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The study of cellular machineries responsible for the iron–sulfur (Fe–S) cluster biogenesis has led to the identification of a large number of proteins, whose importance for life is documented by an increasing number of diseases linked to them. The labile nature of Fe–S clusters and the transient protein–protein interactions, occurring during the various steps of the maturation process, make their structural characterization in solution particularly difficult. Paramagnetic nuclear magnetic resonance (NMR) has been used for decades to characterize chemical composition, magnetic coupling, and the electronic structure of Fe–S clusters in proteins; it represents, therefore, a powerful tool to study the protein–protein interaction networks of proteins involving into iron–sulfur cluster biogenesis. The optimization of the various NMR experiments with respect to the hyperfine interaction will be summarized here in the form of a protocol; recently developed experiments for measuring longitudinal and transverse nuclear relaxation rates in highly paramagnetic systems will be also reviewed. Finally, we will address the use of extrinsic paramagnetic centers covalently bound to diamagnetic proteins, which contributed over the last twenty years to promote the applications of paramagnetic NMR well beyond the structural biology of metalloproteins.

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Section: Paramagnetic Nmrmentioning

confidence: 99%

“…Attempts to replace classical NMR restraints with paramagnetism-based restraints were only partially successful [160][161][162]. Recent studies provided examples in which the spatial dependence of paramagnetic relaxation deviates from the r MH −6 dependence [34,35].…”

Section: Paramagnetism-based Nmr Solution Structure: Are Solution Strmentioning

confidence: 99%

Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein–Protein Interactions of Metalloproteins: The Case of Iron–Sulfur Proteins

Piccioli¹

2020

Magnetochemistry

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“… 7 − 15 PCSs are also gaining momentum in the characterization of the electronic structures of single ion magnets. 6 , 16 − 18 …”

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confidence: 99%

Solution of a Puzzle: High-Level Quantum-Chemical Treatment of Pseudocontact Chemical Shifts Confirms Classic Semiempirical Theory

Lang

Ravera

Parigi

et al. 2020

J. Phys. Chem. Lett.

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A recently popularized approach for the calculation of pseudocontact shifts (PCSs) based on first-principles quantum chemistry (QC) leads to different results than the classic “semiempirical” equation involving the susceptibility tensor. Studies that attempted a comparison of theory and experiment led to conflicting conclusions with respect to the preferred theoretical approach. In this Letter, we show that after inclusion of previously neglected terms in the full Hamiltonian, one can deduce the semiempirical equations from a rigorous QC-based treatment. It also turns out that in the long-distance limit, one can approximate the complete A tensor in terms of the g tensor. By means of Kohn–Sham density functional theory calculations, we numerically confirm the long-distance expression for the A tensor and the theoretically predicted scaling behavior of the different terms. Our derivation suggests a computational strategy in which one calculates the susceptibility tensor and inserts it into the classic equation for the PCS.

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“…The paramagnetic shifts for pyridine protons are more pronounced than those of the N‐anchored tripod L3 . Nevertheless, overall chemical shifts are relatively small because of a weak crystal field is such C 3 ‐symmetrical complexes [28] . The peak assignment is ascertained using two‐dimensional techniques (e. g., 1 H COSY NMR for [Eu L2 ] 3+ in Figure S6).…”

Section: Resultsmentioning

confidence: 99%

“…Nevertheless, overall chemical shifts are relatively small because of a weak crystal field is such C 3 -symmetrical complexes. [28] The peak assignment is ascertained using two-dimensional techniques (e. g., 1 H COSY NMR for [EuL2] 3 + in Figure S6). 1 1 equivalent.…”

Section: Characterization Of Ln III Complexes With Esi-ms and Nmrmentioning

confidence: 99%

Lanthanide Podands with a Short Tripodal Ligand: The Missing Piece of Puzzle

Guénée

Pal

et al. 2020

Eur J Inorg Chem

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A new small tripodal ligand L2 has been synthetized and used for lanthanide complexation in acetonitrile. This podand has a short distance between the carbon anchor and the binding sites, but this structural motif still leads to the formation of stable tripodal mononuclear complexes. Indeed, the crystal structure of a C 3-symmetrical mononuclear complex with Eu III shows a helical wrapping of binding strands around the cation. Similar tripodal complexes are formed with L2 along the Ln III series. The selected ones were characterized with different techniques including NMR, mass spectrometry and spectroscopy. As shown with spectrophotometric and NMR titrations, the LnL2 complexes are moderately stable (log β~7) but remain unchanged in large metal excess. In addition, luminescence lifetimes confirm the complexation of trivalent lanthanide in a single well-protected coordination environment.

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How the Ligand Field in Lanthanide Coordination Complexes Determines Magnetic Susceptibility Anisotropy, Paramagnetic NMR Shift, and Relaxation Behavior

Cited by 138 publications

References 96 publications

Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein–Protein Interactions of Metalloproteins: The Case of Iron–Sulfur Proteins

Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein–Protein Interactions of Metalloproteins: The Case of Iron–Sulfur Proteins

Solution of a Puzzle: High-Level Quantum-Chemical Treatment of Pseudocontact Chemical Shifts Confirms Classic Semiempirical Theory

Lanthanide Podands with a Short Tripodal Ligand: The Missing Piece of Puzzle

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