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22 results on '"Szunyogh, Dániel"'

1. The dynamics of liquid 1-ethyl-3-methylimidazolium acetate measured with implanted-ion $^8$Li $\beta$-NMR

Author

Fujimoto, Derek, McFadden, Ryan M. L., Dehn, Martin H., Petel, Yael, Chatzichristos, Aris, Hemmingsen, Lars, Karner, Victoria L., Kiefl, Robert F., Levy, C. D. Philip, McKenzie, Iain, Michal, Carl A., Morris, Gerald D., Pearson, Matthew R., Szunyogh, Daniel, Ticknor, John O., Stachura, Monika, and MacFarlane, W. Andrew

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics
Abstract

We demonstrate the application of implanted-ion $\beta$-detected NMR as a probe of ionic liquid molecular dynamics through the measurement of $^8$Li spin-lattice relaxation (SLR) and resonance in 1-ethyl-3-methylimidazolium acetate. The motional narrowing of the resonance, and the local maxima in the SLR rate, $1/T_1$, imply a sensitivity to sub-nanosecond Li$^+$ solvation dynamics. From an analysis of $1/T_1$, we extract an activation energy ${E_A = 74.8 \pm 1.5}$ meV and Vogel-Fulcher-Tammann constant ${T_{\mathrm{VFT}} = 165.8 \pm 0.9}$ K, in agreement with the dynamic viscosity of the bulk solvent. Near the melting point, the lineshape is broad and intense, and the form of the relaxation is non-exponential, reflective of our sensitivity to heterogeneous dynamics near the glass transition. The depth resolution of this technique may later provide a unique means of studying nanoscale phenomena in ionic liquids.

Published
2019
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5. Magnesium(II)‐ATP Complexes in 1‐Ethyl‐3‐Methylimidazolium Acetate Solutions Characterized by 31 Mg β‐Radiation‐Detected NMR Spectroscopy

Author

McFadden, Ryan M. L., primary, Szunyogh, Dániel, additional, Bravo‐Frank, Nicholas, additional, Chatzichristos, Aris, additional, Dehn, Martin H., additional, Fujimoto, Derek, additional, Jancsó, Attila, additional, Johannsen, Silke, additional, Kálomista, Ildikó, additional, Karner, Victoria L., additional, Kiefl, Robert F., additional, Larsen, Flemming H., additional, Lassen, Jens, additional, Levy, C. D. Philip, additional, Li, Ruohong, additional, McKenzie, Iain, additional, McPhee, Hannah, additional, Morris, Gerald D., additional, Pearson, Matthew R., additional, Sauer, Stephan P. A., additional, Sigel, Roland K. O., additional, Thulstrup, Peter W., additional, MacFarlane, W. Andrew, additional, Hemmingsen, Lars, additional, and Stachura, Monika, additional

Published
2022
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7. Magnesium(II)‐ATP Complexes in 1‐Ethyl‐3‐Methylimidazolium Acetate Solutions Characterized by 31Mg β‐Radiation‐Detected NMR Spectroscopy.

Author

McFadden, Ryan M. L., Szunyogh, Dániel, Bravo‐Frank, Nicholas, Chatzichristos, Aris, Dehn, Martin H., Fujimoto, Derek, Jancsó, Attila, Johannsen, Silke, Kálomista, Ildikó, Karner, Victoria L., Kiefl, Robert F., Larsen, Flemming H., Lassen, Jens, Levy, C. D. Philip, Li, Ruohong, McKenzie, Iain, McPhee, Hannah, Morris, Gerald D., Pearson, Matthew R., and Sauer, Stephan P. A.

Subjects
*NUCLEAR magnetic resonance spectroscopy, *MAGNESIUM, *NUCLEAR magnetic resonance, *ACETATES, *ENERGY conversion
Abstract

The complexation of MgII with adenosine 5′‐triphosphate (ATP) is omnipresent in biochemical energy conversion, but is difficult to interrogate directly. Here we use the spin‐1/2 β‐emitter 31Mg to study MgII‐ATP complexation in 1‐ethyl‐3‐methylimidazolium acetate (EMIM‐Ac) solutions using β‐radiation‐detected nuclear magnetic resonance (β‐NMR). We demonstrate that (nuclear) spin‐polarized 31Mg, following ion‐implantation from an accelerator beamline into EMIM‐Ac, binds to ATP within its radioactive lifetime before depolarizing. The evolution of the spectra with solute concentration indicates that the implanted 31Mg initially bind to the solvent acetate anions, whereafter they undergo dynamic exchange and form either a mono‐ (31Mg‐ATP) or di‐nuclear (31MgMg‐ATP) complex. The chemical shift of 31Mg‐ATP is observed up‐field of 31MgMg‐ATP, in accord with quantum chemical calculations. These observations constitute a crucial advance towards using β‐NMR to probe chemistry and biochemistry in solution. [ABSTRACT FROM AUTHOR]

Published
2022
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8. On the Use of 31Mg for β-Detected NMR Studies of Solids

Author

McFadden, Ryan M. L., primary, Chatzichristos, Aris, additional, Dehn, Martin H., additional, Fujimoto, Derek, additional, Funakubo, Hiroshi, additional, Gottberg, Alexander, additional, Hitosugi, Taro, additional, Karner, Victoria L., additional, Kiefl, Robert F., additional, Kurokawa, Mao, additional, Lassen, Jens, additional, Levy, C. D. Philip, additional, Li, Ruohong, additional, Morris, Gerald D., additional, Pearson, Matthew R., additional, Shiraki, Susumu, additional, Stachura, Monika, additional, Sugiyama, Jun, additional, Szunyogh, Dániel M., additional, and MacFarlane, W. Andrew, additional

Published
2018
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10. TDPAC andβ-NMR applications in chemistry and biochemistry

Author

Jancso, Attila, primary, Correia, Joao G, additional, Gottberg, Alexander, additional, Schell, Juliana, additional, Stachura, Monika, additional, Szunyogh, Dániel, additional, Pallada, Stavroula, additional, Lupascu, Doru C, additional, Kowalska, Magdalena, additional, and Hemmingsen, Lars, additional

Published
2017
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12. Specificity of the metalloregulator CueR for monovalent metal ions:possible functional role of a coordinated thiol?

Author

Szunyogh, Dániel, Szokolai, Hajnalka, Thulstrup, Peter Waaben, Larsen, Flemming Hofmann, Gyurcsik, Béla, Christensen, Niels Johan, Stachura, Monika Kinga, Hemmingsen, Lars Bo Stegeager, Jancsó, Attila, Szunyogh, Dániel, Szokolai, Hajnalka, Thulstrup, Peter Waaben, Larsen, Flemming Hofmann, Gyurcsik, Béla, Christensen, Niels Johan, Stachura, Monika Kinga, Hemmingsen, Lars Bo Stegeager, and Jancsó, Attila

Abstract

Metal-ion-responsive transcriptional regulators within the MerR family effectively discriminate between mono- and divalent metal ions. Herein we address the origin of the specificity of the CueR protein for monovalent metal ions. Several spectroscopic techniques were employed to study Ag(I) , Zn(II) , and Hg(II) binding to model systems encompassing the metal-ion-binding loop of CueR from E. coli and V. cholerae. In the presence of Ag(I) , a conserved cysteine residue displays a pKa value for deprotonation of the thiol that is close to the physiological pH value. This property is only observed with the monovalent metal ion. Quantum chemically optimized structures of the CueR metal site with Cys 112 protonated demonstrate that the conserved Ser 77 backbone carbonyl oxygen atom from the other monomer of the homodimer is "pulled" towards the metal site. A common allosteric mechanism of the metalloregulatory members of the MerR family is proposed. For CueR, the mechanism relies on the protonation of Cys 112.

Published
2015

16. Towards the role of metal ions in the structural variability of proteins: CdII speciation of a metal ion binding loop motif

Author

Jancsó, Attila, Szunyogh, Dániel, Gyurcsik, Béla, Larsen, Flemming H., Thulstrup, Peter W., Hemmingsen, Lars Bo Stegeager, Christensen, Niels Johan, Jancsó, Attila, Szunyogh, Dániel, Gyurcsik, Béla, Larsen, Flemming H., Thulstrup, Peter W., Hemmingsen, Lars Bo Stegeager, and Christensen, Niels Johan

Abstract

A de novo designed dodecapeptide (HS), inspired by the metal binding loops of metal-responsive transcriptional activators, was synthesized. The aim was to create a model system for structurally promiscuous and intrinsically unstructured proteins, and explore the effect of metal ions on their structure and dynamics. The interaction with CdII was investigated by UV, synchrotron radiation CD, 1H NMR, and perturbed angular correlation (PAC) of γ-rays spectroscopy, pH-potentiometry, and molecular modelling. The peptide mainly displays characteristics of random coil in the CD spectra, and the molecular dynamics simulations demonstrate that it is unstructured with transient and varying helical content. The spectroscopic studies revealed the formation of loop structures with the coordination of the two Cys-thiolates close to each end of the HS peptide, in the presence of one equivalent of CdII per ligand. The imidazole moiety from histidine is also bound to CdII at neutral pH and above. In the presence of 0.5 equivalent of CdII per HS metal bridged structures with e.g. CdS2N 2 and possibly CdS4 coordination geometries are formed above pH ∼6. In an equilibrium of several co-existing species the peptide is exchanging between a number of structures also in its metal ion bound state(s), as indicated by NMR and PAC data. © 2011 The Royal Society of Chemistry.

Published
2011

20. ZnII and HgII binding to a designed peptide that accommodates different coordination geometries.

Author

Szunyogh, Dániel, Gyurcsik, Béla, Larsen, Flemming H., Stachura, Monika, Thulstrup, Peter W., Hemmingsen, Lars, and Jancsó, Attila

Subjects
*ZINC, *METAL ions, *PEPTIDE synthesis, *MERCURY, *ION exchange (Chemistry), *SYNCHROTRON radiation, *COORDINATE covalent bond
Abstract

Designed metal ion binding peptides offer a variety of applications in both basic science as model systems of more complex metalloproteins, and in biotechnology, e.g. in bioremediation of toxic metal ions, biomining or as artificial enzymes. In this work a peptide (HS: Ac-SCHGDQGSDCSI-NH2) has been specifically designed for binding of both ZnII and HgII, i.e. metal ions with different preferences in terms of coordination number, coordination geometry, and to some extent ligand composition. It is demonstrated that HS accommodates both metal ions, and the first coordination sphere, metal ion exchange between peptides, and speciation are characterized as a function of pH using UV-absorption-, synchrotron radiation CD-, 1H-NMR-, and PAC-spectroscopy as well as potentiometry. HgII binds to the peptide with very high affinity in a {HgS2} coordination geometry, bringing together the two cysteinates close to each end of the peptide in a loop structure. Despite the high affinity, HgII is kinetically labile, exchanging between peptides on the subsecond timescale, as indicated by line broadening in 1H-NMR. The ZnII-HS system displays more complex speciation, involving monomeric species with coordinating cysteinates, histidine, and a solvent water molecule, as well as HS-ZnII-HS complexes. In summary, the HS peptide displays conformational flexibility, contains many typical metal ion binding groups, and is able to accommodate metal ions with different structural and ligand preferences with high affinity. As such, the HS peptide may be a scaffold offering binding of a variety of metal ions, and potentially serve for metal ion sequestration in biotechnological applications. [ABSTRACT FROM AUTHOR]

Published
2015
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21. Specificity of the Metalloregulator CueR for Monovalent Metal Ions: Possible Functional Role of a Coordinated Thiol?

Author

Szunyogh D, Szokolai H, Thulstrup PW, Larsen FH, Gyurcsik B, Christensen NJ, Stachura M, Hemmingsen L, and Jancsó A

Abstract

Metal-ion-responsive transcriptional regulators within the MerR family effectively discriminate between mono- and divalent metal ions. Herein we address the origin of the specificity of the CueR protein for monovalent metal ions. Several spectroscopic techniques were employed to study Ag(I) , Zn(II) , and Hg(II) binding to model systems encompassing the metal-ion-binding loop of CueR from E. coli and V. cholerae. In the presence of Ag(I) , a conserved cysteine residue displays a pKa  value for deprotonation of the thiol that is close to the physiological pH value. This property is only observed with the monovalent metal ion. Quantum chemically optimized structures of the CueR metal site with Cys 112 protonated demonstrate that the conserved Ser 77 backbone carbonyl oxygen atom from the other monomer of the homodimer is "pulled" towards the metal site. A common allosteric mechanism of the metalloregulatory members of the MerR family is proposed. For CueR, the mechanism relies on the protonation of Cys 112., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2015
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22. Zn(II) and Hg(II) binding to a designed peptide that accommodates different coordination geometries.

Author

Szunyogh D, Gyurcsik B, Larsen FH, Stachura M, Thulstrup PW, Hemmingsen L, and Jancsó A

Subjects
Circular Dichroism, Ligands, Magnetic Resonance Spectroscopy, Potentiometry, Coordination Complexes chemistry, Mercury chemistry, Oligopeptides chemistry, Zinc chemistry
Abstract

Designed metal ion binding peptides offer a variety of applications in both basic science as model systems of more complex metalloproteins, and in biotechnology, e.g. in bioremediation of toxic metal ions, biomining or as artificial enzymes. In this work a peptide (HS: Ac-SCHGDQGSDCSI-NH2) has been specifically designed for binding of both Zn(II) and Hg(II), i.e. metal ions with different preferences in terms of coordination number, coordination geometry, and to some extent ligand composition. It is demonstrated that HS accommodates both metal ions, and the first coordination sphere, metal ion exchange between peptides, and speciation are characterized as a function of pH using UV-absorption-, synchrotron radiation CD-, (1)H-NMR-, and PAC-spectroscopy as well as potentiometry. Hg(II) binds to the peptide with very high affinity in a {HgS2} coordination geometry, bringing together the two cysteinates close to each end of the peptide in a loop structure. Despite the high affinity, Hg(II) is kinetically labile, exchanging between peptides on the subsecond timescale, as indicated by line broadening in (1)H-NMR. The Zn(II)-HS system displays more complex speciation, involving monomeric species with coordinating cysteinates, histidine, and a solvent water molecule, as well as HS-Zn(II)-HS complexes. In summary, the HS peptide displays conformational flexibility, contains many typical metal ion binding groups, and is able to accommodate metal ions with different structural and ligand preferences with high affinity. As such, the HS peptide may be a scaffold offering binding of a variety of metal ions, and potentially serve for metal ion sequestration in biotechnological applications.

Published
2015
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