Advances in Biomolecular EPR

<p>1. Magnetic Resonance Characterization of Physiologically Important Metal Ion Binding Sites in the Prion and Related Proteins<br>2. The catalytic role of metal-radical/protein-based radicals in heme enzymes<br>3. Rigid Cu2+-based spin labels for the study of higher-order DNA G-quadruplex structures<br>4. Orthogonal spin labeling and membrane proteins: increasing the information content and going towards in cell applications<br>5. Spectroscopic investigation of mono- and di-Mn-containing centers in biochemistry with an emphasis on application of paramagnetic resonance techniques<br>6. In Vivo pO2 Imaging of Tumors: Oxymetry with Very Low-Frequency Electron Paramagnetic Resonance, an Update<br>7. EPR contributions to understanding molybdenum-containing enzymes<br>8. EPR spectroscopy of Type I reaction centers<br>9. Characterization of a substrate-derived radical in the NosN reaction during the biosynthesis of nosiheptide<br>10. Functional solvent-protein interactions characterized by using spin probe EPR spectroscopy<br>11. Integrative Ensemble Modelling of Proteins and their Complexes with Distance Distribution Restraints<br>12. Site directed spin label probes of the mechanism of the cyanobacterial circadian clock<br>13. Pulsed EPR spectroscopy as a tool to probe non-canonical electronic structures in artificial metalloenzymes<br>14. Light-induced Pulsed Dipolar EPR Spectroscopy for distance and orientation analysis<br>15. Recent Advances in Dynamic Nuclear Polarization<br>16. Advances in Rapid Scan EPR Spectroscopy<br>17. Controlling and exploiting intrinsic unpaired electrons in metalloproteins<br>18. EPR advances in characterizing radical SAM Enzymology<br>19. Overhauser high field DNP<br>20. Experimental Guidelines for Trapping Paramagnetic Reaction Intermediates in Radical S-Adenosylmethionine Enzymes<br>21. EPR Characterization of Synthetic Structural and Functional Analogs of Metalloenzyme Active Sites<br>22. EPR spectroscopy on kinases</p>