The Biophysical Probes 2-fluorohistidine and 4-fluorohistidine: Spectroscopic Signatures and Molecular Properties

Chemical tools for probing histidine modifications

Histidine is a unique amino acid with critical roles in protein structure and function, ranging from metal ion binding to enzyme catalysis. Histidine residues in proteins also undergo diverse posttranslational modifications, including methylation, phosphorylation and hydroxylation, by various enzymes, some of them being only recently identified and characterised. In this review, we describe the development of chemical tools for understanding the role of histidine residues in chemical and biological systems. We spotlight the application of histidine analogues in probing biomedically important posttranslational modifications of histidine residues in proteins, and we highlight novel bioconjugation methods that enable chemoselective modifications of histidine residues in peptides and proteins.

Newly identified C–H⋯O hydrogen bond in histidine

Histidine C–H bonds observed in protein structures include (clockwise from top left): myoglobin, β-lactamase, and photoactive yellow protein; calculations indicate that tautomeric/protonation state influences H-bonding ability (bottom left).

Evaluating electronic structure methods for accurate calculation of 19 F chemical shifts in fluorinated amino acids

The ability of electronic structure methods (11 density functionals, HF, and MP2 calculations; two basis sets and two solvation models) to accurately calculate the ¹⁹ F chemical shifts of 31 structures of fluorinated amino acids and analogues with known experimental ¹⁹ F NMR spectra has been evaluated. For this task, BHandHLYP, ωB97X, and Hartree-Fock with scaling factors (provided within) are most accurate. Additionally, the accuracy of methods to calculate relative changes in fluorine shielding across 23 sets of structural variants, such as zwitterionic amino acids versus side chains only, was also determined. This latter criterion may be a better indicator of reliable methods for the ultimate goal of assigning and interpreting chemical shifts of fluorinated amino acids in proteins. It was found that MP2 and M062X calculations most accurately assess changes in shielding among analogues. These results serve as a guide for computational developments to calculate ¹⁹ F chemical shifts in biomolecular environments. © 2017 Wiley Periodicals, Inc.