Abstract
Azido-modified alanine residues (AlaN3) are environment-sensitive, minimally invasive infrared probes for the site-specific investigation of protein structure and dynamics. Here, the capability of the label is investigated to query whether or not a ligand is bound to the active site of lysozyme and how the spectroscopy and dynamics change upon ligand binding. The results demonstrate specific differences for center frequencies of the asymmetric azide stretch vibration, the longtime decay, and the static offset of the frequency fluctuation correlation function (FFCF)-all of which are experimental observables-between the ligand-free and the ligand-bound N3-labeled protein. The center-frequency shifts range from 1 to 8 cm-1, which is detectable from state-of-the art experiments. Similarly, the nonvanishing static component Δ0 of the FFCF between ligand-free and ligand-bound protein can differ by up to a factor of 2.5. This makes the azide label a versatile and structurally sensitive probe to report on the dynamics of proteins in a variety of environments and for a range of different applications. Ligand-induced differences in the dynamics are also mapped onto changes in the local and through-space coupling between residues by virtue of dynamical cross correlation maps. This demonstrates that the position where the label is placed also influences the local and global protein motions.
Highlights
IntroductionProteins are essential for function and sustaining the life of organisms. Experimentation and computational studies have clarified that protein function involves both structure and dynamics. characterizing structural and functional dynamics of proteins at the same time under physiological conditions in the condensed phase, which is prerequisite for understanding cellular processes at a molecular level, remains challenging. Vibrational spectroscopy, in particular, two-dimensional infrared (2D IR) spectroscopy, has been shown to be a powerful tool for studying the structural dynamics of various biological systems. One of the particular challenges is to obtain structural and environmental information in a site-specific manner
MD simulations for the wild type (WT) and all azide-labeled (AlaN3) modified lysozymes were carried out using an adapted version of the Chemistry at Harvard Molecular Mechanics (CHARMM) program36 with an interface to perform simulations with the reproducing kernel Hilbert space (RKHS) potential energy surface (PES)
This work demonstrates that the 1D and 2D IR spectroscopy of the azide bound to alanine residues within one conformational substate for WT lysozyme provides valuable sitespecific and temporal information about ligand binding of PhCN to the active site of WT lysozyme
Summary
Proteins are essential for function and sustaining the life of organisms. Experimentation and computational studies have clarified that protein function involves both structure and dynamics. characterizing structural and functional dynamics of proteins at the same time under physiological conditions in the condensed phase, which is prerequisite for understanding cellular processes at a molecular level, remains challenging. Vibrational spectroscopy, in particular, two-dimensional infrared (2D IR) spectroscopy, has been shown to be a powerful tool for studying the structural dynamics of various biological systems. One of the particular challenges is to obtain structural and environmental information in a site-specific manner. Significant effort has been focused on the development and application of various infrared (IR) reporters that absorb in the frequency range of 1700–2800 cm−1 to discriminate the signal from the strong protein background.. Significant effort has been focused on the development and application of various infrared (IR) reporters that absorb in the frequency range of 1700–2800 cm−1 to discriminate the signal from the strong protein background.7,8 Such IR probes have provided valuable information about the structure and dynamics of complex systems. Isotope edited carbonyl spectroscopy was used to characterize the mechanism of protein folding and amyloid formation or the structure and function of membrane proteins.15,16 Additional molecular groups, such as thiocyanate, cyanamide, sulfhydryl vibrations of cysteines, deuterated carbons, carbonyl vibrations of metal-carbonyls, cyanophenylalanine, and azidohomoalanine (Aha), have been explored Nitrile probes have helped to clarify the role of electrostatic fields in enzymatic reactions or to elucidate the mode of drug binding to proteins. Isotope edited carbonyl spectroscopy was used to characterize the mechanism of protein folding and amyloid formation or the structure and function of membrane proteins. Additional molecular groups, such as thiocyanate, cyanamide, sulfhydryl vibrations of cysteines, deuterated carbons, carbonyl vibrations of metal-carbonyls, cyanophenylalanine, and azidohomoalanine (Aha), have been explored
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