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Direct observation of peptide hydrogel self-assembly

Zoë C. Adams, Erika Olson, Tania L. Lopez‐Silva, Zhengwen Lian, Audrey Y. Kim, Matthew Holcomb, Jörg Zimmermann, Ramkrishna Adhikary, Philip E. Dawson

2022Chemical Science20 citationsDOIOpen Access PDF

Abstract

The characterization of self-assembling molecules presents significant experimental challenges, especially when associated with phase separation or precipitation. Transparent window infrared (IR) spectroscopy leverages site-specific probes that absorb in the "transparent window" region of the biomolecular IR spectrum. Carbon-deuterium (C-D) bonds are especially compelling transparent window probes since they are non-perturbative, can be readily introduced site selectively into peptides and proteins, and their stretch frequencies are sensitive to changes in the local molecular environment. Importantly, IR spectroscopy can be applied to a wide range of molecular samples regardless of solubility or physical state, making it an ideal technique for addressing the solubility challenges presented by self-assembling molecules. Here, we present the first continuous observation of transparent window probes following stopped-flow initiation. To demonstrate utility in a self-assembling system, we selected the MAX1 peptide hydrogel, a biocompatible material that has significant promise for use in drug delivery and medical applications. C-D labeled valine was synthetically introduced into five distinct positions of the twenty-residue MAX1 β-hairpin peptide. Consistent with current structural models, steady-state IR absorption frequencies and linewidths of C-D bonds at all labeled positions indicate that these side chains occupy a hydrophobic region of the hydrogel and that the motion of side chains located in the middle of the hairpin is more restricted than those located on the hairpin ends. Following a rapid change in ionic strength to initiate self-assembly, the peptide absorption spectra were monitored as function of time, allowing determination of site-specific time constants. We find that within the experimental resolution, MAX1 self-assembly occurs as a cooperative process. These studies suggest that stopped-flow transparent window FTIR can be extended to other time-resolved applications, such as protein folding and enzyme kinetics.

Topics & Concepts

ChemistryMoleculeSolubilityAbsorption (acoustics)PeptideInfrared spectroscopySpectroscopySide chainSelf-assemblyAbsorption spectroscopyNanotechnologyChemical physicsMaterials scienceOrganic chemistryOpticsQuantum mechanicsBiochemistryPolymerPhysicsComposite materialSupramolecular Self-Assembly in MaterialsChemical Synthesis and AnalysisAdvanced biosensing and bioanalysis techniques