Hindered segmental dynamics in associative protein hydrogels studied by neutron spin-echo spectroscopy

• dc.contributor.author: Rao, Ameya
• dc.contributor.author: Carrick, Brian R
• dc.contributor.author: Yao, Helen
• dc.contributor.author: Olsen, Bradley D
• dc.date.issued: 2023-07-26
• dc.identifier.uri: https://hdl.handle.net/1721.1/163759
• dc.description.abstract: Transient binding between associating macromolecules can cause qualitative changes to chain dynamics, including modes of conformational relaxation and diffusion, through tethering effects imparted by long-range connectivity. In this work, the role of binding on short-time segmental dynamics in associative polymer gels is investigated by neutron spin-echo (NSE) measurements on a class of model artificial coiled-coil proteins with a systematically varied architecture, probing timescales of 0.1–130 ns, and length scales close to the molecular radius of gyration. The results illustrate effects of transient cross-linking on chain dynamics on different timescales, manifested in changes in segmental relaxation behavior with variations in strand length, chain concentration, and sticker distribution (endblock- vs midblock-functionalized). In all gels, a short-time cooperative diffusion mode is seen over all wave vectors, analogous to a semidilute solution, with no transitions seen at any known structural length scale. However, the diffusion coefficients are found to decrease with increasing junction density across all gels, with the strand length and number of stickers per chain in each gel appearing to play a relatively minor role. The slowing of cooperative diffusion with junction density contrasts with classical predictions of a greater restoring force for fluctuation dissipation due to the increased elasticity, suggesting additional effects of the coiled-coil junctions such as an enhancement in local viscosity that slows dynamics. Notably, the relaxation rates for all gels can be rescaled by the interjunction spacing inferred from small-angle neutron scattering, where they collapse onto a master curve suggestive of self-similar dynamics even in networks with different strand lengths and chain architectures. On long timescales (but shorter than the junction exchange time), a slowing of network relaxation is observed, resulting in a nondecaying plateau in the spin-echo amplitude attributed to a freezing of chain dynamics due to tethering. A characteristic length scale corresponding to the extent of dynamic fluctuations is estimated for each gel, which appears to be smaller than the interjunction spacing but similar to the correlation blob size of the overlapping strands. The results indicate an important role of transient binding on molecular-scale dynamics in associative polymer gels, even on timescales shorter than the junction exchange time, in addition to its effects on long-range self-diffusion previously observed.
• dc.language.iso: en
• dc.publisher: American Physical Society
• dc.relation.isversionof: 10.1103/physrevmaterials.7.075602
• dc.source: OSTI
• dc.type: Article
• dc.identifier.citation: Rao, Ameya, Carrick, Brian R, Yao, Helen and Olsen, Bradley D. 2023. "Hindered segmental dynamics in associative protein hydrogels studied by neutron spin-echo spectroscopy." Physical Review Materials, 7 (7).
• dc.contributor.department: Massachusetts Institute of Technology. Department of Chemical Engineering
• dc.relation.journal: Physical Review Materials
• dc.eprint.version: Author's final manuscript
• mit.journal.volume: 7
• mit.journal.issue: 7