Quantifying Polypeptoid Conformational Landscapes through Integrated Experiment and Simulation

Jiao, Sally; DeStefano, Audra; Monroe, Jacob I.; Barry, Mikayla; Sherck, Nicholas; Casey, Thomas M.; Segalman, Rachel A.; Han, Songi; Shell, M. Scott

doi:10.1021/acs.macromol.1c00550

Cited by 13 publications

(34 citation statements)

References 92 publications

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“…Lennard-Jones nonbonded interactions are cut off at 10 Å. Hydrogen bonds are constrained with SHAKE, 35 and water is kept rigid with SETTLE. 36 We first run a simulation in an expanded ensemble over softened ω dihedral states, a technique we previously developed and validated that samples across slow isomerizations in the polypeptoid backbone, 31 using Langevin dynamics with an integration timestep of 2 fs, a temperature of 300 K, and a friction coefficient of 0.01 ps −1 . The pressure is set to 1 bar using a Monte Carlo (MC) barostat with 500 fs between MC barostat moves.…”

Section: Methodsmentioning

confidence: 99%

“…The peptoid sequences chosen are discussed at the beginning of Section . We use the MFTOID forcefield, which we have previously shown accurately captures the experimentally measured structural distributions of disordered polypeptoids, such as the ones we study here . To prepare the system, we create and geometry-minimize initial peptoid structures in the fully extended conformation using Avogadro 1.2.0 .…”

Section: Materials and Methodsmentioning

confidence: 99%

“…Polypeptoids are highly tunable molecules, as they can be synthesized sequence-specifically via a process that allows access to a wide variety of chemistries. , Previous computational efforts have begun to examine water behavior near polypeptoids in solution and at surfaces, , but have been hampered by slow isomerization timescales (seconds) in polypeptoids that are inaccessible to molecular dynamics simulation. Here, we leverage a computational workflow that accurately samples polypeptoid conformational landscapes in solution to probe the effects of the polypeptoid sequence on local water behavior. We first examine the effect of an entirely polar peptoid sequence on hydration water behavior, making comparisons to bulk water (Section ).…”

Section: Introductionmentioning

confidence: 99%

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Sequence Modulates Polypeptoid Hydration Water Structure and Dynamics

et al. 2022

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We use molecular dynamics simulations to investigate the effect of polypeptoid sequence on the structure and dynamics of its hydration waters. Polypeptoids provide an excellent platform to study small-molecule hydration in disordered polymers, as they can be precisely synthesized with a variety of sidechain chemistries. We examine water behavior near a set of peptoid oligomers in which the number and placement of nonpolar versus polar sidechains are systematically varied.To do this, we leverage a new computational workflow enabling accurate sampling of polypeptoid conformations. We find that the hydration waters are less dense, are more tetrahedral, and have slower dynamics compared to bulk water. The magnitude of these shifts increases with the number of nonpolar groups. We also find that shifts in the water structure and dynamics are strongly correlated, suggesting that experimental insight into the dynamics of hydration water obtained by Overhauser dynamic nuclear polarization (ODNP) also contains information about water structural properties. We then demonstrate the ability of ODNP to probe site-specific dynamics of hydration water near these model peptoid systems.

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Section: Methodsmentioning

confidence: 99%

Section: Materials and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sequence Modulates Polypeptoid Hydration Water Structure and Dynamics

et al. 2022

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“…In this example, double electron–electron resonance (DEER) probes distributions of end-to-end distances of polypeptoids with different numbers of repeat units. Reproduced from ref ( 84 ). Copyright 2021 American Chemical Society.…”

Section: Characterization Across Time and Spacementioning

confidence: 99%

“…Potential approaches for achieving detailed sequence-structure insights include borrowing methods from biophysics that allow probes to be installed in specific sites along a polymer chain that can then leverage, for example, nuclear magnetic resonance (NMR), , fluorescence methods, or electron paramagnetic resonance (EPR) , to probe distributions of distances in polymer chains (Figure a). Of these methods, 2D NMR is unique in that it can determine the structure of small proteins without the use of labels, but extension to longer molecules is made challenging by loss of resolution and increasingly convoluted spectra.…”

Section: Characterization Across Time and Spacementioning

confidence: 99%

Where Biology and Traditional Polymers Meet: The Potential of Associating Sequence-Defined Polymers for Materials Science

DeStefano

Segalman

Davidson

2021

JACS Au

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Polymers with precisely defined monomeric sequences present an exquisite tool for controlling material properties by harnessing both the robustness of synthetic polymers and the ability to tailor the inter- and intramolecular interactions so crucial to many biological materials. While polymer scientists traditionally synthesized and studied the physics of long molecules best described by their statistical nature, many biological polymers derive their highly tailored functions from precisely controlled sequences. Therefore, significant effort has been applied toward developing new methods of synthesizing, characterizing, and understanding the physics of non-natural sequence-defined polymers. This perspective considers the synergistic advantages that can be achieved via tailoring both precise sequence control and attributes of traditional polymers in a single system. Here, we focus on the potential of sequence-defined polymers in highly associating systems, with a focus on the unique properties, such as enhanced proton conductivity, that can be attained by incorporating sequence. In particular, we examine these materials as key model systems for studying previously unresolvable questions in polymer physics including the role of chain shape near interfaces and how to tailor compatibilization between dissimilar polymer blocks. Finally, we discuss the critical challenges—in particular, truly scalable synthetic approaches, characterization and modeling tools, and robust control and understanding of assembly pathways—that must be overcome for sequence-defined polymers to attain their potential and achieve ubiquity.

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Coil–Helix Block Copolymers Can Exhibit Divergent Thermodynamics in the Disordered Phase

Grant,

Fingler,

Buchanan

et al. 2023

J. Chem. Theory Comput.

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Chiral building blocks have the ability to selfassemble and transfer chirality to larger hierarchical length scales, which can be leveraged for the development of novel nanomaterials. Chiral block copolymers, where one block is made completely chiral, are prime candidates for studying this phenomenon, but fundamental questions regarding the self-assembly are still unanswered. For one, experimental studies using different chemistries have shown unexplained diverging shifts in the order−disorder transition temperature. In this study, particlebased molecular simulations of chiral block copolymers in the disordered melt were performed to uncover the thermodynamic behavior of these systems. A wide range of helical models were selected, and several free energy calculations were performed. Specifically, we aimed to understand (1) the thermodynamic impact of changing the conformation of one block in chemically identical block copolymers and (2) the effect of the conformation on the Flory−Huggins interaction parameter, χ, when chemical disparity was introduced. We found that the effective block repulsion exhibits diverging behavior, depending on the specific conformational details of the helical block. Commonly used conformational metrics for flexible or stiff block copolymers do not capture the effective block repulsion because helical blocks are semiflexible and aspherical. Instead, pitch can quantitatively capture the effective block repulsion. Quite remarkably, the shift in χ for chemically dissimilar block copolymers can switch sign with small changes in the pitch of the helix.

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Quantifying Polypeptoid Conformational Landscapes through Integrated Experiment and Simulation

Cited by 13 publications

References 92 publications

Sequence Modulates Polypeptoid Hydration Water Structure and Dynamics

Sequence Modulates Polypeptoid Hydration Water Structure and Dynamics

Where Biology and Traditional Polymers Meet: The Potential of Associating Sequence-Defined Polymers for Materials Science

Coil–Helix Block Copolymers Can Exhibit Divergent Thermodynamics in the Disordered Phase

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