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1. Mapping the Morphological Landscape of Oligomeric Di‐block Peptide–Polymer Amphiphiles**

   https://doi.org/10.1002/anie.202115547  

   Allen, Benjamin P.; Wright, Zoe M.; Taylor, Hailey F.; Oweida, Thomas J.; Kader‐Pinky, Sabila; Patteson, Emily F.; Bucci, Kara M.; Cox, Caleb A.; Senthilvel, Abishec Sundar; Yingling, Yaroslava G.; et al (January 2022, Angewandte Chemie International Edition)

   Abstract Peptide–polymer amphiphiles (PPAs) are tunable hybrid materials that achieve complex assembly landscapes by combining the sequence‐dependent properties of peptides with the structural diversity of polymers. Despite their promise as biomimetic materials, determining how polymer and peptide properties simultaneously affect PPA self‐assembly remains challenging. We herein present a systematic study of PPA structure–assembly relationships. PPAs containing oligo(ethyl acrylate) and random‐coil peptides were used to determine the role of oligomer molecular weight, dispersity, peptide length, and charge density on self‐assembly. We observed that PPAs predominantly formed spheres rather than anisotropic particles. Oligomer molecular weight and peptide hydrophilicity dictated morphology, while dispersity and peptide charge affected particle size. These key benchmarks will facilitate the rational design of PPAs that expand the scope of biomimetic functionality within assembled soft materials. 

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2. Patchy metal nanoparticles with polymers: controllable growth and two-way self-assembly

   https://doi.org/10.1039/D2NR01221A  

   Duan, Hanyi; Malesky, Tessa; Wang, Janet; Liu, Chung-Hao; Tan, Haiyan; Nieh, Mu-Ping; Lin, Yao; He, Jie (May 2022, Nanoscale)

   We report a new design of polymer-patched gold nanoparticles (AuNPs) with controllable interparticle interactions in terms of their direction and strength. Patchy AuNPs (pAuNPs) are prepared through hydrophobicity-driven surface dewetting under deficient ligand exchange conditions. Using the exposed surface on pAuNPs as seeds, a highly controllable growth of AuNPs is carried out via seed-mediated growth while retaining the size of polymer domains. As guided by ligands, these pAuNPs can self-assemble directionally in two ways along the exposed surface (head-to-head) or the polymer-patched surface of pAuNPs (tail-to-tail). Control of the surface asymmetry/coverage on pAuNPs provides an important tool in balancing interparticle interactions (attraction vs. repulsion) that further tunes assembled nanostructures as clusters and nanochains. The self-assembly pathway plays a key role in determining the interparticle distance and therefore plasmon coupling of pAuNPs. Our results demonstrate a new paradigm in the directional self-assembly of anisotropic building blocks for hierarchical nanomaterials with interesting optical properties. 

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3. Iterative Design Reveals Molecular Domain Relationships in Supramolecular Peptide–Drug Conjugates

   https://doi.org/10.1021/acs.biomac.4c00519  

   Sis, Matthew J; Liu, Dongping; Allen, Isabella; Webber, Matthew J (July 2024, Biomacromolecules)

   Supramolecular peptide-drug conjugates (sPDCs) are prepared by covalent attachment of a drug moiety to a peptide motif programmed for one-dimensional self-assembly, with subsequent physical entanglement of these fibrillar structures enabling formation of nanofibrous hydrogels. This class of prodrug materials presents an attractive platform for mass-efficient and site-specific delivery of therapeutic agents using a discrete single-component molecular design. However, a continued challenge in sPDC development is elucidating relationships between supramolecular interactions in their drug and peptide domains and the resultant impact of these domains on assembly outcomes and material properties. Inclusion of a saturated alkyl segment alongside the prodrug in the hydrophobic domain of sPDCs could relieve some of the necessity for ordered, prodrug-produg interactions. Accordingly, nine sPDCs are prepared here to iterate the design variables of amino acid sequence and hydrophobic prodrug/alkyl block design. All molecules spontaneously formed hydrogels under physiological conditions, indicating a less hindered thermodynamic path to self-assembly relative to previous prodrug-only designs. However, material studies on the supramolecular arrangement, formation, and mechanical properties of the resultant sPDC hydrogels, as well as their drug release profiles, showed complex relationships between the hydrophobic and peptide domains in the formation and function of the resulting assemblies. Together, these results indicate that sPDC material properties are intrinsically linked to holistic molecular design, with coupled contributions from their prodrug and peptide domains in directing properties of the emergent materials. 

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4. Pathways of amyloid-beta absorption and aggregation in a membranous environment

   https://doi.org/10.1039/C9CP00040B  

   Sahoo, Abhilash; Xu, Hongcheng; Matysiak, Silvina (April 2019, Physical Chemistry Chemical Physics)

   Aggregation of misfolded oligomeric amyloid-beta (Aβ) peptides on lipid membranes has been identified as a primary event in Alzheimer's pathogenesis. However, the structural and dynamical features of this membrane assisted Aβ aggregation have not been well characterized. The microscopic characterization of dynamic molecular-level interactions in peptide aggregation pathways has been challenging both computationally and experimentally. In this work, we explore differential patterns of membrane-induced Aβ 16–22 (K–L–V–F–F–A–E) aggregation from the microscopic perspective of molecular interactions. Physics-based coarse-grained molecular dynamics (CG-MD) simulations were employed to investigate the effect of lipid headgroup charge – zwitterionic (1-palmitoyl-2-oleoyl- sn-glycero -3-phosphocholine: POPC) and anionic (1-palmitoyl-2-oleoyl- sn-glycero -3-phospho- l -serine: POPS) – on Aβ 16–22 peptide aggregation. Our analyses present an extensive overview of multiple pathways for peptide absorption and biomechanical forces governing peptide folding and aggregation. In agreement with experimental observations, anionic POPS molecules promote extended configurations in Aβ peptides that contribute towards faster emergence of ordered β-sheet-rich peptide assemblies compared to POPC, suggesting faster fibrillation. In addition, lower cumulative rates of peptide aggregation in POPS due to higher peptide–lipid interactions and slower lipid diffusion result in multiple distinct ordered peptide aggregates that can serve as nucleation seeds for subsequent Aβ aggregation. This study provides an in-silico assessment of experimentally observed aggregation patterns, presents new morphological insights and highlights the importance of lipid headgroup chemistry in modulating the peptide absorption and aggregation process. 

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5. In Silico Design and Analysis of Plastic-Binding Peptides

   https://doi.org/10.1021/acs.jpcb.3c04319  

   Bergman, Michael T; Xiao, Xingqing; Hall, Carol K (October 2023, The Journal of Physical Chemistry B)

   Shea, Joan-Emma (Ed.)

   Peptides that bind to inorganic materials can be used to functionalize surfaces, control crystallization, or assist ininterfacial self-assembly. In the past, inorganic-binding peptides have been found predominantly through peptide library screening. While this method has successfully identified peptides that bind to a variety of materials, an alternative design approach that can intelligently search for peptides and provide physical insight for peptide affinity would be desirable. In this work, we develop a computational, physics-based approach to design inorganic-binding peptides, focusing on peptides that bind to the common plastics polyethylene, polypropylene, polystyrene, and poly(ethylene terephthalate). The PepBD algorithm, a Monte Carlo method that samples peptide sequence and conformational space, was modified to include simulated annealing, relax hydration constraints, and an ensemble of conformations to initiate design. These modifications led to the discovery of peptides with significantly better scores compared to those obtained using the original PepBD. PepBD scores were found to improve with increasing van der Waals interactions, although strengthening the intermolecular van der Waals interactions comes at the cost of introducing unfavorable electrostatic interactions. The best designs are enriched in amino acids with bulky side chains and possess hydrophobic and hydrophilic patches whose location depends on the adsorbed conformation. Future work will evaluate the top peptide designs in molecular dynamics simulations and experiment, enabling their application in microplastic pollution remediation and plastic-based biosensors. 

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