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1. Molecular complementarity and structural heterogeneity within co-assembled peptide β-sheet nanofibers

   https://doi.org/10.1039/c9nr08725g  

   Wong, Kong M. ; Wang, Yiming ; Seroski, Dillon T. ; Larkin, Grant E. ; Mehta, Anil K. ; Hudalla, Gregory A. ; Hall, Carol K. ; Paravastu, Anant K. ( February 2020 , Nanoscale)

   null (Ed.)

   Self-assembling peptides have garnered an increasing amount of interest as a functional biomaterial for medical and biotechnological applications. Recently, β-sheet peptide designs utilizing complementary pairs of peptides composed of charged amino acids positioned to impart co-assembly behavior have expanded the portfolio of peptide aggregate structures. Structural characterization of these charge-complementary peptide co-assemblies has been limited. Thus, it is not known how the complementary peptides organize on the molecular level. Through a combination of solid-state NMR measurements and discontinuous molecular dynamics simulations, we investigate the molecular organization of King–Webb peptide nanofibers. KW+ and KW− peptides co-assemble into near stoichiometric two-component β-sheet structures as observed by computational simulations and 13 C– 13 C dipolar couplings. A majority of β-strands are aligned with antiparallel nearest neighbors within the β-sheet as previously suggested by Fourier transform infrared spectroscopy measurements. Surprisingly, however, a significant proportion of β-strand neighbors are parallel. While charge-complementary peptides were previously assumed to organize in an ideal (AB) n pattern, dipolar recoupling measurements on isotopically diluted nanofiber samples reveal a non-negligible amount of self-associated (AA and BB) pairs. Furthermore, computational simulations predict these different structures can coexist within the same nanofiber. Our results highlight structural disorder at the molecular level in a charge-complementary peptide system with implications on co-assembling peptide designs. 

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2. Side‐Chain Chemistry Governs Hierarchical Order of Charge‐Complementary β‐sheet Peptide Coassemblies

   https://doi.org/10.1002/ange.202314531  

   Liu, Renjie ; Dong, Xin ; Seroski, Dillon T. ; Soto Morales, Bethsymarie ; Wong, Kong M. ; Robang, Alicia S. ; Melgar, Lucas ; Angelini, Thomas E. ; Paravastu, Anant K. ; Hall, Carol K. ; et al ( November 2023 , Angewandte Chemie)

   Self‐assembly of proteinaceous biomolecules into functional materials with ordered structures that span length scales is common in nature yet remains a challenge with designer peptides under ambient conditions. This report demonstrates how charged side‐chain chemistry affects the hierarchical co‐assembly of a family of charge‐complementary β‐sheet‐forming peptide pairs known as CATCH(X+/Y−) at physiologic pH and ionic strength in water. In a concentration‐dependent manner, the CATCH(6K+) (Ac‐KQKFKFKFKQK‐Am) and CATCH(6D−) (Ac‐DQDFDFDFDQD‐Am) pair formed either β‐sheet‐rich microspheres or β‐sheet‐rich gels with a micron‐scale plate‐like morphology, which were not observed with other CATCH(X+/Y−) pairs. This hierarchical order was disrupted by replacing D with E, which increased fibril twisting. Replacing K with R, or mutating the N‐ and C‐terminal amino acids in CATCH(6K+) and CATCH(6D−) to Qs, increased observed co‐assembly kinetics, which also disrupted hierarchical order. Due to the ambient assembly conditions, active CATCH(6K+)‐green fluorescent protein fusions could be incorporated into the β‐sheet plates and microspheres formed by the CATCH(6K+/6D−) pair, demonstrating the potential to endow functionality.

    

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3. Side‐Chain Chemistry Governs Hierarchical Order of Charge‐Complementary β‐sheet Peptide Coassemblies

   https://doi.org/10.1002/anie.202314531  

   Liu, Renjie ; Dong, Xin ; Seroski, Dillon T. ; Soto Morales, Bethsymarie ; Wong, Kong M. ; Robang, Alicia S. ; Melgar, Lucas ; Angelini, Thomas E. ; Paravastu, Anant K. ; Hall, Carol K. ; et al ( November 2023 , Angewandte Chemie International Edition)

   Self‐assembly of proteinaceous biomolecules into functional materials with ordered structures that span length scales is common in nature yet remains a challenge with designer peptides under ambient conditions. This report demonstrates how charged side‐chain chemistry affects the hierarchical co‐assembly of a family of charge‐complementary β‐sheet‐forming peptide pairs known as CATCH(X+/Y−) at physiologic pH and ionic strength in water. In a concentration‐dependent manner, the CATCH(6K+) (Ac‐KQKFKFKFKQK‐Am) and CATCH(6D−) (Ac‐DQDFDFDFDQD‐Am) pair formed either β‐sheet‐rich microspheres or β‐sheet‐rich gels with a micron‐scale plate‐like morphology, which were not observed with other CATCH(X+/Y−) pairs. This hierarchical order was disrupted by replacing D with E, which increased fibril twisting. Replacing K with R, or mutating the N‐ and C‐terminal amino acids in CATCH(6K+) and CATCH(6D−) to Qs, increased observed co‐assembly kinetics, which also disrupted hierarchical order. Due to the ambient assembly conditions, active CATCH(6K+)‐green fluorescent protein fusions could be incorporated into the β‐sheet plates and microspheres formed by the CATCH(6K+/6D−) pair, demonstrating the potential to endow functionality.

    

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4. Charge guides pathway selection in β-sheet fibrillizing peptide co-assembly

   https://doi.org/10.1038/s42004-020-00414-w  

   Seroski, Dillon T. ; Dong, Xin ; Wong, Kong M. ; Liu, Renjie ; Shao, Qing ; Paravastu, Anant K. ; Hall, Carol K. ; Hudalla, Gregory A. ( November 2020 , Communications Chemistry)

   Peptide co-assembly is attractive for creating biomaterials with new forms and functions. Emergence of these properties depends on the peptide content of the final assembled structure, which is difficult to predict in multicomponent systems. Here using experiments and simulations we show that charge governs content by affecting propensity for self- and co-association in binary CATCH(+/−) peptide systems. Equimolar mixtures of CATCH(2+/2−), CATCH(4+/4−), and CATCH(6+/6−) formed two-component β-sheets. Solid-state NMR suggested the cationic peptide predominated in the final assemblies. The cationic-to-anionic peptide ratio decreased with increasing charge. CATCH(2+) formed β-sheets when alone, whereas the other peptides remained unassembled. Fibrillization rate increased with peptide charge. The zwitterionic CATCH parent peptide, “Q11”, assembled slowly and only at decreased simulation temperature. These results demonstrate that increasing charge draws complementary peptides together faster, favoring co-assembly, while like-charged molecules repel. We foresee these insights enabling development of co-assembled peptide biomaterials with defined content and predictable properties.

    

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5. Capacity for increased surface area in the hydrophobic core of β ‐sheet peptide bilayer nanoribbons

   https://doi.org/10.1002/psc.3334  

   Jones, Christopher W. ; Morales, Crystal G. ; Eltiste, Sharon L. ; Yanchik‐Slade, Francine E. ; Lee, Naomi R. ; Nilsson, Bradley L. ( June 2021 , Journal of Peptide Science)

   Amphipathic peptides with amino acids arranged in alternating patterns of hydrophobic and hydrophilic residues efficiently self‐assemble intoβ‐sheet bilayer nanoribbons. Hydrophobic side chain functionality is effectively buried in the interior of the putative bilayer of these nanoribbons. This study investigates consequences on self‐assembly of increasing the surface area of aromatic side chain groups that reside in the hydrophobic core of nanoribbons derived from Ac‐(XKXE)₂‐NH₂peptides (X = hydrophobic residue). A series of Ac‐(XKXE)₂‐NH₂peptides incorporating aromatic amino acids of increasing molecular volume and steric profile (X = phenylalanine [Phe], homophenylalanine [Hph], tryptophan [Trp], 1‐naphthylalanine [1‐Nal], 2‐naphthylalanine [2‐Nal], or biphenylalanine [Bip]) were assessed to determine substitution effects on self‐assembly propensity and on morphology of the resulting nanoribbon structures. Additional studies were conducted to determine the effects of incorporating amino acids of differing steric profile in the hydrophobic core (Ac‐X₁KFEFKFE‐NH₂and Ac‐(X_1,5KFE)‐NH₂peptides, X = Trp or Bip). Spectroscopic analysis by circular dichroism (CD) and Fourier transform infrared (FT‐IR) spectroscopy indicatedβ‐sheet formation for all variants. Self‐assembly rate increased with peptide hydrophobicity; increased molecular volume of the hydrophobic side chain groups did not appear to induce kinetic penalties on self‐assembly rates. Transmission electron microscopy (TEM) imaging indicated variation in fibril morphology as a function of amino acid in the X positions. This study confirms that hydrophobicity of amphipathic Ac‐(XKXE)₂‐NH₂peptides correlates to self‐assembly propensity and that the hydrophobic core of the resulting nanoribbon bilayers has a significant capacity to accommodate sterically demanding functional groups. These findings provide insight that may be used to guide the exploitation of self‐assembled amphipathic peptides as functional biomaterials.

    

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