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1. Bacterial acidity-triggered antimicrobial activity of self-assembling peptide nanofibers

   https://doi.org/10.1039/C9TB00134D  

   Chen, Weike; Li, Shuxin; Renick, Paul; Yang, Su; Pandy, Nikhil; Boutte, Cara; Nguyen, Kytai T.; Tang, Liping; Dong, He (May 2019, Journal of Materials Chemistry B)

   A self-assembling peptide nanofiber was developed to sense the microenvironmental pH change associated with bacterial growth. Using a near-infrared probe, a strong correlation was observed between the local pH reduction of bacterial colonies with the degree of peptide disassembly, which led to their enhanced antimicrobial activity against anaerobic bacteria. 

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2. Modular Design and Self‐assembly of pH‐Responsive Multidomain Peptides Incorporating Non‐natural Ionic Amino Acids

   https://doi.org/10.1002/chem.202403085  

   Asokan‐Sheeja, Haritha; Das, Debdatta; Nguyen, Jenny_N; Nguyen, Na; Van_Khanh_Pham, Tran; Nguyen, Kytai_T; Dong, He (November 2024, Chemistry – A European Journal)

   Abstract Stimuli‐responsive peptides, particularly pH‐responsive variants, hold significant promise in biomedical and technological applications by leveraging the broad pH spectrum inherent to biological environments. However, the limited number of natural pH‐responsive amino acids within biologically relevant pH ranges presents challenges for designing rational pH‐responsive peptide assemblies. In our study, we introduce a novel approach by incorporating a library of non‐natural amino acids featuring chemically diverse tertiary amine side chains. Hydrophobic and ionic properties of these non‐natural amino acids facilitate their incorporation into the assembly domain when uncharged, and electrostatic repulsion promotes disassembly under lower pH conditions. Furthermore, we observed a direct relationship between the number of substitutions and the hydrophobicity of these amino acids, influencing their pH‐responsive properties and enabling rational design based on desired transitional pH ranges. The structure‐activity relationship of these pH‐responsive peptides was evaluated by assessing their antimicrobial properties, as their antimicrobial activity is triggered by the disassembly of peptides to release active monomers. This approach not only enhances the specificity and controllability of pH responsiveness but also broadens the scope of peptide materials in biomedical and technological applications. 

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3. Engineering a nanoantibiotic system displaying dual mechanism of action

   https://doi.org/10.1073/pnas.2321498121  

   Xing, Huihua; de_Campos, Luana Janaína; Pereira, Aramis Jose; Fiora, Maria Mercedes; Aguiar-Alves, Fabio; Tagliazucchi, Mario; Conda-Sheridan, Martin (April 2024, Proceedings of the National Academy of Sciences)

   NA (Ed.)

   In recent decades, peptide amphiphiles (PAs) have established themselves as promising self-assembling bioinspired materials in a wide range of medical fields. Herein, we report a dual-therapeutic system constituted by an antimicrobial PA and a cylindrical protease inhibitor (LJC) to achieve broad antimicrobial spectrum and to enhance therapeutic efficacy. We studied two strategies: PA–LJC nanostructures (Encapsulation) and PA nanostructures + free LJC (Combination). Computational modeling using a molecular theory for amphiphile self-assembly captures and explains the morphology of PA–LJC nanostructures and the location of encapsulated LJC in agreement with transmission electron microscopy and two-dimensional (2D) NMR observations. The morphology and release profile of PA–LJC assemblies are strongly correlated to the PA:LJC ratio: high LJC loading induces an initial burst release. We then evaluated the antimicrobial activity of our nanosystems toward gram-positive and gram-negative bacteria. We found that theCombinationbroadens the spectrum of LJC, reduces the therapeutic concentrations of both agents, and is not impacted by the inoculum effect. Further, theEncapsulationprovides additional benefits including bypassing water solubility limitations of LJC and modulating the release of this molecule. The different properties of PA–LJC nanostructures results in different killing profiles, and reduced cytotoxicity and hemolytic activity. Meanwhile, details in membrane alterations caused by each strategy were revealed by various microscopy and fluorescent techniques. Last, in vivo studies in larvae treated by theEncapsulationstrategy showed better antimicrobial efficacy than polymyxin B. Collectively, this study established a multifunctional platform using a versatile PA to act as an antibiotic, membrane-penetrating assistant, and slow-release delivery vehicle. 

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4. Peptide hydrogel with self-healing and redox-responsive properties

   https://doi.org/10.1186/s40580-022-00309-7  

   D’Souza, Areetha; Marshall, Liam R.; Yoon, Jennifer; Kulesha, Alona; Edirisinghe, Dona I.; Chandrasekaran, Siddarth; Rathee, Parth; Prabhakar, Rajeev; Makhlynets, Olga V. (December 2022, Nano Convergence)

   Abstract We have rationally designed a peptide that assembles into a redox-responsive, antimicrobial metallohydrogel. The resulting self-healing material can be rapidly reduced by ascorbate under physiological conditions and demonstrates a remarkable 160-fold change in hydrogel stiffness upon reduction. We provide a computational model of the hydrogel, explaining why position of nitrogen in non-natural amino acid pyridyl-alanine results in drastically different gelation properties of peptides with metal ions. Given its antimicrobial and rheological properties, the newly designed hydrogel can be used for removable wound dressing application, addressing a major unmet need in clinical care. 

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5. Urea-Modified Self-Assembling Peptide Amphiphiles That Form Well-Defined Nanostructures and Hydrogels for Biomedical Applications

   https://doi.org/10.1021/acsabm.2c00158  

   Xing, Huihua; Rodger, Alison; Comer, Jeffrey; Picco, Agustín S.; Huck-Iriart, Cristián; Ezell, Edward L.; Conda-Sheridan, Martin (June 2022, ACS Applied Bio Materials)

   Hydrogen bonding plays a critical role in the self-assembly of peptide amphiphiles (PAs). Herein, we studied the effect of replacing the amide linkage between the peptide and lipid portions of the PA with a urea group, which possesses an additional hydrogen bond donor. We prepared three PAs with the peptide sequence Phe-Phe-Glu-Glu (FFEE): two are amide-linked with hydrophobic tails of different lengths and the other possesses an alkylated urea group. The differences in the self-assembled structures formed by these PAs were assessed using diverse microscopies, nuclear magnetic resonance (NMR), and dichroism techniques. We found that the urea group influences the morphology and internal arrangement of the assemblies. Molecular dynamics simulations suggest that there are about 50% more hydrogen bonds in nanostructures assembled from the urea-PA than those assembled from the other PAs. Furthermore, in silico studies suggest the presence of urea−π stacking interactions with the phenyl group of Phe, which results in distinct peptide conformations in comparison to the amide-linked PAs. We then studied the effect of the urea modification on the mechanical properties of PA hydrogels. We found that the hydrogel made of the urea-PA exhibits increased stability and self-healing ability. In addition, it allows cell adhesion, spreading, and growth as a matrix. This study reveals that the inclusion of urea bonds might be useful in controlling the morphology, mechanical, and biological properties of self-assembled nanostructures and hydrogels formed by the PAs. 

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