peptide nanofibers
Recently Published Documents

Considerable number of works have reported alkaline phosphatase (ALP) enabled intracellular targeting by peptide assemblies, but little is known how these substrates of ALP enters cells. Here we show that the nanoscale assemblies of phosphopeptides, as a dynamic continuum, cluster ALP to enable caveolae mediated endocytosis (CME) and eventual endosomal escape. Specifically, fluorescent phosphopeptides, as substrates of tissue nonspecific alkaline phosphatase (TNAP), undergo enzyme catalyzed self-assembly to form nanofibers. As shown by live cell imaging, the nanoparticles of phosphopeptides, being incubated with HEK293 cells overexpressing red fluorescent protein-tagged TNAP (TNAP-RFP), cluster TNAP-RFP in lipid rafts to enable CME, further dephosphorylation of the phosphopeptides form the peptide nanofibers for endosomal escape inside cells. Inhibiting TNAP, cleaving the membrane anchored TNAP, or disrupting lipid rafts abolishes the endocytosis. Moreover, decreasing the formation of peptide nanofibers prevents the endosomal escape. As the first study establishing a dynamic continuum of supramolecular assemblies for cellular uptake, this work not only illustrates an effective design for enzyme responsive supramolecular therapeutics, but also provides mechanism insights for understanding the dynamics of cellular uptakes of proteins or exogenous peptide aggregates at nanoscale.

Injectable hydrogels are attractive for therapeutic delivery because they can be locally administered through minimally-invasive routes. Charge-complementary peptide nanofibers provide hydrogels that are suitable for encapsulation of biotherapeutics, such as...

Extremely long flexible self-assembling peptide nanofibers can be manipulated to form various two-dimensional patterns.

Pathological stimuli-responsive self-assembly of peptide nanofibers enables selective accumulation of imaging agent cargos in the stimuli-rich regions of interest. It provides enhanced imaging signals, biocompatibility, and tumor/disease accessibility and retention,...

Self-assembled nanofibers hold tremendous promise for cancer theranostics owing to their in situ assembly, spatiotemporal responsiveness, and diverse bioactivity. Herein, this review summarizes recent advances of self-assembled peptide nanofibers and...

Self-assembled peptide nanofibers (NFs) obtained from β-sheet peptides conjugated with drugs, including antigenic peptides, have recently attracted significant attention. However, extensive studies on the interactions of β-sheet peptide NFs with model cell membranes have not been reported. In this study, we investigated the interactions between three types of NFs, composed of PEG-peptide conjugates with different ethylene glycol (EG) lengths (6-, 12- and 24-mer), and dipalmitoylphosphatidylcholine (DPPC) Langmuir membranes. When increasing the EG chain length, those interactions significantly decreased considering measurements in the presence of the NFs of: (i) changes in surface pressure of the DPPC Langmuir monolayers and (ii) surface pressure–area (π–A) compression isotherms of DPPC. Because the observed trend was similar to the EG length dependency with regard to cellular association and cytotoxicity of the NFs that was reported previously, the interaction of NFs with phospholipid membranes represented a crucial factor to determine the cellular association and toxicity of the NFs. In contrast to NFs, no changes were observed with varying EG chain length on the interaction of the building block peptide with the DPPC membrane. The results obtained herein can provide a design guideline on the formulation of β-sheet peptide NFs, which may broaden its potential.