Delivering drug molecules into the cell is one of the major challenges in the process of drug development. In past, cell penetrating peptides have been successfully used for delivering a wide variety of therapeutic molecules into various types of cells for the treatment of multiple diseases. These peptides have unique ability to gain access to the interior of almost any type of cell. Due to the...

Cell penetrating peptides (CPP) are peptides of 10 to 30 residues derived from natural translocating proteins. Multivalency is known to enhance cellular uptake for the Tat peptide and closely related polycationic sequences. To test whether multivalency effects on cellular uptake might also occur with other CPP types, we prepared multivalent versions of the strongly cationic Tat, the amphipathic...

The selective uptake of compounds into specific cells of interest is a major objective in cell biology and drug delivery. By incorporation of a novel, thermostable azobenzene moiety we generated peptides that can be switched optically between an inactive state and an active, cell-penetrating state with excellent spatio-temporal control.

Regulation of biological processes through the use of genetic elements is a central part of biological research and also holds great promise for future therapeutic applications. Oligonucleotides comprise a class of versatile biomolecules capable of modulating gene regulation. Gene therapy, the concept of introducing genetic elements in order to treat disease, presents a promising therapeutic st...

Cell-penetrating peptides (CPPs) provide promising tools for the cellular delivery of molecular cargos ranging in size from small molecules and peptides to proteins and quantum dots. CPPs are typically cationic and/or amphipathic sequences that are unstructured or alpha-helical. We expand the repertoire of cell-penetrating motifs by designing encodable CPPs possessing type-II polyproline (PPII)...

In this work, we will demonstrate a simple yet powerful strategy to assemble single-chain cationic peptides into macromolecular filamentous nanostructures with dramatically improved membrane activity, stability and transfection efficiency.