Naturally derived cell-penetrating peptides and applications in gene regulation A study on internalization mechanisms and endosomal escape

Though much is taken, much abides; and though We are not now that strength which in old days Moved earth and heaven; that which we are, we are; One equal temper of heroic hearts, Made weak by time and fate, but strong in will To strive, to seek, to find, and not to yield Uptake mechanism of novel cell-penetrating peptides derived from the Alzheimer's disease associated gamma-secretase complex Int. Two novel targeting peptide degrading proteases (PrePs) in mitochon-dria and chloroplast: so similar and still different Prediction of cell-penetrating peptides Int. Abstract Abstract Cell-penetrating peptides are a class of peptides which have achieved a lot of recognition due to their vector abilities. Since their discovery over a decade ago, there has been an uncertainty concerning the mechanism by which they are internalized into the cells. Early studies claimed the uptake to be receptor and energy independent, whereas more recent studies have shifted the general view to a more endocytotic belief, without prior binding to a receptor. As an increasing amount of reports emerges claiming the uptake to be endocytic, there is still a discrepancy concerning which endocytic mechanism that is responsible for the internalization and how to exploit the endo-cytic machinery for improved delivery. The main aim of this thesis was to elucidate the internalization mechanism for a series of cell-penetrating peptides derived from naturally occurring proteins, such as the prion protein which is thought to be the infectious particle in prion disorders. Furthermore, applications in gene regulation and improvement of delivery efficacy by induction of endosomolysis were examined. The results obtained confirm the uptake of cell-penetrating peptides to be endocytic; however the internalization mechanism appears to be peptide dependent where macropinocytosis is the most widespread endocytic component responsible for the internalization. The results further demonstrate that the biological response can be increased manifold by the induction of endosomolysis, either by using lysosomotropic agents or peptides able to alter their secondary structure upon protonation with concomitant endoso-molysis. Altogether the results prove that enhanced delivery using cell-penetrating peptides can be achieved by exploiting the intrinsic endocytic mechanisms involved in the translocation process.