Gudrun Aldrian

Direct Translocation as Major Cellular Uptake for CADY Self-Assembling Peptide-Based Nanoparticles

Cell penetrating peptides constitute a potent approach to overcome the limitations of in vivo siRNA delivery. We recently proposed a peptide-based nanoparticle system, CADY, for efficient delivery of siRNA into numerous cell lines. CADY is a secondary amphipathic peptide that forms stable complexes with siRNA thereby improving both their cellular uptake and biological response. With the aim of understanding the cellular uptake mechanism of CADY:siRNA complexes, we have combined biochemical, confocal and electron microscopy approaches. In the present work, we provide evidence that the major route for CADY:siRNA cellular uptake involves direct translocation through the membrane but not the endosomal pathway. We have demonstrated that CADY:siRNA complexes do not colocalize with most endosomal markers and remain fully active in the presence of inhibitors of the endosomal pathway. Moreover, neither electrostatic interactions with cell surface heparan sulphates nor membrane potential are essential for CADY:siRNA cell entry. In contrast, we have shown that CADY:siRNA complexes clearly induce a transient cell membrane permeabilization, which is rapidly restored by cell membrane fluidity. Therefore, we propose that direct translocation is the major gate for cell entry of CADY:siRNA complexes. Membrane perturbation and uptake are driven mainly by the ability of CADY to interact with phospholipids within the cell membrane, followed by rapid localization of the complex in the cytoplasm, without affecting cell integrity or viability.

Insight into the cellular uptake mechanism of a secondary amphipathic cell-penetrating peptide for siRNA delivery.

Delivery of siRNA remains a major limitation to their clinical application, and several technologies have been proposed to improve their cellular uptake. We recently described a peptide-based nanoparticle system for efficient delivery of siRNA into primary cell lines: CADY. CADY is a secondary amphipathic peptide that forms stable complexes with siRNA and improves their cellular uptake independently of the endosomal pathway. In the present work, we have combined molecular modeling, spectroscopy, and membrane interaction approaches in order to gain further insight into CADY/siRNA particle mechanism of interaction with biological membrane. We demonstrate that CADY forms stable complexes with siRNA and binds phospholipids tightly, mainly through electrostatic interactions. Binding to siRNA or phospholipids triggers a conformational transition of CADY from an unfolded state to an alpha-helical structure, thereby stabilizing CADY/siRNA complexes and improving their interactions with cell membranes. Therefore, we propose that CADY cellular membrane interaction is driven by its structural polymorphism which enables stabilization of both electrostatic and hydrophobic contacts with surface membrane proteoglycan and phospholipids.

Structural polymorphism of non-covalent peptide-based delivery systems: highway to cellular uptake.

During the last two decades, delivery has become a major challenge for the development of new therapeutic molecules for the clinic. Although, several strategies either viral or non viral have been proposed to favor cellular uptake and targeting of therapeutics, only few of them have reach preclinical evaluation. Amongst them, cell-penetrating peptide (CPP) constitutes one of the most promising strategy and has applied for systemic in vivo delivery of a variety of therapeutic molecules. Two CPP-strategies have been described; using peptide carriers either covalently-linked to the cargo or forming non-covalent stable complexes with cargo. Peptide-based nanoparticle delivery system corresponds to small amphipathic peptides able to form stable nanoparticles with either proteins/peptides or nucleic acids and to enter the cell independently of the endosomal pathway. Three families of peptide-based nanoparticle systems; MPG, PEP and CADY have been successfully used for the delivery of various biologically active cargoes both ex vivo and in vivo in several animal models. This review will focus on the mechanism of the peptide-based nanoparticles; PEP, MPG and CADY in a structural and biophysical context. It will also highlight the major parameters associated to particle formation/stabilization and the impact of the carrier structural polymorphism in triggering cellular uptake.

Interactions of Amphipathic CPPs with Model Membranes

Due to the poor permeability of the plasma membrane, several strategies are designed to enhance the transfer of therapeutics into cells. Over the last 20 years, small peptides called Cell-Penetrating Peptides (CPPs) have been widely developed to improve the cellular delivery of biomolecules. These small peptides derive from protein transduction domains, chimerical constructs, or model sequences. Several CPPs are primary or secondary amphipathic peptides, depending on whether the distribution of their hydrophobic and hydrophilic domains occurs from their amino-acid sequence or through α-helical folding. Most of the CPPs are able to deliver different therapeutics such as nucleic acids or proteins in vitro and in vivo. Although their mechanisms of internalization are varied and controversial, the understanding of the intrinsic features of CPPs is essential for future developments. This chapter describes several protocols for the investigation of biophysical properties of amphipathic CPPs. Surface physics approaches are specifically applied to characterize the interactions of amphipathic peptides with model membranes. Circular dichroism and infra-red spectroscopy allow the identification of their structural state. These methods are exemplified by the analyses of the main biophysical features of the cell-penetrating peptides MPG, Pep-1, and CADY.

PEGylation rate influences peptide-based nanoparticles mediated siRNA delivery in vitro and in vivo

Abstract Small interfering RNAs (siRNAs) present a strong therapeutic potential because of their ability to inhibit the expression of any desired protein. Recently, we developed the retro‐inverso amphipathic RICK peptide as novel non‐covalent siRNA carrier. This peptide is able to form nanoparticles (NPs) by self‐assembling with the siRNA resulting in the fully siRNA protection based on its protease resistant peptide sequence. With regard to an in vivo application, we investigated here the influence of the polyethylene glycol (PEG) grafting to RICK NPs on their in vitro and in vivo siRNA delivery properties. A detailed structural study shows that PEGylation did not alter the NP formation (only decrease in zeta potential) regardless of the used PEGylation rates. Compared to the native RICK:siRNA NPs, low PEGylation rates (≤ 20%) of the NPs did not influence their cellular internalization capacity as well as their knock‐down specificity (over‐expressed or endogenous system) in vitro. Because the behavior of PEGylated NPs could differ in their in vivo application, we analyzed the repartition of fluorescent labeled NPs injected at the one‐cell stage in zebrafish embryos as well as their pharmacokinetic (PK) profile after administration to mice. After an intra‐cardiac injection of the PEGylated NPs, we could clearly determine that 20% PEG‐RICK NPs reduce significantly liver and kidney accumulation. NPs with 20% PEGylation constitutes a modular, easy‐to‐handle drug delivery system which could be adapted to other types of functional moieties to develop safe and biocompatible delivery systems for the clinical application of RNAi‐based cancer therapeutics. Graphical abstract Figure. No Caption available.

A retro-inverso cell-penetrating peptide for siRNA delivery

BackgroundSmall interfering RNAs (siRNAs) are powerful tools to control gene expression. However, due to their poor cellular permeability and stability, their therapeutic development requires a specific delivery system. Among them, cell-penetrating peptides (CPP) have been shown to transfer efficiently siRNA inside the cells. Recently we developed amphipathic peptides able to self-assemble with siRNAs as peptide-based nanoparticles and to transfect them into cells. However, despite the great potential of these drug delivery systems, most of them display a low resistance to proteases.ResultsHere, we report the development and characterization of a new CPP named RICK corresponding to the retro-inverso form of the CADY-K peptide. We show that RICK conserves the main biophysical features of its L-parental homologue and keeps the ability to associate with siRNA in stable peptide-based nanoparticles. Moreover the RICK:siRNA self-assembly prevents siRNA degradation and induces inhibition of gene expression.ConclusionsThis new approach consists in a promising strategy for future in vivo application, especially for targeted anticancer treatment (e.g. knock-down of cell cycle proteins).Graphical abstractRICK-based nanoparticles: RICK peptides and siRNA self-assemble in peptide-based nanoparticles to penetrate into the cells and to induce target protein knock-down.

Optimisation of vectorisation property: A comparative study for a secondary amphipathic peptide.

RNA interference provides a powerful technology for specific gene silencing. Therapeutic applications of small interfering RNA (siRNA) however require efficient vehicles for stable complexation and intracellular delivery. In order to enhance their cell delivery, short amphipathic peptides called cell-penetrating peptides (CPPs) have been intensively developed for the last two decades. In this context, the secondary amphipathic peptide CADY has shown to form stable siRNA complexes and to improve their cellular uptake independent of the endosomal pathway. In the present work, we have described the parameters influencing CADY nanoparticle formation (buffers, excipients, presence of serum, etc.), and have followed in details the CPP:siRNA self-assembly. Once optimal conditions were determined, we have compared the ability of seven different CADY analogues to form siRNA-loaded nanoparticles compared to CADY:siRNA. First of all, we were able to show by biophysical methods that structural polymorphism (α-helix) is an important prerequisite for stable nanoparticle formation independently of occurring sequence mutations. Luciferase assays revealed that siRNA complexed to CADY-K (shorter version) shows better knock-down efficiency on Neuro2a-Luc(+) and B16-F10-Luc(+) cells compared to CADY:siRNA. Altogether, CADY-K is an ideal candidate for further application especially with regards to ex vivo or in vivo applications.

Conformational Switching in PolyGln Amyloid Fibrils Resulting from a Single Amino Acid Insertion

The established correlation between neurodegenerative disorders and intracerebral deposition of polyglutamine aggregates motivates attempts to better understand their fibrillar structure. We designed polyglutamines with a few lysines inserted to overcome the hindrance of extreme insolubility and two D-lysines to limit the lengths of β-strands. One is 33 amino acids long (PolyQKd-33) and the other has one fewer glutamine (PolyQKd-32). Both form well-dispersed fibrils suitable for analysis by electron microscopy. Electron diffraction confirmed cross-β structures in both fibrils. Remarkably, the deletion of just one glutamine residue from the middle of the peptide leads to substantially different amyloid structures. PolyQKd-32 fibrils are consistently 10-20% wider than PolyQKd-33, as measured by negative staining, cryo-electron microscopy, and scanning transmission electron microscopy. Scanning transmission electron microscopy analysis revealed that the PolyQKd-32 fibrils have 50% higher mass-per-length than PolyQKd-33. This distinction can be explained by a superpleated β-structure model for PolyQKd-33 and a model with two β-solenoid protofibrils for PolyQKd-32. These data provide evidence for β-arch-containing structures in polyglutamine fibrils and open future possibilities for structure-based drug design.