Efficient degradation-aided selection of protease inhibitors by phage display.

In this report, we describe a novel phage display strategy for the identification of dedicated protease inhibiting peptides, based on degradation-aided enrichment of protease resistant phages. Phages were directly incubated with a range of phage-degrading proteases, after which non-degraded phages were used for the next selection round. For proteinase-K we identified after only four selection rounds a peptide (VLIMPVLLGIPLLC) that inhibits proteinase-K activity with an inhibition constant of 4 microM. In analogy, we identified a peptide capable of inhibiting substrate degradation by cathepsin-S (VWNCERITISRLIN), which showed functional inhibition of cathepsin-S induced sprouting of endothelial cells. We envision that the pursued strategy of degradation-aided selection of protease inhibitors (DASPI) represents an effective approach in the design of new protease inhibitors but also of new strategies to render gene and drug vectors protease resistant.

A targeted peptide nucleic acid to down-regulate mouse microsomal triglyceride transfer protein expression in hepatocytes.

Peptide nucleic acids (PNA's) have shown to hold potential as antisense drugs. In this study we have designed PNA drugs for the microsomal triglyceride transfer protein (MTP), which is known to play a critical role in the assembly of atherogenic lipoproteins, and have converted the most potent drug into a liver-targeted prodrug. First, we have synthesized three PNA sequences targeting domains on the mouse MTP mRNA, which were not involved in intrastrand base-pairing interactions as jugded from its secondary structure. Only one of the PNA's, PNA569, showed dose-dependent inhibition of MTP expression in a cell-free system for coupled transcription/translation of MTP. Second, to improve the cellular uptake of this PNA drug, we have conjugated PNA569 to a high affinity ligand for the asialoglycoprotein receptor, K(GalNAc)(2). As compared to the parent PNA, the prodrug PNA-K(GalNAc)(2) was found to display to a markedly improved capacity to inhibit MTP mRNA expression in parenchymal liver cells. A glycoconjugated nonsense control appeared to be ineffective. In conclusion, the design of a targeted PNA is described to reduce MTP expression in parenchymal liver cells by 70%. The presented approach for targeted tissue-specific down-regulation of genes by PNA's may be valid for other genes as well.

Improvement of hepatocyte-specific gene expression by a targeted colchicine prodrug.

Colchicine, an established tubulin inhibitor, interferes with the trafficking of endocytotic vesicles and thereby promotes the escape of lysosome-entrapped compounds. To improve its potency and cell specificity, a targeted prodrug of colchicine was synthesized by conjugation to a high-affinity ligand (di-N(alpha),N(epsilon)-(5-(2-acetamido-2-deoxy-beta-D-galactopyranosyloxy)pentanomido)lysine, K(GalNAc)(2)) for the asialoglycoprotein receptor on parenchymal liver cells. The resulting colchicine-K(GalNAc)(2) conjugate bound to this receptor with an affinity of 4.5 nM. Confocal microscopy studies confirmed rapid uptake and receptor dependency of a prodrug conjugated with fluorescein isothiocyanate. Colchicine-K(GalNAc)(2) substantially increased the transfection efficiency of polyplexed DNA in parenchymal liver cells in a concentration- and receptor-dependent fashion. Colchicine-K(GalNAc)(2) was found to enhance the transfection efficiency by 50-fold at 1 nM, whereas the parental colchicine was ineffective. In conclusion, this nontoxic colchicine-K(GalNAc)(2) conjugate can be a useful tool to improve the transfection efficiency of hepatic nonviral gene transfer vehicles.

Targeted lysosome disruptive elements for improvement of parenchymal liver cell-specific gene delivery.

The transfection ability of nonviral gene therapy vehicles is generally hampered by untimely lysosomal degradation of internalized DNA. In this study we describe the development of a targeted lysosome disruptive element to facilitate the escape of DNA from the lysosomal compartment, thus enhancing the transfection efficacy, in a cell-specific fashion. Two peptides (INF7 and JTS-1) were tested for their capacity to disrupt liposomes. In contrast to JTS-1, INF7 induced rapid cholesterol-independent leakage (EC(50), 1.3 microm). INF7 was therefore selected for coupling to a high affinity ligand for the asialoglycoprotein receptor (ASGPr), K(GalNAc)(2), to im- prove its uptake by parenchymal liver cells. Although the parent peptide disrupted both cholesterol-rich and -poor liposomes, the conjugate, INF7-K(GalNAc)(2), only induced leakage of cholesterol-poor liposomes. Given that endosomal membranes of eukaryotic cells contain <5% cholesterol, this implies that the conjugate will display a higher selectivity toward endosomal membranes. Although both INF7 and INF7-K(GalNAc)(2) were found to increase the transfection efficiency on polyplex-mediated gene transfer to parenchymal liver cells by 30-fold, only INF7-K(GalNAc)(2) appeared to do so in an ASGPr-specific manner. In mice, INF7-K(GalNAc)(2) was specifically targeted to the liver, whereas INF7 was distributed evenly over various organs. In summary, we have prepared a nontoxic cell-specific lysosome disruptive element that improves gene delivery to parenchymal liver cells via the ASGPr. Its high cell specificity and preference to lyse intracellular membranes make this conjugate a promising lead in hepatocyte-specific drug/gene delivery protocols.