Peptide vectors for the nonviral delivery of nucleic acids.

Over the past two decades, gene therapy has garnered tremendous attention and is heralded by many as the ultimate cure to treat diseases such as cancer, viral infections, and inherited genetic disorders. However, the therapeutic applications of nucleic acids extend beyond the delivery of double-stranded DNA and subsequent expression of deficient gene products in diseased tissue. Other strategies include antisense oligonucleotides and most notably RNA interference (RNAi). Antisense strategies bear great potential for the treatment of diseases that are caused by misspliced mRNA, and RNAi is a universal and extraordinarily efficient tool to knock down the expression of virtually any gene by specific degradation of the desired target mRNA. However, because of the hurdles associated with effective delivery of nucleic acids across a cell membrane, the initial euphoria surrounding siRNA therapy soon subsided. The ability of oligonucleotides to cross the plasma membrane is hampered by their size and highly negative charge. Viral vectors have long been the gold standard to overcome this barrier, but they are associated with severe immunogenic effects and possible tumorigenesis. Cell-penetrating peptides (CPPs), cationic peptides that can translocate through the cell membrane independent of receptors and can transport cargo including proteins, small organic molecules, nanoparticles, and oligonucleotides, represent a promising class of nonviral delivery vectors. This Account focuses on peptide carrier systems for the cellular delivery of various types of therapeutic nucleic acids with a special emphasis on cell-penetrating peptides. We also emphasize the clinical relevance of this research through examples of promising in vivo studies. Although CPPs are often derived from naturally occurring protein transduction domains, they can also be artificially designed. Because CPPs typically include many positively charged amino acids, those electrostatic interactions facilitate the formation of complexes between the carriers and the oligonucleotides. One drawback of CPP-mediated delivery includes entrapment of the cargo in endosomes because uptake tends to be endocytic: coupling of fatty acids or endosome-disruptive peptides to the CPPs can overcome this problem. CPPs can also lack specificity for a single cell type, which can be addressed through the use of targeting moieties, such as peptide ligands that bind to specific receptors. Researchers have also applied these strategies to cationic carrier systems for nonviral oligonucleotide delivery, such as liposomes or polymers, but CPPs tend to be less cytotoxic than other delivery vehicles.

[1]  P. Camelliti,et al.  Pip5 transduction peptides direct high efficiency oligonucleotide-mediated dystrophin exon skipping in heart and phenotypic correction in mdx mice. , 2011, Molecular therapy : the journal of the American Society of Gene Therapy.

[2]  A. Moore,et al.  siRNA delivery to CNS cells using a membrane translocation peptide. , 2010, Bioconjugate chemistry.

[3]  D. Maclean,et al.  Therapeutic applications of cell-penetrating peptides. , 2011, Methods in molecular biology.

[4]  S. Wilton,et al.  Splicing intervention for Duchenne muscular dystrophy. , 2005, Current opinion in pharmacology.

[5]  Beverly L. Davidson,et al.  Current prospects for RNA interference-based therapies , 2011, Nature Reviews Genetics.

[6]  P. Lundin,et al.  Application of PepFect peptides for the delivery of splice-correcting oligonucleotides. , 2011, Methods in molecular biology.

[7]  Alain Pluen,et al.  Delivery of therapeutic shRNA and siRNA by Tat fusion peptide targeting BCR-ABL fusion gene in Chronic Myeloid Leukemia cells. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[8]  Young Jik Kwon,et al.  Efficient and targeted delivery of siRNA in vivo , 2010, The FEBS journal.

[9]  Roger Y Tsien,et al.  In vivo characterization of activatable cell penetrating peptides for targeting protease activity in cancer. , 2009, Integrative biology : quantitative biosciences from nano to macro.

[10]  K. Anderson,et al.  Synthesis and in vitro testing of new potent polyacridine-melittin gene delivery peptides. , 2010, Bioconjugate chemistry.

[11]  Ű. Langel,et al.  Delivery of nucleic acids with a stearylated (RxR)4 peptide using a non-covalent co-incubation strategy. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[12]  H. Tseng,et al.  Selective inhibition of human brain tumor cells through multifunctional quantum-dot-based siRNA delivery. , 2010, Angewandte Chemie.

[13]  P. Lundin,et al.  Distinct uptake routes of cell-penetrating peptide conjugates. , 2008, Bioconjugate chemistry.

[14]  G. Kibria,et al.  Dual-ligand modification of PEGylated liposomes shows better cell selectivity and efficient gene delivery. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[15]  Jun Li,et al.  Low molecular weight polyethylenimine cross-linked by 2-hydroxypropyl-gamma-cyclodextrin coupled to peptide targeting HER2 as a gene delivery vector. , 2010, Biomaterials.

[16]  U. Haberkorn,et al.  The pharmacokinetics of cell-penetrating peptides. , 2010, Molecular pharmaceutics.

[17]  C. Berkland,et al.  Calcium condensed LABL-TAT complexes effectively target gene delivery to ICAM-1 expressing cells. , 2011, Molecular pharmaceutics.

[18]  T. Niidome,et al.  Transgene regulation system responding to Rho associated coiled-coil kinase (ROCK) activation. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[19]  H Harashima,et al.  Stearylated arginine-rich peptides: a new class of transfection systems. , 2001, Bioconjugate chemistry.

[20]  M. Wood,et al.  Delivery of siRNA to the mouse brain by systemic injection of targeted exosomes , 2011, Nature Biotechnology.

[21]  Ű. Langel,et al.  Cargo-dependent cytotoxicity and delivery efficacy of cell-penetrating peptides: a comparative study. , 2007, The Biochemical journal.

[22]  P. Iversen,et al.  Arginine-rich cell-penetrating peptide dramatically enhances AMO-mediated ATM aberrant splicing correction and enables delivery to brain and cerebellum. , 2011, Human molecular genetics.

[23]  Ű. Langel,et al.  Insights into the cellular trafficking of splice redirecting oligonucleotides complexed with chemically modified cell-penetrating peptides. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[24]  P. Nielsen,et al.  Calcium ions effectively enhance the effect of antisense peptide nucleic acids conjugated to cationic tat and oligoarginine peptides. , 2005, Chemistry & biology.

[25]  S. Hart,et al.  Receptor-targeted liposome-peptide nanocomplexes for siRNA delivery. , 2011, Biomaterials.

[26]  Astrid Gräslund,et al.  Mechanisms of Cellular Uptake of Cell-Penetrating Peptides , 2011, Journal of biophysics.

[27]  F. Szoka,et al.  GALA: a designed synthetic pH-responsive amphipathic peptide with applications in drug and gene delivery. , 2004, Advanced drug delivery reviews.

[28]  D. Scherman,et al.  Design and Evaluation of Histidine-Rich Amphipathic Peptides for siRNA Delivery , 2010, Pharmaceutical Research.

[29]  Munia Ganguli,et al.  Exogenous and Cell Surface Glycosaminoglycans Alter DNA Delivery Efficiency of Arginine and Lysine Homopeptides in Distinctly Different Ways* , 2011, The Journal of Biological Chemistry.

[30]  K. Lu,et al.  Chemical strategies for the synthesis of peptide-oligonucleotide conjugates. , 2010, Bioconjugate chemistry.

[31]  Ű. Langel,et al.  Novel Fatty Acid Modifications of Transportan 10 , 2010, International Journal of Peptide Research and Therapeutics.

[32]  N. Senzer,et al.  Systemic therapeutic gene delivery for cancer: crafting Paris' arrow. , 2009, Current gene therapy.

[33]  Fanyu Meng,et al.  Effective siRNA delivery and target mRNA degradation using an amphipathic peptide to facilitate pH-dependent endosomal escape. , 2011, The Biochemical journal.

[34]  Y. Sunada,et al.  Plasmid DNA gene therapy by electroporation: principles and recent advances. , 2011, Current gene therapy.

[35]  T. Anchordoquy,et al.  Drug delivery trends in clinical trials and translational medicine: challenges and opportunities in the delivery of nucleic acid-based therapeutics. , 2011, Journal of pharmaceutical sciences.

[36]  A. F. Saleh,et al.  Improved Tat-mediated plasmid DNA transfer by fusion to LK15 peptide. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[37]  M. Pooga,et al.  NickFects, Phosphorylated Derivatives of Transportan 10 for Cellular Delivery of Oligonucleotides , 2011, International Journal of Peptide Research and Therapeutics.

[38]  A. Metspalu,et al.  Design of a peptide-based vector, PepFect6, for efficient delivery of siRNA in cell culture and systemically in vivo , 2011, Nucleic acids research.

[39]  R. Brock,et al.  Biological responses towards cationic peptides and drug carriers. , 2011, Trends in pharmacological sciences.

[40]  S. Pun,et al.  A truncated HGP peptide sequence that retains endosomolytic activity and improves gene delivery efficiencies. , 2010, Molecular pharmaceutics.

[41]  S. Futaki,et al.  Endosomal escape and the knockdown efficiency of liposomal-siRNA by the fusogenic peptide shGALA. , 2011, Biomaterials.

[42]  L. Gentilucci,et al.  Chemical modifications designed to improve peptide stability: incorporation of non-natural amino acids, pseudo-peptide bonds, and cyclization. , 2010, Current pharmaceutical design.

[43]  J. L. Santos,et al.  Gene delivery into mesenchymal stem cells: a biomimetic approach using RGD nanoclusters based on poly(amidoamine) dendrimers. , 2011, Biomacromolecules.

[44]  P. Nielsen,et al.  Improved cellular activity of antisense peptide nucleic acids by conjugation to a cationic peptide-lipid (CatLip) domain. , 2008, Bioconjugate chemistry.

[45]  M. Ogris,et al.  Synthesis and biological evaluation of a bioresponsive and endosomolytic siRNA-polymer conjugate. , 2009, Molecular pharmaceutics.

[46]  Annick Thomas,et al.  Insight into the cellular uptake mechanism of a secondary amphipathic cell-penetrating peptide for siRNA delivery. , 2010, Biochemistry.

[47]  P. Shankar,et al.  Silencing Early Viral Replication in Macrophages and Dendritic Cells Effectively Suppresses Flavivirus Encephalitis , 2011, PloS one.

[48]  Carl O. Pabo,et al.  Cellular uptake of the tat protein from human immunodeficiency virus , 1988, Cell.

[49]  C. I. Smith,et al.  PepFect 14, a novel cell-penetrating peptide for oligonucleotide delivery in solution and as solid formulation , 2011, Nucleic acids research.

[50]  M. Pooga,et al.  Cell penetration by transportan. , 1998, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[51]  B. Lebleu,et al.  A non-covalent strategy combining cationic lipids and CPPs to enhance the delivery of splice correcting oligonucleotides. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[52]  L. Billingham,et al.  Phase I/II trial of a dendritic cell vaccine transfected with DNA encoding melan A and gp100 for patients with metastatic melanoma , 2011, Gene Therapy.

[53]  Sang-Hyun Min,et al.  Gene delivery using a derivative of the protein transduction domain peptide, K-Antp. , 2010, Biomaterials.

[54]  Afsaneh Lavasanifar,et al.  Traceable multifunctional micellar nanocarriers for cancer-targeted co-delivery of MDR-1 siRNA and doxorubicin. , 2011, ACS nano.

[55]  Cellular uptake of the tat protein from human immunodeficiency virus. , 1990, Disease markers.

[56]  Xiaoyuan Chen,et al.  Intracellular delivery of an antisense oligonucleotide via endocytosis of a G protein-coupled receptor , 2010, Nucleic acids research.