Nucleic acid delivery by cell penetrating peptides derived from dengue virus capsid protein: design and mechanism of action

Cell penetrating peptides (CPPs) can be used as drug delivery systems for different therapeutic molecules. In this work two novel CPPs, pepR and pepM, designed from two domains of the dengue virus (DENV) capsid protein, were studied for their ability to deliver nucleic acids into cells as non‐covalently bound cargo. Translocation studies were performed by confocal microscopy in HepG2, BHK and HEK cell lineages, astrocytes and peripheral blood mononuclear cells. Combined studies in HepG2 cells, astrocytes and BHK cells, at 4 and 37 °C or using specific endocytosis inhibitors, revealed that pepR and pepM use distinct internalization routes: pepM translocates lipid membranes directly, while pepR uses an endocytic pathway. To confirm these results, a methodology was developed to monitor the translocation kinetics of both peptides by real‐time flow cytometry. Kinetic constants were determined, and the amount of nucleic acids delivered was estimated. Additional studies were performed in order to understand the molecular bases of the peptide‐mediated translocation. Peptide–nucleic acid and peptide–lipid membrane interactions were studied quantitatively based on the intrinsic fluorescence of the peptides. pepR and pepM bound ssDNA to the same extent. Partition studies revealed that both peptides bind preferentially to anionic lipid membranes, adopting an α‐helical conformation. However, fluorescence quenching studies suggest that pepM is deeply inserted into the lipid bilayer, in contrast with pepR. Moreover, only pepM is able to promote the fusion and aggregation of vesicles composed of zwitterionic lipids. Altogether, the results show that DENV capsid protein derived peptides serve as good templates for novel CPP‐based nucleic acid delivery strategies, defining different routes for cell entry.

[1]  D. Andreu,et al.  Kinetic uptake profiles of cell penetrating peptides in lymphocytes and monocytes. , 2013, Biochimica et biophysica acta.

[2]  D. Andreu,et al.  Peptides as models for the structure and function of viral capsid proteins: Insights on dengue virus capsid. , 2013, Biopolymers.

[3]  S. Futaki,et al.  Cell-penetrating peptides (CPPs) as a vector for the delivery of siRNAs into cells. , 2013, Molecular bioSystems.

[4]  D. Andreu,et al.  Quantifying molecular partition of cell‐penetrating peptide–cargo supramolecular complexes into lipid membranes: optimizing peptide‐based drug delivery systems , 2013, Journal of peptide science : an official publication of the European Peptide Society.

[5]  Marco M. Domingues,et al.  Translocating the blood-brain barrier using electrostatics , 2012, Front. Cell. Neurosci..

[6]  F. Milletti,et al.  Cell-penetrating peptides: classes, origin, and current landscape. , 2012, Drug discovery today.

[7]  Juliane Nguyen,et al.  Nucleic acid delivery: the missing pieces of the puzzle? , 2012, Accounts of chemical research.

[8]  Ernst Wagner,et al.  Polymers for siRNA delivery: inspired by viruses to be targeted, dynamic, and precise. , 2012, Accounts of chemical research.

[9]  Astrid Gräslund,et al.  Efficient intracellular delivery of nucleic acid pharmaceuticals using cell-penetrating peptides. , 2012, Accounts of chemical research.

[10]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[11]  Ülo Langel,et al.  Cell-penetrating peptides for the delivery of nucleic acids , 2012, Expert opinion on drug delivery.

[12]  Nir Ben-Tal,et al.  Monte Carlo simulations of peptide–membrane interactions with the MCPep web server† , 2012, Nucleic Acids Res..

[13]  J. Cooper,et al.  Roles for actin assembly in endocytosis. , 2012, Annual review of biochemistry.

[14]  Mark Bradley,et al.  Peptides for cell-selective drug delivery. , 2012, Trends in pharmacological sciences.

[15]  Jan Hoyer,et al.  Peptide vectors for the nonviral delivery of nucleic acids. , 2012, Accounts of chemical research.

[16]  T. McIntosh,et al.  Charge-reversal lipids, peptide-based lipids, and nucleoside-based lipids for gene delivery. , 2012, Accounts of chemical research.

[17]  Gajendra P. S. Raghava,et al.  CPPsite: a curated database of cell penetrating peptides , 2012, Database J. Biol. Databases Curation.

[18]  Caroline Louis-Jeune,et al.  Prediction of protein secondary structure from circular dichroism using theoretically derived spectra , 2012, Proteins.

[19]  Azam Bolhassani,et al.  Potential efficacy of cell-penetrating peptides for nucleic acid and drug delivery in cancer. , 2011, Biochimica et biophysica acta.

[20]  Li Tang,et al.  Translocation of HIV TAT peptide and analogues induced by multiplexed membrane and cytoskeletal interactions , 2011, Proceedings of the National Academy of Sciences.

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

[22]  I. Neundorf,et al.  Antimicrobial peptides with cell-penetrating peptide properties and vice versa , 2011, European Biophysics Journal.

[23]  I. Mäger,et al.  In vivo biodistribution and efficacy of peptide mediated delivery. , 2010, Trends in pharmacological sciences.

[24]  Miguel A R B Castanho,et al.  Drug-lipid interaction evaluation: why a 19th century solution? , 2010, Trends in pharmacological sciences.

[25]  M. X. Fernandes,et al.  Escherichia coli Cell Surface Perturbation and Disruption Induced by Antimicrobial Peptides BP100 and pepR* , 2010, The Journal of Biological Chemistry.

[26]  Yang Zhang,et al.  I-TASSER: a unified platform for automated protein structure and function prediction , 2010, Nature Protocols.

[27]  R. Vandenbroucke,et al.  Title: the Use of Inhibitors to Study Endocytic Pathways of Gene Carriers: Optimisation and Pitfalls the Use of Inhibitors to Study Endocytic Pathways of Gene Carriers: Optimisation and Pitfalls Dries Vercauteren , 2022 .

[28]  G. Núñez,et al.  Clathrin- and Dynamin-Dependent Endocytic Pathway Regulates Muramyl Dipeptide Internalization and NOD2 Activation1 , 2009, The Journal of Immunology.

[29]  M. Morris,et al.  Twenty years of cell-penetrating peptides: from molecular mechanisms to therapeutics , 2009, British journal of pharmacology.

[30]  Manuel N Melo,et al.  Synergistic effects of the membrane actions of cecropin-melittin antimicrobial hybrid peptide BP100. , 2009, Biophysical journal.

[31]  M. C. Cardoso,et al.  Cell Entry of Arginine-rich Peptides Is Independent of Endocytosis*S⃞ , 2009, Journal of Biological Chemistry.

[32]  G. Fields,et al.  Solid phase peptide synthesis utilizing 9-fluorenylmethoxycarbonyl amino acids. , 2009, International journal of peptide and protein research.

[33]  Dominique Douguet,et al.  HELIQUEST: a web server to screen sequences with specific alpha-helical properties , 2008, Bioinform..

[34]  Marco M. Domingues,et al.  What can light scattering spectroscopy do for membrane‐active peptide studies? , 2008, Journal of peptide science : an official publication of the European Peptide Society.

[35]  Rui Oliveira,et al.  Combining metabolic flux analysis tools and 13C NMR to estimate intracellular fluxes of cultured astrocytes , 2008, Neurochemistry International.

[36]  J. Zimmerberg,et al.  The physical chemistry of biological membranes , 2006, Nature chemical biology.

[37]  Miguel A R B Castanho,et al.  Cell-penetrating peptides and antimicrobial peptides: how different are they? , 2006, The Biochemical journal.

[38]  T. Kirchhausen,et al.  Dynasore, a cell-permeable inhibitor of dynamin. , 2006, Developmental cell.

[39]  N. C. Price,et al.  How to study proteins by circular dichroism. , 2005, Biochimica et biophysica acta.

[40]  Miguel A R B Castanho,et al.  Translocation of beta-galactosidase mediated by the cell-penetrating peptide pep-1 into lipid vesicles and human HeLa cells is driven by membrane electrostatic potential. , 2005, Biochemistry.

[41]  B. Lebleu,et al.  Cellular Uptake of Unconjugated TAT Peptide Involves Clathrin-dependent Endocytosis and Heparan Sulfate Receptors* , 2005, Journal of Biological Chemistry.

[42]  Kai Simons,et al.  Model systems, lipid rafts, and cell membranes. , 2004, Annual review of biophysics and biomolecular structure.

[43]  Carol Beth Post,et al.  Solution structure of dengue virus capsid protein reveals another fold. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[44]  Manuel Prieto,et al.  Quantifying molecular partition into model systems of biomembranes: an emphasis on optical spectroscopic methods. , 2003, Biochimica et biophysica acta.

[45]  S. Tatulian Structural effects of covalent inhibition of phospholipase A2 suggest allosteric coupling between membrane binding and catalytic sites. , 2003, Biophysical journal.

[46]  N. C. Santos,et al.  Lipossomas: a bala mágica acertou? , 2002 .

[47]  J. García de la Torre,et al.  Joint determination by Brownian dynamics and fluorescence quenching of the in-depth location profile of biomolecules in membranes. , 2002, Analytical biochemistry.

[48]  S H White,et al.  How to measure and analyze tryptophan fluorescence in membranes properly, and why bother? , 2000, Analytical biochemistry.

[49]  C. Yu,et al.  Fusion induced aggregation of model vesicles studied by dynamic and static light scattering. , 2000, Chemistry and physics of lipids.

[50]  Liam J. McGuffin,et al.  The PSIPRED protein structure prediction server , 2000, Bioinform..

[51]  N. Greenfield Applications of circular dichroism in protein and peptide analysis , 1999 .

[52]  M. Prieto,et al.  Fluorescence quenching data interpretation in biological systems. The use of microscopic models for data analysis and interpretation of complex systems. , 1998, Biochimica et biophysica acta.

[53]  B. Falgout,et al.  A conserved internal hydrophobic domain mediates the stable membrane integration of the dengue virus capsid protein. , 1997, Virology.

[54]  N. Santos,et al.  Teaching light scattering spectroscopy: the dimension and shape of tobacco mosaic virus. , 1996, Biophysical journal.

[55]  M. Prieto,et al.  Filipin fluorescence quenching by spin-labeled probes: studies in aqueous solution and in a membrane model system. , 1995, Biophysical journal.

[56]  M. Yamazaki,et al.  Direct evidence of induction of interdigitated gel structure in large unilamellar vesicles of dipalmitoylphosphatidylcholine by ethanol: studies by excimer method and high-resolution electron cryomicroscopy. , 1994, Biophysical journal.

[57]  M. Prieto,et al.  Ribonuclease T1 and alcohol dehydrogenase fluorescence quenching by acrylamide: A laboratory experiment for undergraduate students , 1993 .

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

[59]  J. Nagle,et al.  Structure of fully hydrated bilayer dispersions. , 1988, Biochimica et biophysica acta.

[60]  A. Schousboe,et al.  Energy metabolism in glutamatergic neurons, GABAergic neurons and astrocytes in primary cultures , 1988, Neurochemical Research.

[61]  K. Ghiggino,et al.  Vertical fluctuations of phospholipid acyl chains in bilayers , 1987, FEBS letters.

[62]  D. Sargent,et al.  Membrane lipid phase as catalyst for peptide-receptor interactions. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[63]  S. Provencher A constrained regularization method for inverting data represented by linear algebraic or integral equations , 1982 .

[64]  D. Hoekstra,et al.  Use of resonance energy transfer to monitor membrane fusion. , 1981, Biochemistry.

[65]  David R. Liu,et al.  Engineering and identifying supercharged proteins for macromolecule delivery into mammalian cells. , 2012, Methods in enzymology.

[66]  A. Ivanov,et al.  Pharmacological inhibition of endocytic pathways: is it specific enough to be useful? , 2008, Methods in molecular biology.

[67]  Michael M. Kozlov,et al.  How proteins produce cellular membrane curvature , 2006, Nature Reviews Molecular Cell Biology.

[68]  M. Castanho,et al.  Lipid membrane-induced optimization for ligand–receptor docking: recent tools and insights for the “membrane catalysis” model , 2005, European Biophysics Journal.

[69]  W. Delano The PyMOL Molecular Graphics System , 2002 .

[70]  R. Langer,et al.  Advances in Drug Delivery , 1986 .

[71]  G. Kneale,et al.  Analysis of DNA-protein interactions by intrinsic fluorescence. , 1994, Methods in molecular biology.

[72]  S. Provencher CONTIN: A general purpose constrained regularization program for inverting noisy linear algebraic and integral equations , 1984 .

[73]  J. Lakowicz Principles of fluorescence spectroscopy , 1983 .