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We have to admit that today, despite numerous studies carried out in the field, the mechanism of uptake of CPPs is still not clarified. In addition, it is likely that mechanisms may differ between distinct CPPs. However, we feel that the CPPs shown earlier differ from other classes of peptides used in drug delivery, in particular peptides recognized by cell-surface receptors, because they are captured by cells in absence of a chiral receptor, or even when endocytosis has been blocked. This difference has a very high impact in cargo delivery, since CPPs and their cargoes do not accumulate in endosomes and lysosomes and thus have better access in the same time to other compartments less sensitive to degradation. The uptake mechanisms of CPPs also differ from those of a wide variety of toxins and antimicrobial peptides, as they do not form pores within the membranes. Therefore, this handbook describes the latter class of membrane-active peptides only briefly. Chapter 14 has signal sequences as its subject due to possible mechanistic similarities between the uptake of these peptides and that of CPPs. Attempts have been made to extract structural information that would predict the uptake process of the transport peptides. Positive charges in side chains of Lys/Arg, amphiphilicity of the peptide, presence of Trp or Phe residues in certain positions, and length of the polypeptide chain have been proposed as crucial factors determining cellular uptake. However, general rules for cellular uptake of peptides are only beginning to emerge. Therefore, rational design of novel transport peptides, sequence comparison, SAR studies, molecular modeling, biophysical characterization, and multivariate analysis will be necessary for successful application of CPPS in research and therapy. These topics are discussed throughout the handbook, particularly in Section II. Applications of CPPs Traditionally, polypeptides and oligonucleotides are considered of limited therapeutical value because of their low biomembrane permeability and their relatively rapid degradation. This is an obstacle to their use in biomedical research and as pharmaceutical substances. Indeed, the possibility to manipulate intracellular biological targets would increase if large-sized hydrophilic compounds could be addressed intracellularly, without severe limitation on amounts inherent to the necessity to cross lipid bilayers. Thus, the discovery that CPPs translocate across the plasma membrane of live cells and permit intracellular transport of cargoes, such as conjugated peptides, proteins, oligonucleotides, λ phages, and nanoparticles has opened new possibilities in biomedical research and therapy. In Section III, several such applications are covered, including methods for CPP conjugation and microbial applications. In conclusion, a constantly growing number of cell-penetrating peptides are available today and have been applied for cellular delivery of a variety of bioactive cargoes with seemingly no strict size limit. This handbook summarizes that which has already been achieved. Although the mechanisms of cellular uptake of CPPs are not yet clarified, attempts have been and are being made to help solve this question, thus opening the way to rational design of peptidic and nonpeptidic carriers. Clinical applications will then be within reach. Ülo Langel
REFERENCES 1. Green, M. and Loewenstein, P.M., Autonomous functional domains of chemically synthesized human immunodeficiency virus tat trans-activator protein, Cell, 55, 1179, 1988. 2. Frankel, A.D. and Pabo, C.O., Cellular uptake of the tat protein from human immunodeficiency virus, Cell, 55, 1189, 1988. 3. Joliot, A. et al., Antennapedia homeobox peptide regulates neural morphogenesis, Proc. Natl. Acad. Sci. U.S.A., 88, 1864, 1991. 4. Derossi, D. et al., The third helix of the Antennapedia homeodomain translocates through biological membranes, J. Biol. Chem., 269, 10444, 1994. 5. Vivès, E., Brodin, P., and Lebleu, B., A truncated HIV-1 Tat protein basic domain rapidly translocates through the plasma membrane and accumulates in the cell nucleus, J. Biol. Chem., 272, 16010, 1997. 6. Chaloin, L. et al., Design of carrier peptide–oligonucleotide conjugates with rapid membrane translocation and nuclear localization properties, Biochem. Biophys. Res. Commun., 243, 601, 1998. 7. Chang, M. et al., Dissecting G protein-coupled receptor signaling pathways with membrane-permeable blocking peptides, J. Biol. Chem., 275, 7021, 2000. 8. Elmquist, A. et al., VE-Cadherin-derived cell-penetrating peptide, pVEC, with carrier functions, Exp. Cell Res., 269, 237, 2001. 9. Pooga, M. et al., Cell penetration by transportan, FASEB J., 12, 67, 1998. 10. Oehlke, J. et al., Evidence for extensive and nonspecific translocation of oligopeptides across plasma membranes of mammalian cells, Biochim. Biophys. Acta, 1330, 50, 1997. 11. Mitchell, D.J. et al., Polyarginine enters cells more efficiently than other polycationic homopolymers, J. Pept. Res., 56, 318, 2000. 12. Mi, Z. et al., Characterization of a class of cationic peptides able to facilitate efficient protein transduction in vitro and in vivo, Mol. Ther., 2, 339, 2000. 13. Han, K. et al., Efficient intracellular delivery of GFP by homeodomains of Drosophila Fushi-tarazu and Engrailed proteins, Mol. Cells, 10, 728, 2000. 14. Wender, P.A. et al., The design, synthesis, and evaluation of molecules that enable or enhance cellular uptake: peptoid molecular transporters, Proc. Natl. Acad. Sci. USA, 97, 13003, 2000. 15. Gudmundsson, O.S. et al., Coumarinic acid-based cyclic prodrugs of opioid peptides that exhibit metabolic stability to peptidases and excellent cellular permeability, Pharmac. Res., 16, 7, 1999. 16. Eichholtz, T. et al., A myristoylated pseudosubstrate peptide, a novel protein kinase C inhibitor, J. Biol. Chem., 268, 1982, 1993. 17. Vegners, R., Cunningham, C.C., and Janmey, P.A., Cell-permeant peptide derivatives based on the phosphoinositide binding site of gelsolin, in Peptides 1998, Bajusz, S. and Hudesz, F., Eds., Akademiai Kiado, Budapest, 82, 1999. 18. Tarasova, N.L., Rice, W.G., and Michejda, C.J., Inhibition of G-protein-coupled receptor function by disruption of transmembrane domain interactions, J. Biol. Chem., 274, 34911, 1999.
Page 2 and 3: CELL- PENETRATING PEPTIDES Processe
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3 Transportans Margus Pooga, Mattia
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Transportans 55 Indeed, galparan is
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Transportans 57 especially the endo
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Transportans 59 In the penetration
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Transportans 61 A 21-mer antisense
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Transportans 63 Commonly, the prote
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Transportans 65 antibiotin antibodi
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Transportans 67 For cross-linking o
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Transportans 69 and still retain ef
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Model Amphipathic Peptides 73 its D
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Model Amphipathic Peptides 75 pmol/
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TABLE 4.1 Internalization of Peptid
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TABLE 4.2 Internalization of Peptid
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Model Amphipathic Peptides 81 relat
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Model Amphipathic Peptides 87 A cat
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Model Amphipathic Peptides 89 At th
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Model Amphipathic Peptides 91 16. H
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Signal Sequence-Based Cell-Penetrat
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Interactions of Cell-Penetrating Pe
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Structure Prediction of CPPs and It
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FIGURE 9.8 The center of the figure
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Cell-Penetrating Peptides as Vector
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CPP 2 Cargo or mRNA CAP Antisense A
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Microbial Membrane-Permeating Pepti
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Index A Abaecin, 129 Abz radiolabel
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Index 399 Diffraction, 168 Disulphi
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Index 401 structure prediction, 187
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Index 403 pRB proteins, Tat-E1A bin
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Index 405 lipid perturbation (secon
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