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Kinetics of Uptake of Cell-Penetrating Peptides 291 concentrations the membrane leakage increased. Tat peptide did not induce any leakage at all, even at highest concentrations used (20 µM), while a negligible effect was detected for penetratin. The effect of a cargo on the translocation velocity is of great interest. Cargoes transported by CPPs are very different in structure and in size, ranging from organic molecules of low molecular mass (e.g., biotin, fluorescein), over peptides, DNA, and PNA fragments, to proteins of around 150 kDa. It is expected that a cargo could have an influence on the rate of internalization of CPP–cargo construct. However, as it was shown, small cargoes usually do not influence the rate of translocation substantially. 8 The data on kinetics of translocation of CPP coupled to medium- and large-size cargos are not available. From immunofluorescence studies utilizing confocal microscopy, it could be deduced that TP attached to protein cargos of up to 150 kDa internalizes more slowly than TP itself, as estimated visually from the dynamics of fluorescence appearance in the cells. 8,23 Exact characterization of how much slower this process is has not been carried out. Biotinyl–TP could be detected in cells after a few minutes and reached maximal intracellular concentration after 20 min of incubation. 8 Transportan attached to green fluorescence protein (GFP, molecular mass 28 kDa), avidin–TRITC (molecular mass 66 kDa), and polyclonal antibody (molecular mass 150 kDa) were detected in the cytoplasm substantially later, on average after 30 min of incubation. However, in some cases, e.g., with noncovalently attached monoclonal antibody against biotin to biotinyl–TP, the construct was detected in the cell after 2 h incubation. 23 Proteins have also been translocated by the Tat (47–57) carrier. 24 Successful translocation of partially denatured β-galactosidase into different mouse cells was achieved, but the experiments do not allow comparison of rate of translocation between the Tat (47–57)–β-galactosidase construct and Tat (47–57). Interestingly, β-galactosidase was refolded inside the cells and regained its full physiological role. 13.5 CONCLUSIONS AND FUTURE PERSPECTIVE Methods of kinetics have already proven their usefulness by providing valuable data on the rate of CPP internalization and by establishing the link between rate and yield of cellular uptake, as well as structure of CPP. Complete study of cellular penetration kinetics with all CPPs and various cargo molecules would give additional valuable information and allow constructing kinetic models for cell penetration of each individual CPP, leading to a better understanding of principles that govern the internalization of CPPs. Establishing methodological procedures for convenient and reliable real-time monitoring of internalization is an important first step. ACKNOWLEDGMENTS This work was supported by grants from the EC Biotechnology Project BIO4-98-0227, Swedish Research Councils TFR and NFR, and grants from the Ministry of Science, Education, and Sport of the Republic of Slovenia.
292 Cell-Penetrating Peptides: Processes and Applications REFERENCES 1. Hällbrink, M. et al., Cargo delivery kinetics of cell-penetrating peptides, Biochim. Biophys. Acta, 1515, 101, 2001. 2. Tosteson, M.T. et al., Melittin lysis of red cells, J. Membr. Biol., 87, 35, 1985. 3. Scheller, A. et al., Structural requirements for cellular uptake of α-helical amphipathic peptide, J. Peptide Sci., 5, 185, 1999. 4. Oehlke, J. et al., Cellular uptake of an α-helical amphipathic model peptide with the potential to deliver polar compounds into cell interior non-endocytotically, Biochim. Biophys. Acta, 1414, 127, 1998. 5. Drin, G. et al., Physico-chemical requirements for cellular uptake of pAntp peptide, Eur. J. Biochem., 268, 1304, 2001. 6. Polyakov, V. et al., Novel Tat-peptide chelates for direct transduction of Technetium- 99m and Rhenium into human cells for imaging and radiotherapy, Bioconjugate Chem., 11, 762, 2000. 7. Lindgren, M. et al., Translocation properties of novel cell penetrating transportan and penetratin analogues, Bioconjugate Chem., 11, 619, 2000. 8. Pooga, M. et al., Cell penetration by transportan, FASEB J., 12, 67, 1998. 9. Soomets, U. et al., Deletion analogues of transportan, Biochim. Biophys. Acta, 1467, 165, 2000. 10. Gavin, J.R. et al., Insulin receptors in human circulating cells and fibroblasts, Proc. Natl. Acad. Sci. U.S.A., 69, 747, 1972. 11. Rousselle, C. et al., New advances in the transport of Doxorubicin through the bloodbrain barrier by peptide vector-mediated strategy, Mol. Pharmacol., 57, 679, 2000. 12. Oehlke, J. et al., Evidence for extensive and nonspecific translocation of oligopeptides across plasma membranes of mammalian cells, Biochim. Biophys. Acta, 1330, 50, 1997. 13. Lorenz, D. et al., Mechanism of peptide-induced mast cell degranulation. Translocation and patch-clamp studies, J. Gen. Physiol., 112, 577, 1998. 14. White, S.H. and Wimley, W.C., Membrane protein folding and stability: physical principles, Annu. Rev. Biophys. Biomol. Struct., 28, 319, 1999. 15. Heuser, J.E. and Anderson, R.G., Hypertonic media inhibit receptor-mediated endocytosis by blocking clathrin-coated pit formation, J. Cell Biol., 108, 389, 1989. 16. Frost, S.C. and Lane, M.D., Evidence for the involvement of vicinal sulfhydryl groups in insulin-activated hexose transport by 3T3-L1 adipocytes, J. Biol. Chem., 260, 2646, 1985. 17. McKenzie, F.R., Basic techniques to study G-protein function, in Signal Transduction. A Practical Approach, Milligan, G., Ed., Oxford University Press, New York, 1992, chap. 2. 18. Stojan, J., Analysis of progress curves in an acetylcholinesterase reaction: a numerical integration treatment, J. Chem. Inf. Comput. Sci., 37, 1025, 1997. 19. Bedecs, K., Langel, Ü., and Bartfai, T., Metabolism of galanin and galanin (1 to 16) in isolated cerebrospinal fluid and spinal cord from rat, Neuropeptides, 29, 137, 1995. 20. Soomets, U. et al., From galanin and mastoparan to galparan and transportan, Curr. Top. Pept. Protein Res., 2, 83, 1997. 21. Derossi, D. et al., Cell internalization of the third helix of the Antennapedia homeodomain is receptor-independent, J. Biol. Chem., 271, 18188, 1996. 22. 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. U.S.A., 97, 13003, 2000.
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CELL- PENETRATING PEPTIDES Processe
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Pharmacology and Toxicology: Basic
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Library of Congress Cataloging-in-P
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to the handbook are prominent resea
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REFERENCES 1. Green, M. and Loewens
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Contributors Mats Andersson Microbi
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Erin T. Pelkey Department of Chemis
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Contents Section I Classes of Cell-
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Chapter 16 Cell-Penetrating Peptide
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The Tat-Derived Cell-Penetrating Pe
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24 Cell-Penetrating Peptides: Proce
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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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116 Cell-Penetrating Peptides: Proc
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Interactions of Cell-Penetrating Pe
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Structure Prediction of CPPs and It
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FIGURE 9.7 (Color Figure 9.7 follow
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FIGURE 9.8 The center of the figure
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Biophysical Studies of Cell-Penetra
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FIGURE 15.9 (Color Figure 15.9 foll
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Cell-Penetrating Peptide Conjugatio
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Cell-Penetrating Peptide Conjugatio
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Cell-Penetrating Peptides as Vector
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TABLE 16.1 Examples of Transport of
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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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