The plasma membrane represents an impermeable barrier for most macromolecules. Still some proteins and so‐called cell‐penetrating peptides enter cells efficiently. It has been shown that endocytosis contributes to the import of these molecules. However, conflicting results have been obtained concerning the nature of the endocytic process. In addition, there have been new findings for an endocytosis‐independent cellular entry. In this study, we provide evidence that the Antennapedia‐homeodomain‐derived antennapedia (Antp) peptide, nona‐arginine and the HIV‐1 Tat‐protein‐derived Tat peptide simultaneously use three endocytic pathways: macropinocytosis, clathrin‐mediated endocytosis and caveolae/lipid‐raft‐mediated endocytosis. Antennapedia differs from Tat and R9 by the extent by which the different import mechanisms contribute to uptake. Moreover, at higher concentrations, uptake occurs by a mechanism that originates from spatially restricted sites of the plasma membrane and leads to a rapid cytoplasmic distribution of the peptides. Endocytic vesicles could not be detected, suggesting an endocytosis‐independent mode of uptake. Heparinase treatment of cells negatively affects this import, as does the protein kinase C inhibitor rottlerin, expression of dominant‐negative dynamin and chlorpromazine. This mechanism of uptake was observed for a panel of different cell lines. For Antp, significantly higher peptide concentrations and inhibition of endocytosis were required to induce its uptake. The relevance of these findings for import of biologically active cargos is shown.
The molecular events that contribute to the cellular uptake of cell-penetrating peptides (CPP) are still a matter of intense research. Here, we report on the identification and characterization of a 22-amino acid CPP derived from the human milk protein, lactoferrin. The peptide exhibits a conformation-dependent uptake efficiency that is correlated with efficient binding to heparan sulfate and lipid-induced conformational changes. The peptide contains a disulfide bridge formed by terminal cysteine residues. At concentrations exceeding 10 M, this peptide undergoes the same rapid entry into the cytoplasm that was described previously for the arginine-rich CPPs nona-arginine and Tat. Cytoplasmic entry strictly depends on the presence of the disulfide bridge. To better understand this conformation dependence, NMR spectroscopy was performed for the free peptide, and CD measurements were performed for free and lipidbound peptide. In solution, the peptides showed only slight differences in secondary structure, with a predominantly disordered structure both in the presence and absence of the disulfide bridge. In contrast, in complex with large unilamellar vesicles, the conformation of the oxidized and reduced forms of the peptide clearly differed. Moreover, surface plasmon resonance experiments showed that the oxidized form binds to heparan sulfate with a considerably higher affinity than the reduced form. Consistently, membrane binding and cellular uptake of the peptide were reduced when heparan sulfate chains were removed.
Cationic cell-penetrating peptides (CPPs) have been used widely as delivery vectors for the import of molecules that otherwise do not cross the plasma membrane of eukaryotic cells. In this work, we demonstrate that the three cationic CPPs, Antennapedia homeodomain-derived peptide (Antp), nona-arginine and Tat-derived peptide, inhibit tumour necrosis factor (TNF)-mediated signal transduction. This inhibition is based on the downregulation of TNF receptors at the cell surface by induction of internalization. In contrast to TNF-dependent receptor internalization, no receptor activation occurs. The receptor downregulation is not restricted to the CPPs. Remarkably, the HIV-1 Tat protein itself also induces the internalization of TNF receptors. The dynamin dependence of the internalization, as well as the fact that epidermal growth factor receptors are also internalized, suggest a general induction of clathrin-dependent endocytosis as the mechanism of action. The significance of these findings for the use of cationic CPPs in the import of bioactive peptides is demonstrated here using a conjugate consisting of Antp and a Smac protein-derived cargo peptide. The cargo alone, when introduced into cells by electroporation, enhanced TNF-induced apoptosis by inhibiting the anti-apoptotic action of IAPs (inhibitor of apoptosis proteins). For the Antp-Smac conjugate at concentrations below 40 μM the inhibitory effect of the Antp peptide compensated for the pro-apoptotic activity of the cargo, and led to the protection of cells against TNF-mediated apoptosis. These data provide important new information for the use of cationic CPPs for the cellular delivery of bioactive molecules.
Here, we demonstrate that coupling to N-hydroxypropyl methacrylamide (HPMA) copolymer greatly enhances the activity of apoptosis-inducing peptides inside cells. Peptides corresponding to the BH3 domain of Bid were coupled to a thioesteractivated HPMA (28.5 kDa) via native chemical ligation in a simple one-pot synthesis. Peptides and polymer conjugates were introduced into cells either by electroporation or by conjugation to the cell-penetrating peptide nona-arginine. The molecular basis of the increased activity is elucidated in detail. Loading efficiency and intracellular residence time were assessed by confocal microscopy. Fluorescence correlation spectroscopy was used as a separation-free analytical technique to determine proteolytic degradation in crude cell lysates. HPMA conjugation strongly increased the half-life of the peptides in crude cell lysates and inside cells, revealing proteolytic protection as the basis for higher activity.
Synthetic peptides are valuable tools in fundamental and applied biomedical research. On one hand, these molecules provide highly efficient access to competitive inhibitors of molecular interactions and enzyme substrates by rational design. On the other hand, peptides may serve as powerful vectors to mediate cellular uptake of molecules that otherwise enter cells only poorly. The coupling of both such functionalities provides access to molecules interfering with molecular processes inside the cell. However, the combination of several functionalities on one synthetic peptide may be compromised by problems associated with the synthesis of long peptides. Native chemical ligation enables the chemoselective coupling of fully deprotected functional building blocks. However, peptide thioesters are still not accessible by standard solid-phase peptide synthesis. Here, we demonstrate the cofunctionalization of a thioester-activated N-hydroxypropyl methacrylamide (HPMA) copolymer (28,500 Da) with the cell-penetrating peptide (CPP) nonaarginine and a bioactive peptide as independent building blocks by native chemical ligation. Nonaarginine was employed as a cell-penetrating peptide (CPP), a fluorescein-labeled analogue of a pro-apoptotic peptide as a biofunctional cargo. Incorporation of the fluorescein label enabled the highly sensitive quantification of the coupling stoichiometry by fluorescence correlation spectroscopy (FCS) using 0.4 pmol/12 ng of labeled construct. A construct only bearing the functional cargo peptide required cellular import by electroporation in order to show activity. In contrast, a construct combining all functionalities was active upon incubation of cells, validating the modular nature of the approach.
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