Pille Säälik

Penetration without cells: Membrane translocation of cell-penetrating peptides in the model giant plasma membrane vesicles

The cellular internalization of cell-penetrating peptides (CPPs) is proposed to take place by both endocytic processes and by a direct translocation across the plasma membrane. So far only scarce data is available about what determines the choice between the two uptake routes, or the proportion of used pathways when both are active simultaneously. Furthermore, the mechanism(s) of membrane penetration by peptides is itself still a matter of debate. We have introduced the giant plasma membrane vesicles (GPMVs) to study the interaction of six well-described CPPs (fluorescently labeled nona-arginine, Tat peptide, Penetratin, MAP, Transportan and TP10) in a model system of native plasma membrane without the interference of endocytic processes. The membranes of GPMVs are shown to segregate into liquid-ordered and liquid-disordered phases at low temperatures and we demonstrate here by confocal microscopy that amphipathic CPPs preferentially associate with liquid-disordered membrane areas. Moreover, all tested CPPs accumulate into the lumen of GPMVs both at ambient and low temperature. The uncharged control peptide and dextran, in contrary, do not translocate from the medium into the lumen of vesicles. The absence of energy-dependent cellular processes and the impermeability to hydrophilic macromolecules makes the GPMVs a useful model to study the translocation of CPPs across the plasma membrane in conditions lacking endocytosis.

Peptide-mediated protein delivery—Which pathways are penetrable?

The growing number of reports on the effective cargo delivery by cell-penetrating peptides (CPPs) has extensively widened our knowledge about the mechanisms involved in CPP-mediated delivery. However, the data available on the internalization mode of CPP-cargo complexes are often conflicting and/or equivocal. Moreover, the intracellular trafficking of CPP-cargo complexes is, to date, relatively unexplored resulting in only minimal information about what is really happening to the complexes inside the cell. This review focuses on defining the endocytic pathways engaged in the transduction of CPP-cargo complexes and seeks to determine the extent of different endocytic routes required for effective uptake. In addition, the intracellular pathways utilized during the trafficking and sorting of CPP-cargo complexes as well as the ultimate fate of the complexes inside cells will be discussed.

CPP-protein constructs induce a population of non-acidic vesicles during trafficking through endo-lysosomal pathway

The major limitation in the application of bioactive molecules is their low permeation across plasma membrane. Effective transporters - cell-penetrating peptides (CPPs) - are utilized to enhance uptake of various cargo upon attachment to its sequences. Still, information about relevance of different endocytic routes during CPP-cargo internalization is ambiguous and underlying mechanism(s) of intracellular trafficking is even less understood. We first defined involvement of recycling pathway in trafficking of 3 different CPPs - transportan, oligoarginine and Tat - complexed to avidin-TexasRed in Cos-7 cells in relation to trans-Golgi network spatially constraining recycling endosomes. By confocal microscopy, only a negligible fraction of complexes-containing vesicles were found inside trans-Golgi ring suggesting its marginal role in CPP-mediated delivery. Secondly, we characterized engagement of endo-lysosomal pathway to assess acidity of complexes-containing vesicles. CPPs induced 3 different populations of complexes-containing vesicles which size and proportion depended on CPP, time and concentration. In time, more complexes were targeted to low-pH structures. However, a population of complexes-containing vesicles was observed to retain rather neutral pH. Induction of vesicles with non-acidic pH generated i.e. by caveolin-dependent endocytosis or by CPPs themselves during intracellular trafficking could be the key step in inducement of escape of complexes from endosomal structures, a limiting step in effective cargo delivery by CPPs.

Protein delivery with transportans is mediated by caveolae rather than flotillin-dependent pathways

Delivery of large bioactive cargoes into cells with the help of cell-penetrating peptides (CPPs) is mostly based on endocytic processes. Here we map the cellular pathways used by transportan and transportan 10 (TP10) for protein transduction in HeLa cells. CPP-mediated cellular delivery is often suggested to be lipid-raft-dependent; therefore, we used flotillin-1, caveolin, Rab5, and PI3P as markers to elucidate the involvement of these particular endosomal pathways in the protein uptake process. Confocal laser scanning and electron microscopy reveal only a negligible overlap of avidin/neutravidin conveyed into cells by transportans with the raft marker flotillin-1 or early endosomal markers Rab5 and PI3P. However, about 20% of protein-CPP complexes colocalize with the caveolar/caveosomal marker caveolin, and down-regulation of caveolin-1 by siRNA treatment leads to the inhibition of the CPP-mediated protein uptake by 30-50%. On the contrary, the lack of flotillin-1 increases rather than decreases the CPP-mediated protein transport. The participation of the caveolin-1-dependent pathway in CPP-mediated protein delivery was also corroborated by using caveolin-1 knockout mouse embryonic fibroblasts.

Cellular uptake and biological activity of peptide nucleic acids conjugated with peptides with and without cell-penetrating ability.

A 12‐mer peptide nucleic acid (PNA) directed against the nociceptin/orphanin FQ receptor mRNA was disulfide bridged with various peptides without and with cell‐penetrating features. The cellular uptake and the antisense activity of these conjugates were assessed in parallel. Quantitation of the internalized PNA was performed by using an approach based on capillary electrophoresis with laser‐induced fluorescence detection (CE‐LIF). This approach enabled a selective assessment of the PNA moiety liberated from the conjugate in the reducing intracellular environment, thus avoiding bias of the results by surface adsorption. The biological activity of the conjugates was studied by an assay based on the downregulation of the nociceptin/orphanin FQ receptor in neonatal rat cardiomyocytes (CM). Comparable cellular uptake was found for all conjugates and for the naked PNA, irrespective of the cell‐penetrating properties of the peptide components. All conjugates exhibited a comparable biological activity in the 100 nM range. The naked PNA also exhibited extensive antisense activity, which, however, proved about five times lower than that of the conjugates. The found results suggest cellular uptake and the bioactivity of PNA‐peptide conjugates to be not primarily related to the cell‐penetrating ability of their peptide components. Likewise from these results it can be inferred that the superior bioactivity of the PNA‐peptide conjugates in comparison with that of naked PNA rely on as yet unknown factors rather than on higher membrane permeability. Several hints point to the resistance against cellular export and the aggregation propensity combined with the endocytosis rate to be candidates for such factors. Copyright

Cell-penetrating peptide secures an efficient endosomal escape of an intact cargo upon a brief photo-induction

Since their discovery, cell-penetrating peptides (CPPs) have provided a novel, efficient, and non-invasive mode of transport for various (bioactive) cargos into cells. Despite the ever-growing number of successful implications of the CPP-mediated delivery, issues concerning their intracellular trafficking, significant targeting to degradative organelles, and limited endosomal escape are still hindering their widespread use. To overcome these obstacles, we have utilized a potent photo-induction technique with a fluorescently labeled protein cargo attached to an efficient CPP, TP10. In this study we have determined some key requirements behind this induced escape (e.g., dependence on peptide-to-cargo ratio, time and cargo), and have semi-quantitatively assessed the characteristics of the endosomes that become leaky upon this treatment. Furthermore, we provide evidence that the photo-released cargo remains intact and functional. Altogether, we can conclude that the photo-induced endosomes are specific large complexes-condensed non-acidic vesicles, where the released cargo remains in its native intact form. The latter was confirmed with tubulin as the cargo, which upon photo-induction was incorporated into microtubules. Because of this, we propose that combining the CPP-mediated delivery with photo-activation technique could provide a simple method for overcoming major limitations faced today and serve as a basis for enhanced delivery efficiency and a subsequent elevated cellular response of different bioactive cargo molecules.

Mapping of Protein Transduction Pathways with Fluorescent Microscopy

The number of various cargo delivered into cells by CPPs demonstrates the effective transport abilities of these short-peptidic sequences. Over the years of research, the translocation process of CPP-cargo complexes has been mapped to being of mostly endocytic nature, however, there is still no consensus on which of the endocytic routes is prevalent and to which extent the interplay between different modes of endocytosis is taking place. The intracellular trafficking of CPPs attached to a cargo molecule is even less understood. Therefore, the internalization and the subsequent intracellular targeting of complexes need clarification in order to define cellular destinations and improve the targeting of the cargo molecule to specific cellular compartments depending on the cargo attached to the transporting vector. This chapter focuses on describing the methods for visualizing the CPP-protein complexes in relation to different endocytic markers, for example transferrin (marker for clathrin-mediated endocytosis) and cholera toxin (ambiguous marker for clathrin-, caveolin-, and flotillin-mediated, but also clathrin- and caveolin-independent endocytosis) to determine the role of the respective pathways during entry to cells, and to different intracellular targets, for instance the lysosomal organelles or the Golgi apparatus. Additionally, antibody staining of respective endocytic vesicles following the internalization of CPP-protein complexes will be discussed.

Arginine-Rich Cell-Penetrating Peptides Require Nucleolin and Cholesterol-Poor Subdomains for Translocation across Membranes

Proficient transport vectors called cell-penetrating peptides (CPPs) internalize into eukaryotic cells mostly via endocytic pathways and facilitate the uptake of various cargo molecules attached to them. However, some CPPs are able to induce disturbances in the plasma membrane and translocate through it seemingly in an energy-independent manner. For understanding this phenomenon, giant plasma membrane vesicles (GPMVs) derived from the cells are a beneficial model system, since GPMVs have a complex membrane composition comparable to the cells yet lack cellular energy-dependent mechanisms. We investigated the translocation of arginine-rich CPPs into GPMVs with different membrane compositions. Our results demonstrate that lower cholesterol content favors accumulation of nona-arginine and, additionally, sequestration of cholesterol increases the uptake of the CPPs in vesicles with higher cholesterol packing density. Furthermore, the proteins on the surface of vesicles are essential for the uptake of arginine-rich CPPs: downregulation of nucleolin decreases the accumulation and digestion of proteins on the membrane suppresses translocation even more efficiently.

Abstract 1343: P32-targeting TT1 peptide delivers nanoparticles to intracranial glioblastomas

Targeted delivery of cancer therapeutics using affinity ligands can dramatically improve antitumor efficacy. Over the years a number of homing peptides that upon systemic injection accumulate in solid tumors have been identified by in vivo peptide phage display. In a quest to find homing peptides optimally suited for drug delivery to high-grade gliomas, our laboratories are using advanced mouse models of glioblastoma (GBM) to systematically audit known tumor-homing peptides and to perform new in vivo screens using peptide phage libraries. P32 is a mitochondrial chaperone that is aberrantly expressed on the cell surface in activated malignant and stromal cells in tumors. P32 is a receptor for widely used LypP-1 peptide and for recently identified TT1 peptide. Here we show that iron oxide nanoworms (IONW) functionalized with linear TT1 peptide (CKRGARST) strongly home to intracranial GBMs grafted in immune deficient mice. IONW are paramagnetic nanoparticles that are PEGylated to extend blood half-life, and have, because of their elongated shape, more effective targeting properties than spherical nanoparticles. Five hours after intravenous injection of IONW (7.5 mg/kg), macroscopic fluorescence imaging demonstrated robust homing of TT1-IONW in GBMs of murine origin (WT GBM and VEGF KO GBM from the G. Berger lab) and in a patient-derived glioma model (P13 model from the Bjerkvig lab). Confocal microscopy confirmed the presence of TT1 but not control IONW in gliomas, with TT1-IONW signal showing partial overlap with blood- and lymphatic vessel markers (CD31 and LYVE-1) in WT GBM and P13 gliomas, whereas lower level of colocalization with these markers was detected for mouse GBM not expressing VEGF. In addition, moderate colocalization between TT1-IONW and the macrophage marker CD11b was detected in the P13 tumors. Detailed phenotyping and functional characterization of TT1-positive macrophages is ongoing. Our data suggest that TT1 peptide has potential applications as a glioma-targeting vehicle. Currently, we are evaluating TT1-targeted IONWs as a contrast agent for glioma MRI and as carriers for cytotoxic compounds. Citation Format: Pille Saalik, Hedi Hunt, Allan Tobi, Anne-Mari Anton Willmore, Kadri Toome, Shweta Sharma, Ramana Kotamraju, Gabriele Bergers, Rolf Bjerkvig, Erkki Ruoslahti, Tambet Teesalu, Tambet Teesalu. P32-targeting TT1 peptide delivers nanoparticles to intracranial glioblastomas. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 1343.

Abstract 2164: Tenascin-C binding peptides for cancer targeting

Extracellular matrix protein tenascin C (TNC) is strongly overexpressed in the stroma of many solid tumors. TNC expression is upregulated at the invasive front of tumors while being nearly undetectable in normal adult tissues. TNC-targeted humanized antibodies are undergoing clinical development for targeting compounds to solid tumors. Compared to antibodies, homing peptides may have more favorable extravasation and tumor penetration properties. We used in vitro T7 peptide display to identify peptides that bind to the alternatively spliced domain C of the large isoform of Tenascin-C (TNC FnIIIC). The selected phage pool showed 500-fold increase in binding to immobilized TNC FnIIIC. Candidate TNC FnIIIC-binding peptides (designated PL1- 3) were found to bind to TNC FnIII C protein, to the extracellular matrix extracted from PC3 prostate tumors and to cultured tumor cells known to overexpress TNC. To evaluate candidate peptides in vivo, we used mice bearing patient-derived xenografts of P3 glioma (R. Bjerkvig, Bergen, Norway), 4T1 breast tumors, and PC-3prostate carcinoma. A pool of the phages displaying TNC FnIIIC binding peptides, and a panel of phages displaying published tumor homing and control peptides was injected intravenously in tumor-bearing mice, and relative tumor homing and background in control tissues was determined for each phage using high-throughput sequencing (HTS) of phage genomic DNA. These studies demonstrated that among TNC FnIIIC targeting peptides, the PL3 peptide showed the best tumor homing and specificity profile. To evaluate the potential of the synthetic PL3 peptide for tumor targeting of nanoparticles, we coupled PL3 peptide to iron oxide nanoworms (IONW) - paramagnetic nanoparticles that are PEGylated to extend blood half-life, and have because of their elongated shape more effective targeting properties than spherical nanoparticles. 5 hours after intravenous administration of 7.5mg/kg of IONW in mice bearing PC3 prostate cancer xenografts, PL3-IONW but not control IONW showed a robust accumulation in tumor vasculature, and some extravasation into extravascular tumor tissue. Our data suggests that the newly identified TNC FnIIIC targeting peptide, PL3, may be used for payload delivery into tumor stroma. Currently, we are evaluating PL3-targeted IONWs as a MRI contrast agent and as carriers for cytotoxic compounds to TNC expressing tumors. Citation Format: Prakash Lingasamy, Allan Tobi, Hedi Hunt, Pille Saalik, Markko Salumae, Tambet Teesalu, Tambet Teesalu. Tenascin-C binding peptides for cancer targeting. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2164.