Effects of cargo molecules on the cellular uptake of arginine-rich cell-penetrating peptides

The identification of cell-penetrating peptides (CPPs) as vectors for the intracellular delivery of conjugated molecules such as peptides, proteins, and oligonucleotides has emerged as a significant tool to modulate biological activities inside cells. The mechanism of CPP uptake by the cells is still unclear, and appears to be both endocytotic and non-endocytotic, depending on the CPP and cell type. Moreover, it is also unknown whether cargo sequences have an effect on the uptake and cellular distribution properties of CPP sequences. Here, we combine results from quantitative fluorescence microscopy and binding to lipid membrane models to determine the effect of cargo peptide molecules on the cellular uptake and distribution of the arginine-rich CPPs, R₇, and R₇W, in live cells. Image analysis algorithms that quantify fluorescence were used to measure the relative amount of peptide taken up by the cell, as well as the extent to which the uptake was endocytotic in nature. The results presented here indicate that fusion of arginine-rich CPPs to peptide sequences reduces the efficiency of uptake, and dramatically changes the cellular distribution of the CPP from a diffuse pattern to one in which the peptides are mostly retained in endosomal compartments.     

Effects of cargo molecules on the cellular uptake of arginine-rich cell-penetrating peptides

The identification of cell-penetrating peptides (CPPs) as vectors for the intracellular delivery of conjugated molecules such as peptides, proteins, and oligonucleotides has emerged as a significant tool to modulate biological activities inside cells. The mechanism of CPP uptake by the cells is still unclear, and appears to be both endocytotic and non-endocytotic, depending on the CPP and cell type. Moreover, it is also unknown whether cargo sequences have an effect on the uptake and cellular distribution properties of CPP sequences. Here, we combine results from quantitative fluorescence microscopy and binding to lipid membrane models to determine the effect of cargo peptide molecules on the cellular uptake and distribution of the arginine-rich CPPs, R7, and R7W, in live cells. Image analysis algorithms that quantify fluorescence were used to measure the relative amount of peptide taken up by the cell, as well as the extent to which the uptake was endocytotic in nature. The results presented here indicate that fusion of arginine-rich CPPs to peptide sequences reduces the efficiency of uptake, and dramatically changes the cellular distribution of the CPP from a diffuse pattern to one in which the peptides are mostly retained in endosomal compartments.     

Enhanced intracellular peptide delivery by multivalent cell-penetrating peptide with bioreducible linkage

Multivalent cell-penetrating peptides (CPPs) have been reported to show enhancement in cellular uptake and endosomolytic activity. However, its application was limited to trans-delivery of cargo which is lower in cellular uptake efficiency of cargo than cis-delivery. Here, we tried the cis-delivery of cargo with multivalent CPP by preparing bioreducible dimeric CPP–cargo with apoptotic activity using TatBim peptide, a fusion of Tat CPP and Bim peptide derived from Bim apoptosis-inducing protein. Dimeric TatBim was almost twice as highly internalized by cells and significantly induced apoptosis compared to monomeric TatBim. Contribution of bioreducible linkage of dimeric TatBim towards apoptotic activity was also confirmed.     

Secondary structure of cell-penetrating peptides controls membrane interaction and insertion

The clinical use of efficient therapeutic agents is often limited by the poor permeability of the biological membranes. In order to enhance their cell delivery, short amphipathic peptides called cell-penetrating peptides (CPPs) have been intensively developed for the last two decades. CPPs are based either on protein transduction domains, model peptide or chimeric constructs and have been used to deliver cargoes into cells through either covalent or non-covalent strategies. Although several parameters are simultaneously involved in their internalization mechanism, recent focuses on CPPs suggested that structural properties and interactions with membrane phospholipids could play a major role in the cellular uptake mechanism. In the present work, we report a comparative analysis of the structural plasticity of 10 well-known CPPs as well as their ability to interact with phospholipid membranes. We propose a new classification of CPPs based on their structural properties, affinity for phospholipids and internalization pathways already reported in the literature.     

Human-protein-derived peptides for intracellular delivery of biomolecules

Access of therapeutic biomolecules to cytoplasmic and nuclear targets is hampered by the inability of these molecules to cross biological membranes. Approaches to overcome this hurdle involve CPPs (cell-penetrating peptides) or protein transduction domains. Most of these require rather high concentrations to elicit cell-penetrating functionality, are non-human, pathogen-derived or synthetic entities, and may therefore not be tolerated or even immunogenic. We identified novel human-protein-derived CPPs by a combination of in silico and experimental analyses: polycationic CPP candidates were identified in an in silico library of all 30-mer peptides of the human proteome. Of these peptides, 60 derived from extracellular proteins were evaluated experimentally. Cell viability and siRNA (small interfering RNA) transfection assays revealed that 20 out of the 60 peptides were functional. Three of these showed CPP functionality without interfering with cell viability. A peptide derived from human NRTN (neurturin), which contains an α-helix, performed the best in our screen and was uniformly taken up by cultured cells. Examples for payloads that can be delivered to the cytosol by the NRTN peptide include complexed siRNAs and both N- and C-terminally fused pro-apoptotic peptides.     

Cell-penetrating peptide induces leaky fusion of liposomes containing late endosome-specific anionic lipid

Cationic cell-penetrating peptides (CPPs) are a promising vehicle for the delivery of macromolecular drugs. Although many studies have indicated that CPPs enter cells by endocytosis, the mechanisms by which they cross endosomal membranes remain elusive. On the basis of experiments with liposomes, we propose that CPP escape into the cytosol is based on leaky fusion (i.e., fusion associated with the permeabilization of membranes) of the bis(monoacylglycero)phosphate (BMP)-enriched membranes of late endosomes. In our experiments, prototypic CPP HIV-1 TAT peptide did not interact with liposomes mimicking the outer leaflet of the plasma membrane, but it did induce lipid mixing and membrane leakage as it translocated into liposomes mimicking the lipid composition of late endosome. Both membrane leakage and lipid mixing depended on the BMP content and were promoted at acidic pH, which is characteristic of late endosomes. Substitution of BMP with its structural isomer, phosphatidylglycerol (PG), significantly reduced both leakage of the aqueous probe from liposomes and lipid mixing between liposomes. Although affinity of binding to TAT was similar for BMP and PG, BMP exhibited a higher tendency to support the inverted hexagonal phase than PG. Finally, membrane leakage and peptide translocation were both inhibited by inhibitors of lipid mixing, further substantiating the hypothesis that cationic peptides cross BMP-enriched membranes by inducing leaky fusion between them.     

Cell-penetrating peptides and antimicrobial peptides: how different are they?

Some cationic peptides, referred to as CPPs (cell-penetrating peptides), have the ability to translocate across biological membranes in a non-disruptive way and to overcome the impermeable nature of the cell membrane. They have been successfully used for drug delivery into mammalian cells; however, there is no consensus about the mechanism of cellular uptake. Both endocytic and non-endocytic pathways are supported by experimental evidence. The observation that some AMPs (antimicrobial peptides) can enter host cells without damaging their cytoplasmic membrane, as well as kill pathogenic agents, has also attracted attention. The capacity to translocate across the cell membrane has been reported for some of these AMPs. Like CPPs, AMPs are short and cationic sequences with a high affinity for membranes. Similarities between CPPs and AMPs prompted us to question if these two classes of peptides really belong to unrelated families. In this Review, a critical comparison of the mechanisms that underlie cellular uptake is undertaken. A reflection and a new perspective about CPPs and AMPs are presented.     

Identification of a novel cell-penetrating peptide from human phosphatidate phosphatase LPIN3

Biomolecules such as proteins, DNA, and RNA are macromolecules and can not cross the cell membrane. However, cell-penetrating peptide (CPP) has been shown to deliver therapeutic biomolecules successfully into cells. The various and widely used CPPs including TAT, VP22, and Antp are mostly non-human originated CPPs, and are limited by their potential toxicity and immunogenicity. We report here on a newly identified novel cell-penetrating sequence (LPIN; RRKRRRRRK) from the nuclear localization sequence (NLS) of human nuclear phosphatase, LPIN3. LPIN-EGFP recombinant protein was concentration- and time-dependently delivered into cells and localized to the nucleus as well as the cytoplasm. It penetrated the cell membrane by lipid raft-mediated endocytosis by binding to heparan sulfate proteoglycan. LPIN-EGFP was successfully delivered into primary mouse splenocytes in vitro and it could be delivered into various tissues including liver, kidney, and intestine in mice after intra-peritoneal injection. This research suggests that LPIN-CPP could be used in a drug delivery system to deliver therapeutic biomolecules including peptides, proteins, DNA, and RNA and without the limitations of non-human originated CPPs such as TAT-CPP.     

Antimicrobial and cell-penetrating peptides induce lipid vesicle fusion by folding and aggregation

According to their distinct biological functions, membrane-active peptides are generally classified as antimicrobial (AMP), cell-penetrating (CPP), or fusion peptides (FP). The former two classes are known to have some structural and physicochemical similarities, but fusogenic peptides tend to have rather different features and sequences. Nevertheless, we found that many CPPs and some AMPs exhibit a pronounced fusogenic activity, as measured by a lipid mixing assay with vesicles composed of typical eukaryotic lipids. Compared to the HIV fusion peptide (FP23) as a representative standard, all designer-made peptides showed much higher lipid-mixing activities (MSI-103, MAP, transportan, penetratin, Pep1). Native sequences, on the other hand, were less fusogenic (magainin 2, PGLa, gramicidin S), and pre-aggregated ones were inactive (alamethicin, SAP). The peptide structures were characterized by circular dichroism before and after interacting with the lipid vesicles. A striking correlation between the extent of conformational change and the respective fusion activities was found for the series of peptides investigated here. At the same time, the CD data show that lipid mixing can be triggered by any type of conformation acquired upon binding, whether α-helical, β-stranded, or other. These observations suggest that lipid vesicle fusion can simply be driven by the energy released upon membrane binding, peptide folding, and possibly further aggregation. This comparative study of AMPs, CPPs, and FPs emphasizes the multifunctional aspects of membrane-active peptides, and it suggests that the origin of a peptide (native sequence or designer-made) may be more relevant to define its functional range than any given name.     

Photodamage of lipid bilayers by irradiation of a fluorescently labeled cell-penetrating peptide

Background

Fluorescently labeled cell-penetrating peptides can translocate into cells by endocytosis and upon light irradiation, lyse the endocytic vesicles. This photo-inducible endosomolytic activity of Fl–CPPs can be used to efficiently deliver macromolecules such as proteins and nucleic acids and other small organic molecules into the cytosol of live cells. The requirement of a light trigger to induce photolysis provides a more spatial and temporal control to the intracellular delivery process.

Methods

In this report, we examine the molecular level mechanisms by which cell-penetrating peptides such as TAT when labeled with small organic fluorophore molecules acquire a photo-induced lytic activity using a simplified model of lipid vesicles.

Results

The peptide TAT labeled with 5(6)-carboxytetramethylrhodamine binds to negatively charged phospholipids, thereby bringing the fluorophore in close proximity to the membrane of liposomes. Upon light irradiation, the excited fluorophore produces reactive oxygen species at the lipid bilayer and oxidation of the membrane is achieved. In addition, the fluorescent peptide causes aggregation of photo-oxidized lipids, an activity that requires the presence of arginine residues in the peptide sequence.

Conclusions

These results suggest that the cell-penetrating peptide plays a dual role. On one hand, TAT targets a conjugated fluorophore to membranes. On the other hand, TAT participates directly in the destabilization of photosensitized membranes. Peptide and fluorophore therefore appear to act in synergy to destroy membranes efficiently.

General significance

Understanding the mechanism behind Fl–CPP mediated membrane photodamage will help to design optimally photo-endosomolytic compounds.     

Newly synthesized peptide,Ara-27, exhibits significant improvement in cell-penetrating ability compared to conventional peptides

Cell-penetrating peptides (CPPs) are short amino acid sequences known to act as a vehicle for enhancing the intracellular translocating efficiency of extracellular molecules. Although many groups have attempted to develop peptides with high cell-penetrating efficiencies, very few have demonstrated efficient cellular uptake of CPPs at low concentrations. Here, we describe a newly synthesized peptide derived from Arabidopsis, Ara-27, which exhibits significant improvement in cell-penetrating efficiency compared to existing CPPs. The cell-penetrating efficiency of Ara-27 was compared with the commonly used Tat-protein transduction domain (Tat-PTD) and membrane translocating sequence (MTS) in human dermal fibroblast (HDF) and human dental pulp stem cells (hDPSC). Cell-penetrating efficiency of fluorescein isothiocyanate (FITC)-labeled CPPs were assessed by flow cytometry and visualized by confocal microscopy. Flow cytometric analysis revealed >99% cell-penetrating efficiency for 2 μM Ara-27 in both HDF and hDPSC. In contrast, 2 μM Tat-PTD and MTS showed <10% cell-penetrating efficiency in both cells. In support, relative fluorescence intensities of FITC-labeled Ara-27 were around 8 to 22 times higher than those of Tat-PTD and MTS in both cells. Confocal analysis revealed internalization of 0.2 and 2 μM Ara-27 in both human cells, which was not observed for Tat-PTD and MTS at either concentration. In conclusion, this study describes a novel CPP, Ara-27, which exhibit significant improvement in intracellular uptake compared to conventional CPPs, without affecting cell viability. Thus, development of Ara-27 based peptides may lead to improved delivery of functional cargo such as small molecules, siRNA, and drugs for in vivo studies.     

Re-evaluating the role of strongly charged sequences in amphipathic cell-penetrating peptides: a fluorescence study using Pep-1

Cell-penetrating peptides (CPPs) are able to translocate across biological membranes and deliver bioactive proteins. Cellular uptake and intracellular distribution of CPPs is commonly evaluated with fluorescent labels, which can alter peptide properties. The effect of carboxyfluorescein label in the Lys-rich domain of the amphipathic CPP pep-1, was evaluated and compared with non-labelled pep-1 in vitro and in vivo. A reduced membrane affinity and an endosomal-dependent translocation mechanism, at variance with non-labelled pep-1, were detected. Therefore, the charged domain is not a mere enabler of peptide adsorption but has a crucial role in the translocation pathway of non-labelled pep-1.     

A Cancer Specific Cell-Penetrating Peptide,BR2, for the Efficient Delivery of an scFv into Cancer Cells

Cell-penetrating peptides (CPPs) have proven very effective as intracellular delivery vehicles for various therapeutics. However, there are some concerns about non-specific penetration and cytotoxicity of CPPs for effective cancer treatments. Herein, based on the cell-penetrating motif of an anticancer peptide, buforin IIb, we designed several CPP derivatives with cancer cell specificity. Among the derivatives, a 17-amino acid peptide (BR2) was found to have cancer-specificity without toxicity to normal cells. After specifically targeting cancer cells through interaction with gangliosides, BR2 entered cells via lipid-mediated macropinocytosis. Moreover, BR2 showed higher membrane translocation efficiency than the well-known CPP Tat (49–57). The capability of BR2 as a cancer-specific drug carrier was demonstrated by fusion of BR2 to a single-chain variable fragment (scFv) directed toward a mutated K-ras (G12V). BR2-fused scFv induced a higher degree of apoptosis than Tat-fused scFv in K-ras mutated HCT116 cells. These results suggest that the novel cell-penetrating peptide BR2 has great potential as a useful drug delivery carrier with cancer cell specificity.     

综述: 细胞穿透肽及其结构改造在siRNA传递中的应用

小RNA药物应用于临床的主要技术瓶颈在于如何高效、低毒地将小RNA分子传递到它发挥功能的场所．基于细胞穿透肽在小RNA透皮给药的临床应用中所取得的进展,本文系统评述了近年来细胞穿透肽在小RNA的体内、体外传递方面的研究动态,分析了细胞穿透肽的结构改造对肽/小RNA复合物转染进入细胞发挥功能的影响,展望了细胞穿透肽作为小RNA的体内药物传递载体的发展方向．     

Membrane-active peptides and the clustering of anionic lipids

There is some overlap in the biological activities of cell-penetrating peptides (CPPs) and antimicrobial peptides (AMPs). We compared nine AMPs, seven CPPs, and a fusion peptide with regard to their ability to cluster anionic lipids in a mixture mimicking the cytoplasmic membrane of Gram-negative bacteria, as measured by differential scanning calorimetry. We also studied their bacteriostatic effect on several bacterial strains, and examined their conformational changes upon membrane binding using circular dichroism. A remarkable correlation was found between the net positive charge of the peptides and their capacity to induce anionic lipid clustering, which was independent of their secondary structure. Among the peptides studied, six AMPs and four CPPs were found to have strong anionic lipid clustering activity. These peptides also had bacteriostatic activity against several strains (particularly Gram-negative Escherichia coli) that are sensitive to lipid clustering agents. AMPs and CPPs that did not cluster anionic lipids were not toxic to E. coli. As shown previously for several types of AMPs, anionic lipid clustering likely contributes to the mechanism of antibacterial action of highly cationic CPPs. The same mechanism could explain the escape of CPPs from intracellular endosomes that are enriched with anionic lipids.     

Contributions of glycosaminoglycan binding and clustering to the biological uptake of the nonamphipathic cell-penetrating peptide WR9

Many cell-penetrating peptides (CPPs) bind to glycosaminoglycans (GAG) located on the extracellular side of biological tissues. CPP binding to the cell surface is intimately associated with clustering of surface molecules and is usually followed by uptake into the cell interior. We have investigated the uptake mechanism by comparing CPPs which bind, but cannot induce, GAG clustering with those which do induce GAG clustering. We have synthesized the tryptophan-labeled CPP nona-l-arginine (WR(9)) and its monodispersely PEGylated derivate (PEG(27)-WR(9)) and have compared them with respect to glycan binding, glycan clustering, and their uptake into living cells. Both CPPs bind to the GAG heparin with high affinity (K(D) ～ 100 nM), but the PEGylation prevents the GAG clustering. Thus, it is possible to uncouple and analyze the contributions of GAG binding and GAG clustering to the biological CPP uptake. The uptake of PEG-WR(9) into CH-K1 cells is confined to intracellular vesicles, where colocalization with transferrin attests to an endocytic uptake. Transfection experiments with plasmid DNA for GFP revealed poor GFP expression, suggesting that endocytic uptake of PEG-WR(9) is compromised by insufficient release from endocytic vesicles. In contrast, WR(9) shows two uptake routes. At low concentration (<5 μM), WR(9) uptake occurs mainly through endocytosis. At higher concentration, WR(9) uptake is greatly enhanced, showing a diffuse spreading over the entire cytoplasm and nucleus-a phenomenon termed "transduction". Transduction of WR(9) leads to a higher GFP expression as compared to PEG-WR(9) endocytosis but also damages the plasma membrane as evidenced by SYTOX Green staining. The results suggest that GAG binding without and with GAG clustering induce two different pathways of CPP uptake.     

An opportunistic route to success: Towards a change of paradigm to fully exploit the potential of cell-penetrating peptides

About 25 years ago it was demonstrated that certain peptides possess the ability to cross the plasma membrane. This led to the development of cell-penetrating peptides (CPPs) as vectors to mediate the cellular entry of (macro-)molecules that do not show cell entry by themselves. Nonetheless, in spite of an early bloom of promising pre-clinical studies, not a single CPP-based drug has been approved, yet. It is a paradigm in CPP research that the peptides are taken up by virtually all cells. In exploratory research and early preclinical development, this assumption guides the choice of the therapeutic target. However, while this indiscriminatory uptake may be the case for tissue culture experiments, in an organism this is clearly not the case. Biodistribution analyses demonstrate that CPPs only target a very limited number of cells and many tissues are hardly reached at all. Here, we review biodistribution analyses of CPPs and CPP-based drug delivery systems. Based on this analysis we propose a paradigm change towards a more opportunistic approach in CPP research. The application of CPPs should focus on those pathophysiologies for which the relevant target cells have been shown to be reached in vivo.