PEP and CADY-mediated delivery of fluorescent peptides and proteins into living cells

Cell-penetrating peptides (CPPs) constitute a family of peptides with the characteristic ability to cross biological membranes and deliver cargo into the intracellular milieu. Several CPPs have been proposed for delivery of polypeptides and proteins into cells through either of two strategies: covalent or complexed in a non-covalent fashion. Members of the PEP family are primary amphipathic peptides which have been shown to deliver peptides and proteins into a wide variety of cells through formation of non-covalent complexes. CADY is a secondary amphipathic peptide which has been demonstrated to deliver short nucleic acids, in particular siRNA with high efficiency. Here we review the characteristics of the PEP and CADY carriers and describe a novel derivative of CADY termed CADY2, which also presents sequence similarities to Pep1. We have compared Pep1, CADY and CADY2 in their efficiency to interact with and internalize short fluorogenic peptides and proteins into cultured cells, and provide evidence that CADY2 can interact with proteins and peptides and deliver them efficiently into living cells, similar to Pep1, but in contrast to CADY which is unable to deliver any peptide, even short negatively charged peptides. This is the first study to investigate the influence of the cargo on the interactions between PEP and CADY carriers, thereby providing novel insights into the physicochemical parameters underlying interactions and cellular uptake of peptides and proteins by these non-covalent CPPs.     

Biophysical and biological studies of end-group-modified derivatives of Pep-1

Pep-1 is a tryptophane-rich cell-penetrating peptide (CPP) that has been previously proposed to bind protein cargoes by hydrophobic assembly and translocate them across cellular membranes. To date, however, the molecular mechanisms responsible for cargo binding and translocation have not been clearly identified. This study was conducted to gain insight into the interaction between Pep-1 with its cargo and the biological membrane to identify the thereby involved structural elements crucial for translocation. We studied three peptides differing in their N- and C-termini: (i) Pep-1, carrying an acetylated N-terminus and a C-terminal cysteamine elongation, (ii) AcPepWAmide, with an acetylated N-terminus and an amidated C-terminus, and (iii) PepW, with two free termini. Thioredoxin (TRX) and beta-galactosidase were used as protein cargoes. To study CPP-membrane interactions, we performed biophysical as well as biological assays. To mimic biological membranes, we used phospholipid liposomes in a dye leakage assay and surfactant micelles for high-resolution NMR studies. In addition, membrane integrity, cell viability, and translocation efficiency were analyzed in HeLa cells. An alpha-helical structure was found for all peptides in the hydrophobic N-terminal region encompassing residues 4-13, whereas the hydrophilic region remained unstructured in the presence of micelles. Our results show that the investigated peptides interacted with the micelles as well as with the protein cargo via their tryptophan-rich domain. All peptides displayed an orientation parallel to the micelle surface. The C-terminal cysteamine group formed an additional membrane anchor, leading to more efficient translocation properties in cells. No membrane permeabilization was observed, and our data were largely compatible with an endocytic pathway for cellular uptake.     

细胞穿透肽:一种新型非病毒载体

细胞膜的选择通透性对维持细胞内环境的稳定起着非常重要的作用,但细胞膜的这种特性限制了一些生物大分子和药物进入细胞内,不利于对一些细胞内疾病的诊断和药物靶向治疗的应用。如何将一些具有诊断和治疗潜力的生物大分子、药物通过细胞膜进入细胞内一直是医学界研究的热点和难点。细胞穿透肽是一类能够携带多肽、蛋白质、核酸、纳米颗粒、病毒颗粒及药物等穿过细胞膜进入细胞,导致完整载物内化的短肽,为生物大分子和药物进入细胞内部提供了有力的运载工具,其作为载体具有的高转导效率和低毒性特点,已经得到了广泛关注和大量研究。目前,细胞穿透肽作为生物分子和药物细胞内化的运载体已经在荧光成像,肿瘤治疗,抗炎治疗及药物靶向治疗中发挥了潜在的诊断和治疗作用,显示出其诱人的应用前景。     

Insight into the mechanism of internalization of the cell-penetrating carrier peptide Pep-1 through conformational analysis

Recently, we described a new strategy for the delivery of proteins and peptides into mammalian cells, based on an amphipathic peptide of 21 residues, Pep-1, which was designed on the basis of a protein-interacting domain associated with a nuclear localization sequence and separated by a linker. This peptide carrier constitutes a powerful tool for the delivery of active proteins or peptides both in cultured cells and in vivo, without requiring any covalent coupling. We have examined the conformational states of Pep-1 in its free form and complexed with a cargo peptide and have investigated their ability to interact with phospholipids and the structural consequences of these interactions. From the conformational point of view, Pep-1 behaves significantly differently from other similarly designed cell-penetrating peptides. CD analysis revealed a transition from a nonstructured to a helical conformation upon increase of the concentration. Determination of the structure by NMR showed that in water, its alpha-helical domain extends from residues 4-13. CD and FTIR indicate that Pep-1 adopts a helical conformation in the presence of phospholipids. Adsorption measurements performed at the air-water interface are consistent with the helical form. Pep-1 does not undergo conformational changes upon formation of a particle with a cargo peptide. In contrast, we observe a partial conformational transition when the complex encounters phospholipids. We propose that the membrane crossing process involves formation of a transient transmembrane pore-like structure. Conformational change of Pep-1 is not associated with complexation with its cargo but is induced upon association with the cell membrane.     

Novel Fatty Acid Modifications of Transportan 10

Cell-penetrating peptides (CPPs) are able to efficiently internalize into cells and can therefore be used as vectors for non-viral cellular delivery of different cargoes. Previous studies have shown that hydrophobic modifications of different CPPs can increase their transfection efficiency dramatically. In this study we have modified the cell penetrating-peptide transportan 10 (TP10) with a variety of hydrophobic molecules to determine the role of hydrophobicity in the uptake of these molecules. The results can be used to synthesize more efficient delivery vectors. To evaluate how these constructs are able to transport cargoes into cells we used 2′-OMe splice correcting oligonucleotides. Non-covalent peptide-cargo complexes were formed and their transfection efficiency was measured using a luciferase readout system. The hydrophobicity of the novel modifications was correlated with their biological efficacy. We determined the most efficient range of hydrophobicity for TP10 analogs for delivering oligonucleotides into cells. In order to assess how the transfection efficacy of these particles is dependent on their size the hydrodynamic diameter of the formed nanoparticles was measured using dynamic light scattering. These findings will be used to develop highly efficient non-viral gene therapy vectors.     

Refinement of a Quantitative Structure–Activity Relationship Model for Prediction of Cell-Penetrating Peptide Based Transfection Systems

Cell-penetrating peptide (CPP) based transfection systems (PBTS) are a promising class of drug delivery vectors. CPPs are short mainly cationic peptides capable of delivering cell non-permeant cargo to the interior of the cell. Some CPPs have the ability to form non-covalent complexes with oligonucleotides for gene therapy applications. In this study, we use quantitative structure–activity relationships (QSAR) , a statistical method based on regression data analysis. Here, an fragment QSAR (FQSAR) model is developed to predict new peptides based on standard alpha helical conformers and Assisted Model Building with Energy Refinement molecular mechanics simulations of previous peptides. These new peptides were examined for plasmid transfection efficiency and compared with their predicted biological activity. The best predicted peptides were capable of achieving plasmid transfection with significant improvement compared to the previous generation of peptides. Our results demonstrate that FQSAR model refinement is an efficient method for optimizing PBTS for improved biological activity.     

Cellular delivery of small interfering RNA by a non-covalently attached cell-penetrating peptide: quantitative analysis of uptake and biological effect

Cell-penetrating peptides (CPPs) have evolved as promising new tools to deliver nucleic acids into cells. So far, the majority of these delivery systems require a covalent linkage between carrier and cargo. To exploit the higher flexibility of a non-covalent strategy, we focused on the characterisation of a novel carrier peptide termed MPGα, which spontaneously forms complexes with nucleic acids. Using a luciferase-targeted small interfering RNA (siRNA) as cargo, we optimised the conditions for MPGα-mediated transfection of mammalian cells. In this system, reporter gene activity could be inhibited up to 90% with an IC₅₀ value in the sub-nanomolar range. As a key issue, we addressed the cellular uptake mechanism of MPGα/siRNA complexes applying various approaches. First, transfection of HeLa cells with MPGα/siRNA complexes in the presence of several inhibitors of endocytosis showed a significant reduction of the RNA interference (RNAi) effect. Second, confocal laser microscopy revealed a punctual intracellular pattern rather than a diffuse distribution of fluorescently labelled RNA-cargo. These data provide strong evidence of an endocytotic pathway contributing significantly to the uptake of MPGα/siRNA complexes. Finally, we quantified the intracellular number of siRNA molecules after MPGα-mediated transfection. The amount of siRNA required to induce half maximal RNAi was 10000 molecules per cell. Together, the combination of methods provided allows for a detailed side by side quantitative analysis of cargo internalisation and related biological effects. Thus, the overall efficiency of a given delivery technique as well as the mechanism of uptake can be assessed.     

Endocytic Trafficking of Nanoparticles Delivered by Cell-penetrating Peptides Comprised of Nona-arginine and a Penetration Accelerating Sequence

Cell-penetrating peptides (CPPs) can traverse cellular membranes and deliver biologically active molecules into cells. In this study, we demonstrate that CPPs comprised of nona-arginine (R9) and a penetration accelerating peptide sequence (Pas) that facilitates escape from endocytic lysosomes, denoted as PR9, greatly enhance the delivery of noncovalently associated quantum dots (QDs) into human A549 cells. Mechanistic studies, intracellular trafficking analysis and a functional gene assay reveal that endocytosis is the main route for intracellular delivery of PR9/QD complexes. Endocytic trafficking of PR9/QD complexes was monitored using both confocal and transmission electron microscopy (TEM). Zeta-potential and size analyses indicate the importance of electrostatic forces in the interaction of PR9/QD complexes with plasma membranes. Circular dichroism (CD) spectroscopy reveals that the secondary structural elements of PR9 have similar conformations in aqueous buffer at pH 7 and 5. This study of nontoxic PR9 provides a basis for the design of optimized cargo delivery that allows escape from endocytic vesicles.     

A non-covalent peptide-based carrier for in vivo delivery of DNA mimics

The dramatic acceleration in identification of new nucleic-acid-based therapeutic molecules has provided new perspectives in pharmaceutical research. However, their development is limited by their poor cellular uptake and inefficient trafficking. Here we describe a short amphipathic peptide, Pep-3, that combines a tryptophan/phenylalanine domain with a lysine/arginine-rich hydrophilic motif. Pep-3 forms stable nano-size complexes with peptide-nucleic acid analogues and promotes their efficient delivery into a wide variety of cell lines, including primary and suspension lines, without any associated cytotoxicity. We demonstrate that Pep-3-mediated delivery of antisense-cyclin B1-charged-PNA blocks tumour growth in vivo upon intratumoral and intravenous injection. Moreover, we show that PEGylation of Pep-3 significantly improves complex stability in vivo and consequently the efficiency of antisense cyclin B1 administered intravenously. Given the biological characteristics of these vectors, we believe that peptide-based delivery technologies hold a true promise for therapeutic applications of DNA mimics.     

Delivery of HIV-1 Nef Protein in Mammalian Cells Using Cell Penetrating Peptides as a Candidate Therapeutic Vaccine

The HIV-1 Nef protein expressed early in viral life cycle has been known as a potent candidate for therapeutic vaccine development. Due to different cell barriers, various cell penetrating peptides (CPPs) such as Pep-1 and CADY-2 have been known to deliver biologically active proteins to cytoplasmic compartments via the plasma membrane. In current study, we firstly evaluated the efficiency of lentiviral vector (pCDH-CMV-MCS-EF1-cGFP-T2A-puro) and eukaryotic expression vector (pEGFP-N1) for expression of HIV-1 Nef protein in HEK-293T cells using TurboFect transfection reagent. Our results showed that both vectors can effectively express the Nef proteins within the target cell. The pEGFP-N1 was more effective than pCDH-GFP for protein expression. Furthermore, Nef protein was expressed in E. coli as GST-Nef fusion and transfected by the amphipathic CPPs including Pep-1 and CADY-2 into HEK-293T cells. The size and morphology of the GST-Nef/CPP complexes were evaluated by scanning electron microscopy, and Zetasizer. Our data indicated that the recombinant GST-Nef protein generated in BL21 strain migrated as a clear band of ~50 kDa in SDS-PAGE. The CPP/GST-Nef nanoparticles were formed with a diameter of below 200 nm and notably delivered into HEK-293T cells. Generally, the Nef protein was expressed in prokaryotic and eukaryotic expression systems using different vectors and efficiently transfected in mammalian cells using various delivery systems. The in vitro efficient delivery of HIV-1 Nef gene and also its protein supports the potential of Nef DNA constructs and CPPs as potent carriers of Nef protein for HIV vaccine design in Future.     

The Neuroprotective Efficacy of Cell-Penetrating Peptides TAT,Penetratin, Arg-9, and Pep-1 in Glutamic Acid,Kainic Acid,and In Vitro Ischemia Injury Models Using Primary Cortical Neuronal Cultures

Cell-penetrating peptides (CPPs) are small peptides (typically 5–25 amino acids), which are used to facilitate the delivery of normally non-permeable cargos such as other peptides, proteins, nucleic acids, or drugs into cells. However, several recent studies have demonstrated that the TAT CPP has neuroprotective properties. Therefore, in this study, we assessed the TAT and three other CPPs (penetratin, Arg-9, Pep-1) for their neuroprotective properties in cortical neuronal cultures following exposure to glutamic acid, kainic acid, or in vitro ischemia (oxygen–glucose deprivation). Arg-9, penetratin, and TAT-D displayed consistent and high level neuroprotective activity in both the glutamic acid (IC50: 0.78, 3.4, 13.9 μM) and kainic acid (IC50: 0.81, 2.0, 6.2 μM) injury models, while Pep-1 was ineffective. The TAT-D isoform displayed similar efficacy to the TAT-L isoform in the glutamic acid model. Interestingly, Arg-9 was the only CPP that displayed efficacy when washed-out prior to glutamic acid exposure. Neuroprotection following in vitro ischemia was more variable with all peptides providing some level of neuroprotection (IC50; Arg-9: 6.0 μM, TAT-D: 7.1 μM, penetratin/Pep-1: >10 μM). The positive control peptides JNKI-1D-TAT (JNK inhibitory peptide) and/or PYC36L-TAT (AP-1 inhibitory peptide) were neuroprotective in all models. Finally, in a post-glutamic acid treatment experiment, Arg-9 was highly effective when added immediately after, and mildly effective when added 15 min post-insult, while the JNKI-1D-TAT control peptide was ineffective when added post-insult. These findings demonstrate that different CPPs have the ability to inhibit neurodamaging events/pathways associated with excitotoxic and ischemic injuries. More importantly, they highlight the need to interpret neuroprotection studies when using CPPs as delivery agents with caution. On a positive note, the cytoprotective properties of CPPs suggests they are ideal carrier molecules to deliver neuroprotective drugs to the CNS following injury and/or potential neuroprotectants in their own right.     

Single-molecule imaging of the association of the cell-penetrating peptide Pep-1 to model membranes

Pep-1 is an amphiphatic peptide that can form noncovalent complexes with a cargo protein with subsequent delivery into a live cell. In this study, the behavior of Pep-1 was directly visualized by fluorescent imaging techniques at the single-molecule level of sensitivity. The interactions of Pep-1 and two of its labeled fluorescent analogues with large and cell-sized giant unilamellar vesicles and supported bilayers are reported. The role of the bilayer charge and ionic strength of the medium were examined. Pep-1 caused fusion and association of vesicles, and it perturbed the vesicle's membrane. The association of the peptide with neutral bilayers was promoted by anchoring of the cysteamine moiety. The association of the peptide with the structural defects of the neutral membrane was very efficient. The electrostatic forces were shown to be important for the association of the peptide only in low ionic strength solutions and were completely diminished at physiological ionic strength. Pep-1 did not induce the association to the model membrane of a number of proteins chosen to exhibit a range of properties. The results suggest that Pep-1 assisted delivery of cargo in living cells may result from cooperative effects.     

A novel human derived cell-penetrating peptide in drug delivery

Cell-penetrating peptides can carry a variety of biologically active molecules into cells. Here we have identified a novel CPP derived from the C-terminus of human extracellular superoxide dismutase (hC-SOD3) which was shown to be located throughout in the cytoplasm and nucleus by fluorescence microscopy investigation. Furthermore, when apoptin fused to hC-SOD3, it was translocated efficiently into HeLa cells resulting in antitumor activities. This study shows that hC-SOD3 has the potential to penetrate and translocate cargo molecules into cells and has no cytotoxicity at effective concentration.     

Identification and characterization of a novel cell-penetrating peptide of 30Kc19 protein derived from Bombyx mori

Cell-penetrating peptides (CPPs) or protein transduction domains (PTDs) have attracted increasing attention due to their high potential to deliver various, otherwise impermeable, bioactive agents, such as drugs and proteins across cell membranes. A number of CPPs have been discovered since then. Recently, 30Kc19 protein has attracted attention because it was the first cell-penetrating protein that has been found in insect hemolymph. Here, we report a cell-penetrating peptide derived from 30Kc19 protein, VVNKLIRNNKMNC, which efficiently penetrates cells when supplemented to medium for mammalian cell culture. Moreover, like other CPPs, this “Pep-c19” also efficiently delivered cell-impermeable cargo proteins, such as green fluorescent protein (GFP) into cells. In addition to the in vitro system, Pep-c19 exhibited the cell-penetrating property in vivo. When Pep-c19 was intraperitoneally injected into mice, Pep-c19 successfully delivered cargo proteins into various organ tissues with higher efficiency than the 30Kc19 protein itself, and without toxicity. Our data demonstrates that Pep-c19 has a great potential as a cell-penetrating peptide that can be used as a therapeutic tool to efficiently deliver different cell-impermeable cargo molecules into the tissues of various organs.     

Glycosylated cell-penetrating peptides and their conjugates to a proapoptotic peptide: preparation by click chemistry and cell viability studies

Cell-penetrating peptides (CPPs), which are usually short basic peptides, are able to cross cell membranes and convey bioactive cargoes inside cells. CPPs have been widely used to deliver inside cells peptides, proteins, and oligonucleotides; however, their entry mechanisms still remain controversial. A major problem concerning CPPs remains their lack of selectivity to target a specific type of cell and/or an intracellular component. We have previously shown that myristoylation of one of these CPPs affected the intracellular distribution of the cargo. We report here on the synthesis of glycosylated analogs of the cell-penetrating peptide (R6/W3): Ac-RRWWRRWRR-NH₂. One, two, or three galactose(s), with or without a spacer, were introduced into the sequence of this nonapeptide via a triazole link, the Huisgen reaction being achieved on a solid support. Four of these glycosylated CPPs were coupled via a disulfide bridge to the proapoptotic KLAK peptide, (KLAKLAKKLAKLAK), which alone does not enter into cells. The effect on cell viability and the uptake efficiency of different glycosylated conjugates were studied on CHO cells and were compared to those of the nonglycosylated conjugates: (R6/W3)S-S-KLAK and penetratinS-S-KLAK. We show that glycosylation significantly increases the cell viability of CHO cells compared to the nonglycosylated conjugates and concomitantly decreases the internalization of the KLAK cargo. These results suggest that glycosylation of CPP may be a key point in targeting specific cells.     

穿膜肽的内化机制及其应用

穿膜肽是一类具有特殊穿膜功能的多肽分子,能携带其它分子甚至超分子颗粒穿膜进入细胞内部．早期研究认为,其进胞是一种无需受体、也不存在饱和状态的非经典胞吞行为．近年研究表明,其穿膜机制可能与其含有的氨基酸种类有很大关系．现在,穿膜肽的穿膜过程称为巨型胞饮行为,它与传统的胞吞形式很相似．当然,还可能存在着其它的进胞方式而没有被证明或发现．关于穿膜肽的应用也是人们最感兴趣的,在很多领域的研究都在进行并不断取得进展．不论是生物界还是医学界,穿膜肽都被认为将是一类非常有发展潜力的多肽分子．     

Delivery of Nucleic Acids, Proteins, and Nanoparticles by Arginine-Rich Cell-Penetrating Peptides in Rotifers

Cell-penetrating peptides (CPPs) are a group of short, membrane-permeable cationic peptides that represent a nonviral technology for delivering nanomaterials and macromolecules into live cells. In this study, two arginine-rich CPPs, HR9 and IR9, were found to be capable of entering rotifers. CPPs were able to efficiently deliver noncovalently associated with cargoes, including plasmid DNAs, red fluorescent proteins (RFPs), and semiconductor quantum dots, into rotifers. The functional reporter gene assay demonstrated that HR9-delivered plasmid DNAs containing the enhanced green fluorescent protein and RFP coding sequences could be actively expressed in rotifers. The 1-(4,5-dimethylthiazol-2-yl)-3,5-diphenylformazan assay further confirmed that CPP-mediated cargo delivery was not toxic to rotifers. Thus, these two CPPs hold a great potential for the delivery of exogenous genes, proteins, and nanoparticles in rotifers.     

Comparison of the interaction,positioning, structure induction and membrane perturbation of cell-penetrating peptides and non-translocating variants with phospholipid vesicles

Cell-penetrating peptides (CPPs) are able to translocate and carry cargo molecules across cell membranes. Using fluorescence techniques (polarization and quenching) and CD spectroscopy we studied the interaction, conformation and topology of two such peptides, transportan and 'penetratin' (pAntp), and two variants of differing translocating abilities, with small phospholipid vesicles of varying charge density. The induced structure of transportan is always helical independent of vesicle surface charge. pAntp and its two variants interact significantly only with negatively charged vesicles. The induced secondary structure depends on membrane charge and lipid/peptide ratio. The degree of membrane perturbation, evidenced by fluorescence polarization, of pAntp and its variants is related to their secondary structure. In the helical state, the peptides have little effect on the membrane. Under conditions where pAntp and its variants are converted into beta-structures, they cause membrane perturbation. Oriented CD suggests that the two CPPs (pAntp and transportan) in their helical state lie along the vesicle surface, while the two pAntp variants appear to penetrate deeper into the membrane.     

Cell-penetrating peptides: from molecular mechanisms to therapeutics

The recent discovery of new potent therapeutic molecules which do not reach the clinic due to poor delivery and low bioavailability have made the delivery of molecules a keystone in therapeutic development. Several technologies have been designed to improve cellular uptake of therapeutic molecules, including CPPs (cell-penetrating peptides), which represent a new and innovative concept to bypass the problem of bioavailability of drugs. CPPs constitute very promising tools and have been successfully applied for in vivo. Two CPP strategies have been described to date; the first one requires chemical linkage between the drug and the carrier for cellular drug internalization, and the second is based on the formation of stable complexes with drugs, depending on their chemical nature. The Pep and MPG families are short amphipathic peptides, which form stable nanoparticles with proteins and nucleic acids respectively. MPG- and Pep-based nanoparticles enter cells independently of the endosomal pathway and efficiently deliver cargoes, in a fully biologically active form, into a large variety of cell lines, as well as in animal models. This review focuses on the structure-function relationship of non-covalent MPG and Pep-1 strategies, and their requirement for cellular uptake of biomolecules and applications in cultured cells and animal models.     

A plasmid display platform for the selection of peptides exhibiting a functional cell-penetrating phenotype

Cell-penetrating peptides (CPPs) represent a promising nonviral platform for the delivery of therapeutic cargos to cells and tissues. However, these peptides are often nonspecific, and their mechanism of action is still a subject of debate, which hinders the design of new CPPs. The alternative to rational protein design is the combinatorial approach to protein engineering, whereby large libraries of peptides are created and a screening or selection procedure is used to identify members with the desired phenotype(s). Here we describe a novel procedure for selecting peptides with a CPP phenotype using a plasmid display (PD) platform to link the peptides to their encoding DNA sequences. The PD system is based on genetic fusions to a DNA binding domain. The plasmid was designed to concomitantly express a fluorescent reporter protein to serve as a mock therapeutic cargo indicating its functional delivery into a cell. We have demonstrated this selection strategy using a control CPP (the TAT peptide) in the PC12 neuronal-like cell line. In the absence of transfection reagents, TAT was unable to deliver the protein/DNA complexes. The inclusion of the HA2 peptide from the hemagglutinin protein and the addition of polyethylenimine (PEI) were similarly ineffective. The addition of Lipofectamine, however, enabled the TAT-mediated delivery of the protein/DNA complexes, which was significantly better than control experiments without a CPP. This new PD selection platform will be a valuable new approach for use in identifying unique CPPs from randomized libraries with novel abilities and specificities.