Translocation of cell‐penetrating peptides into Candida fungal pathogens

Cell‐penetrating peptides (CPPs) are small peptides capable of crossing cellular membranes while carrying molecular cargo. Although they have been widely studied for their ability to translocate nucleic acids, small molecules, and proteins into mammalian cells, studies of their interaction with fungal cells are limited. In this work, we evaluated the translocation of eleven fluorescently labeled peptides into the important human fungal pathogens Candida albicans and C. glabrata and explored the mechanisms of translocation. Seven of these peptides (cecropin B, penetratin, pVEC, MAP, SynB, (KFF)₃K, and MPG) exhibited substantial translocation (>80% of cells) into both species in a concentration‐dependent manner, and an additional peptide (TP‐10) exhibiting strong translocation into only C. glabrata. Vacuoles were involved in translocation and intracellular trafficking of the peptides in the fungal cells and, for some peptides, escape from the vacuoles and localization in the cytosol were correlated to toxicity toward the fungal cells. Endocytosis was involved in the translocation of cecropin B, MAP, SynB, MPG, (KFF)₃K, and TP‐10, and cecropin B, penetratin, pVEC, and MAP caused membrane permeabilization during translocation. These results indicate the involvement of multiple translocation mechanisms for some CPPs. Although high levels of translocation were typically associated with toxicity of the peptides toward the fungal cells, SynB was translocated efficiently into Candida cells at concentrations that led to minimal toxicity. Our work highlights the potential of CPPs in delivering antifungal molecules and other bioactive cargo to Candida pathogens.     

pVEC hydrophobic N‐terminus is critical for antibacterial activity

Cell‐penetrating peptides (CPPs) are commonly defined by their shared ability to be internalized into eukaryotic cells, without inducing permanent membrane damage, and to improve cargo delivery. Many CPPs also possess antimicrobial action strong enough to selectively lyse microbes in infected mammalian cultures. pVEC, a CPP derived from cadherin, is able to translocate into mammalian cells, and it is also antimicrobial. Structure‐activity relationship and sequence alignment studies have suggested that the hydrophobic N‐terminus (LLIIL) of pVEC is essential for this peptide's uptake into eukaryotic cells. In this study, our aim was to examine the contribution of these residues to the antimicrobial action and the translocation mechanism of pVEC. We performed antimicrobial activity and microscopy experiments with pVEC and with del5 pVEC (N‐terminal truncated variant of pVEC) and showed that pVEC loses its antimicrobial effect upon deletion of the LLIIL residues, even though both peptides induce membrane permeability. We also calculated the free energy of the transport process using steered molecular dynamic simulations and replica exchange umbrella sampling simulations to compare the difference in uptake mechanism of the 2 peptides in atomistic detail. Despite the difference in experimentally observed antimicrobial activity, the simulations on the 2 peptides showed similar characteristics and the energetic cost of translocation of pVEC was higher than that of del5 pVEC, suggesting that pVEC uptake mechanism cannot be explained by simple passive transport. Our results suggest that LLIIL residues are key contributors to pVEC antibacterial activity because of irreversible membrane disruption.     

Bilayer interaction and localization of cell penetrating peptides with model membranes: a comparative study of a human calcitonin (hCT)-derived peptide with pVEC and pAntp(43-58)

Cell-penetrating peptides (CPPs) are able to translocate problematic therapeutic cargoes across cellular membranes. The exact mechanisms of translocation are still under investigation. However, evidence for endocytic uptake is increasing. We investigated the interactions of CPPs with phospholipid bilayers as first step of translocation. To this purpose, we employed four independent techniques, comprising (i) liposome buffer equilibrium dialysis, (ii) Trp fluorescence quenching, (iii) fluorescence polarization, and (iv) determination of zeta-potentials. Using unilamellar vesicles (LUVs) of different phospholipid composition, we compared weakly cationic human calcitonin (hCT)-derived peptides with the oligocationic CPPs pVEC and penetratin (pAntp). Apparent partition coefficients of hCT-derived peptides in neutral POPC LUVs were dependent on amino acid composition and secondary structure; partitioning in negatively charged POPC/POPG (80:20) LUVs was increased and mainly governed by electrostatic interactions. For hCT(9-32) and its derivatives, D values raised from about 100-200 in POPC to about 1000 to 1500 when negatively charged lipids were present. Localization profiles of CPPs obtained by Trp fluorescence quenching were dependent on the charge density of LUVs. In POPC/POPG, hCT-derived CPPs were located on the bilayer surface, whereas pVEC and pAntp resided deeper in the membrane. In POPG LUVs, an increase of fluorescence polarization was observed for pVEC and pAntp but not for hCT-derived peptides. Generally, we found strong peptide-phospholipid interactions, especially when negatively charged lipids were present.     

Bilayer interaction and localization of cell penetrating peptides with model membranes: A comparative study of a human calcitonin (hCT)-derived peptide with pVEC and pAntp(43-58)

Cell-penetrating peptides (CPPs) are able to translocate problematic therapeutic cargoes across cellular membranes. The exact mechanisms of translocation are still under investigation. However, evidence for endocytic uptake is increasing. We investigated the interactions of CPPs with phospholipid bilayers as first step of translocation. To this purpose, we employed four independent techniques, comprising (i) liposome buffer equilibrium dialysis, (ii) Trp fluorescence quenching, (iii) fluorescence polarization, and (iv) determination of ζ-potentials. Using unilamellar vesicles (LUVs) of different phospholipid composition, we compared weakly cationic human calcitonin (hCT)-derived peptides with the oligocationic CPPs pVEC and penetratin (pAntp). Apparent partition coefficients of hCT-derived peptides in neutral POPC LUVs were dependent on amino acid composition and secondary structure; partitioning in negatively charged POPC/POPG (80:20) LUVs was increased and mainly governed by electrostatic interactions. For hCT(9-32) and its derivatives, D values raised from about 100-200 in POPC to about 1000 to 1500 when negatively charged lipids were present. Localization profiles of CPPs obtained by Trp fluorescence quenching were dependent on the charge density of LUVs. In POPC/POPG, hCT-derived CPPs were located on the bilayer surface, whereas pVEC and pAntp resided deeper in the membrane. In POPG LUVs, an increase of fluorescence polarization was observed for pVEC and pAntp but not for hCT-derived peptides. Generally, we found strong peptide-phospholipid interactions, especially when negatively charged lipids were present.     

VE-cadherin-derived cell-penetrating peptide, pVEC, with carrier functions

Cell-penetrating peptides, CPPs, have been shown to translocate into living cells by a receptor-independent mechanism and to carry macromolecules over the plasma membrane. This article reports studies of the internalization of pVEC, an 18-amino acid-long peptide derived from the murine sequence of the cell adhesion molecule vascular endothelial cadherin, amino acids 615-632. Fluorophore-labeled pVEC entered four different cell lines tested: human aortic endothelial cells, brain capillary endothelial cells, Bowes melanoma cells, and murine brain endothelial cells. In order to evaluate the translocation efficiency of pVEC, we performed a side-by-side comparison with penetratin, a well-characterized CPP. The cellular uptake of pVEC was highest for murine brain endothelial cells. All cell lines tested contained equal or slightly higher concentrations of pVEC than penetratin. pVEC mainly accumulated in nuclear structures but was also found throughout the cells. Furthermore, pVEC functioned as a transporter of both a hexameric peptide nucleic acid molecule of 1.7 kDa and a 67-kDa protein, streptavidin-FITC, and cellular uptake of fluorophore-labeled pVEC took place at 4 degrees C, suggesting a nonendocytotic mechanism of translocation. In conclusion, our results indicate that pVEC is efficiently and rapidly taken up into cells and functions as a potent carrier peptide.     

Internalisation of cell-penetrating peptides into tobacco protoplasts

Cells are protected from the surrounding environment by plasma membrane which is impenetrable for most hydrophilic molecules. In the last 10 years cell-penetrating peptides (CPPs) have been discovered and developed. CPPs enter mammalian cells and carry cargo molecules over the plasma membrane with a molecular weight several times their own. Known transformation methods for plant cells have relatively low efficiency and require improvement. The possibility to use CPPs as potential delivery vectors for internalisation in plant cells has been studied in the present work. We analyse and compare the uptake of the fluorescein-labeled CPPs, transportan, TP10, penetratin and pVEC in Bowes human melanoma cells and Nicotiana tabacum cultivar (cv.) SR-1 protoplasts (plant cells without cell wall). We study the internalisation efficiency of CPPs with fluorescence microscopy, spectrofluorometry and fluorescence-activated cell sorter (FACS). All methods indicate, for the first time, that these CPPs can internalise into N. tabacum cv. SR-1 protoplasts. Transportan has the highest uptake efficacy among the studied peptides, both in mammalian cells and plant protoplast. The internalisation of CPPs by plant protoplasts may open up a new effective method for transfection in plants.     

Binding of cell-penetrating penetratin peptides to plasma membrane vesicles correlates directly with cellular uptake

Cell-penetrating peptides (CPPs) gain access to intracellular compartments mainly via endocytosis and have capacity to deliver macromolecular cargo into cells. Although the involvement of various endocytic routes has been described it is still unclear which interactions are involved in eliciting an uptake response and to what extent affinity for particular cell surface components may determine the efficiency of a particular CPP. Previous biophysical studies of the interaction between CPPs and either lipid vesicles or soluble sugar-mimics of cell surface proteoglycans, the two most commonly suggested CPP binding targets, have not allowed quantitative correlations to be established. We here explore the use of plasma membrane vesicles (PMVs) derived from cultured mammalian cells as cell surface models in biophysical experiments. Further, we examine the relationship between affinity for PMVs and uptake into live cells using the CPP penetratin and two analogs enriched in arginines and lysines respectively. We show, using centrifugation to sediment PMVs, that the amount of peptide in the pellet fraction correlates linearly with the degree of cell internalization and that the relative efficiency of all-arginine and all-lysine variants of penetratin can be ascribed to their respective cell surface affinities. Our data show differences between arginine- and lysine-rich variants of penetratin that has not been previously accounted for in studies using lipid vesicles. Our data also indicate greater differences in binding affinity to PMVs than to heparin, a commonly used cell surface proteoglycan mimic. Taken together, this suggests that the cell surface interactions of CPPs are dependent on several cell surface moieties and their molecular organization on the plasma membrane.     

Uptake of cell-penetrating peptides in yeasts

The uptake of different cell-penetrating peptides (CPPs) in two yeast species, Saccharomyces cerevisiae and Candida albicans, was studied using fluorescence HPLC-analyses of cell content. Comparison of the ability of penetratin, pVEC and (KFF)(3)K to traverse the yeast cell envelope shows that the cellular uptake of the peptides varies widely. Moreover, the intracellular degradation of the CPPs studied varies from complete stability to complete degradation. We show that intracellular degradation into membrane impermeable products can significantly contribute to the fluorescence signal. pVEC displayed highest internalizing capacity, and considering its stability in both yeast species, it is an attractive candidate for further studies.     

Quantitatively determined uptake of cell-penetrating peptides in non-mammalian cells with an evaluation of degradation and antimicrobial effects

Cell-penetrating peptides (CPPs) are carriers developed to improve mammalian cell uptake of important research tools such as antisense oligonucleotides and short interfering RNAs. However, the data on CPP uptake into non-mammalian cells are limited. We have studied the uptake and antimicrobial effects of the three representative peptides penetratin (derived from a non-mammalian protein), MAP (artificial peptide) and pVEC (derived from a mammalian protein) using fluorescence HPLC in four common model systems: insect cells (Sf9), gram-positive bacteria (Bacillus megaterium), gram-negative bacteria (Escherichia coli) and yeast (Saccharomyces cerevisiae). We demonstrate that non-mammalian cells internalize CPPs and a comparison of the uptake of the peptides show that the intracellular concentration and degradation of the peptides varies widely among organisms. In addition, these CPPs showed antimicrobial activity.     

Alternative Mechanisms for the Interaction of the Cell-Penetrating Peptides Penetratin and the TAT Peptide with Lipid Bilayers

Cell-penetrating peptides (CPPs) have recently attracted much interest due to their apparent ability to penetrate cell membranes in an energy-independent manner. Here molecular-dynamics simulation techniques were used to study the interaction of two CPPs: penetratin and the TAT peptide with 1,2-Dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) phospolipid bilayers shed light on alternative mechanisms by which these peptides might cross biological membranes. In contrast to previous simulation studies of charged peptides interacting with lipid bilayers, no spontaneous formation of transmembrane pores was observed. Instead, the simulations suggest that the peptides may enter the cell by micropinocytosis, whereby the peptides induce curvature in the membrane, ultimately leading to the formation of small vesicles within the cell that encapsulate the peptides. Specifically, multiple peptides were observed to induce large deformations in the lipid bilayer that persisted throughout the timescale of the simulations (hundreds of nanoseconds). Pore formation could be induced in simulations in which an external potential was used to pull a single penetratin or TAT peptide into the membrane. With the use of umbrella-sampling techniques, the free energy of inserting a single penetratin peptide into a DPPC bilayer was estimated to be ∼75 kJmol⁻¹, which suggests that the spontaneous penetration of single peptides would require a timescale of at least seconds to minutes. This work also illustrates the extent to which the results of such simulations can depend on the initial conditions, the extent of equilibration, the size of the system, and the conditions under which the simulations are performed. The implications of this with respect to the current systems and to simulations of membrane-peptide interactions in general are discussed.     

Investigation of penetratin peptides. Part 2. In vitro uptake of penetratin and two of its derivatives

As endocytic uptake of the Antennapedia homeodomain‐derived penetratin peptide (RQIKIWFQNRRMKWKK) is finally being revealed, some of the early views about penetratin need to be reconsidered. Endocytic uptake seems to contradict the indispensability of tryptophans and also the minimum length of 16 amino acid residues for efficient internalization. To revise the membrane translocation of penetratin, two penetratin analogs were designed and synthesized: a peptide in which tryptophans were replaced by phenylalanines (Phe^{6, 14}‐penetratin, RQIKI F FQNRRMK F KK) and a shortened analog (dodeca‐penetratin, RQIKIWF‐R‐KWKK) made up of only 12 residues. The peptides were fluorescently labeled and applied to live, unfixed cells from various lines. Cellular uptake was analysed by confocal microscopy and flow cytometry. Low temperature or ATP‐depletion blocked the intracellular entry of all three penetratin peptides. A decrease in membrane fluidity or cholesterol depletion with methyl‐β‐cyclodextrin greatly inhibited peptide uptake, showing the involvement of cholesterol‐rich lipid rafts in internalization. Exogenous heparan sulfate also diminished the internalization of penetratin and its derivatives, reflecting the paramount importance of electrostatic interactions with polyanionic cell‐surface proteoglycans. The beneficial presence of tryptophans is supported by observations on the decreased cellular uptake of Phe^{6, 14}‐penetratin. The maintained translocational efficiency of dodeca‐penetratin demonstrates that a thorough understanding of penetratin internalization can yield new penetratin analogs with unaltered translocational abilities. This study provides evidence on the energy‐dependent and lipid raft‐mediated endocytic uptake of penetratin and highlights the necessity of revealing those pathways that cationic cell‐penetrating peptides employ to enter live cells. Copyright © 2005 European Peptide Society and John Wiley & Sons, Ltd.     

Protein cargo delivery properties of cell-penetrating peptides. A comparative study

Application of cell-penetrating peptides for delivering various hydrophilic macromolecules with biological function into cells has gained much attention in recent years. We compared the protein transduction efficiency of four cell-penetrating peptides: penetratin, Tat peptide, transportan, and pVEC and studied the effects of various medium parameters on the uptake. Depletion of cellular energy and lowering of temperature strongly impaired the internalization of protein complexed with cell-penetrating peptides, confirming the endocytotic mechanism of peptide-mediated protein cellular transduction. Peptide-induced protein association with HeLa cells decreased 3-6-fold in energy-depleted cells. Inhibition of clathrin-dependent endocytosis by the hyperosmolar medium decreased the uptake of peptide-avidin complexes 1.5-3-fold and the removal of cholesterol from the plasma membrane 1.2-2-fold, suggesting that both clathrin-dependent and independent endocytosis were involved in peptide-induced cellular delivery of avidin. However, even under conditions of cellular energy depletion, ceasing of cellular traffic, and partial depolarization of plasma membrane, peptide-protein complexes associated with HeLa cells, as observed by FACS analysis and spectrofluorimetry. Among the studied peptides, pTat and transportan revealed higher protein transduction efficiency than penetratin or pVEC.     

Membrane interaction and perturbation mechanisms induced by two cationic cell penetrating peptides with distinct charge distribution

Independently from the cell penetrating peptide uptake mechanism (endocytic or not), the interaction of the peptide with the lipid bilayer remains a common issue that needs further investigation. The cell penetrating or antimicrobial properties of exogenous peptides require probably different preliminary interactions with the plasma membrane. Herein, we have employed (31)P NMR, differential scanning calorimetry and CD to study the membrane interaction and perturbation mechanisms of two basic peptides with similar length but distinct charge distribution, penetratin (non-amphipathic) and RL16, a secondary amphipathic peptide. The peptide effects on the thermotropic phase behavior of large multilamellar vesicles of dimyristoylphosphatidylcholine (DMPC), dimyristoylphosphatidylglycerol (DMPG) and dipalmitoleoyl phosphatidylethanolamine (DiPoPE) were investigated. We have found that, even though both peptides are cationic, their interaction with zwitterionic versus anionic lipids is markedly distinct. Penetratin greatly affects the temperature, enthalpy and cooperativity of DMPG main phase transition but does not affect those of DMPC while RL16 presents opposite effects. Additionally, it was found that penetratin induces a negative curvature whereas RL16 induces a positive one, since a decrease in the fluid lamellar to inverted hexagonal phase transition temperature of DiPoPE (T(H)) was observed for penetratin and an increase for RL16. Contrary to penetratin, (31)P NMR of samples containing DMPC MLVs and RL16 shows an isotropic signal indicative of the formation of small vesicles, concomitant with a great decrease in sample turbidity both below and at the phase transition temperature. Opposite effects were also observed on DMPG where both peptides provoke strong aggregation and precipitation. Both CPPs adopt helical structures when contacting with anionic lipids, and possess a dual behavior by either presenting their cationic or hydrophobic domains towards the phospholipid face, depending on the lipid nature (anionic vs zwitterionic, respectively). Surprisingly, the increase of electrostatic interactions at the water membrane interface prevents the insertion of RL16 hydrophobic region in the bilayer, but is essential for the interaction of penetratin. Modulation of amphipathic profiles and charge distribution of CPPs can alter the balance of hydrophobic and electrostatic membrane interaction leading to translocation or and membrane permeabilisation. Penetratin has a relative pure CPP behavior whereas RL16 presents mixed CPP/AMP properties. A better understanding of those processes is essential to unveil their cell translocation mechanism.     

A comparison of the different helices adopted by ��- and ��-peptides suggests different reasons for their stability

The right‐handed α‐helix is the dominant helical fold of α‐peptides, whereas the left‐handed 3₁₄‐helix is the dominant helical fold of β‐peptides. Using molecular dynamics simulations, the properties of α‐helical α‐peptides and 3₁₄‐helical β‐peptides with different C‐terminal protonation states and in the solvents water and methanol are compared. The observed energetic and entropic differences can be traced to differences in the polarity of the solvent‐accessible surface area and, in particular, the solute dipole moments, suggesting different reasons for their stability.     

Cell-Penetrating Peptides Selectively Cross the Blood-Brain Barrier In Vivo

Cell-penetrating peptides (CPPs) are a group of peptides, which have the ability to cross cell membrane bilayers. CPPs themselves can exert biological activity and can be formed endogenously. Fragmentary studies demonstrate their ability to enhance transport of different cargoes across the blood-brain barrier (BBB). However, comparative, quantitative data on the BBB permeability of different CPPs are currently lacking. Therefore, the in vivo BBB transport characteristics of five chemically diverse CPPs, i.e. pVEC, SynB3, Tat 47–57, transportan 10 (TP10) and TP10-2, were determined. The results of the multiple time regression (MTR) analysis revealed that CPPs show divergent BBB influx properties: Tat 47–57, SynB3, and especially pVEC showed very high unidirectional influx rates of 4.73 μl/(g × min), 5.63 μl/(g × min) and 6.02 μl/(g × min), respectively, while the transportan analogs showed a negligible to low brain influx. Using capillary depletion, it was found that 80% of the influxed peptides effectively reached the brain parenchyma. Except for pVEC, all peptides showed a significant efflux out of the brain. Co-injection of pVEC with radioiodinated bovine serum albumin (BSA) did not enhance the brain influx of radiodionated BSA, indicating that pVEC does not itself significantly alter the BBB properties. A saturable mechanism could not be demonstrated by co-injecting an excess dose of non-radiolabeled CPP. No significant regional differences in brain influx were observed, with the exception for pVEC, for which the regional variations were only marginal. The observed BBB influx transport properties cannot be correlated with their cell-penetrating ability, and therefore, good CPP properties do not imply efficient brain influx.     

Membrane interactions of cell-penetrating peptides probed by tryptophan fluorescence and dichroism techniques: correlations of structure to cellular uptake

This work reports on the binding and conformation of a series of CPPs in the bilayer membranes of large unilamellar vesicles and the effect of the presence of cholesterol. We show a negative correlation between alpha-helical structure and uptake efficiency for penetratin peptides where the two central arginine residues of penetratin are thought to be important for breaking the secondary structure. Penetratin alpha-helicity is also reduced upon incorporation of cholesterol into the membrane. Flow linear dichroism in the far-UV region shows that the penetratin peptides adopt a preferential orientation of the alpha-helix parallel to the bilayer, and the linear dichroism (LD) spectrum in the aromatic region indicates that the tryptophan residues are preferentially oriented parallel to the membrane. The Tat analogue TatP59W and the oligoarginine R7W, which are more efficient CPPs than penetratin, bind to membranes as random coils and do not show any orientation in LD, again indicating that alpha-helicity reduces uptake efficiency. Further, we observe large variations in tryptophan quantum yields for the five CPPs in this study and discuss this in terms of the ability to cause lipid rearrangement. Binding isotherms show that cholesterol increases the affinity of the peptide for the membrane, but tryptophan fluorescence lifetimes are essentially unaltered by incorporation of as much as 40 mol % cholesterol into the membrane, suggesting the absence of specific peptide-cholesterol interactions. Fluorescence emission maxima are insensitive to cholesterol and indicate that the peptide is positioned in the headgroup region. The results on peptide-membrane interactions are discussed in terms of possible uptake mechanisms.     

Internalisation of cell-penetrating peptides into tobacco protoplasts

Cells are protected from the surrounding environment by plasma membrane which is impenetrable for most hydrophilic molecules. In the last 10 years cell-penetrating peptides (CPPs) have been discovered and developed. CPPs enter mammalian cells and carry cargo molecules over the plasma membrane with a molecular weight several times their own. Known transformation methods for plant cells have relatively low efficiency and require improvement. The possibility to use CPPs as potential delivery vectors for internalisation in plant cells has been studied in the present work. We analyse and compare the uptake of the fluorescein-labeled CPPs, transportan, TP10, penetratin and pVEC in Bowes human melanoma cells and Nicotiana tabacum cultivar (cv.) SR-1 protoplasts (plant cells without cell wall). We study the internalisation efficiency of CPPs with fluorescence microscopy, spectrofluorometry and fluorescence-activated cell sorter (FACS). All methods indicate, for the first time, that these CPPs can internalise into N. tabacum cv. SR-1 protoplasts. Transportan has the highest uptake efficacy among the studied peptides, both in mammalian cells and plant protoplast. The internalisation of CPPs by plant protoplasts may open up a new effective method for transfection in plants.     

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.     

The cell penetrating peptides pVEC and W2-pVEC induce transformation of gel phase domains in phospholipid bilayers without affecting their integrity

The cell penetrating peptide (CPP) pVEC has been shown to translocate efficiently the plasma membrane of different mammalian cell lines by a receptor-independent mechanism without exhibiting cellular toxicity. This ability renders CPPs of broad interest in cell biology, biotechnology, and drug delivery. To gain insight into the interaction of CPPs with biomembranes, we studied the interaction of pVEC and W2-pVEC, an Ile --> Trp modification of the former, with phase-separated supported phospholipid bilayers (SPB) by atomic force microscopy (AFM). W2-pVEC induced a transformation of dipalmitoyl phosphatidylcholine (DPPC) domains from a gel phase state via an intermediate state with branched structures into essentially flat bilayers. With pVEC the transformation followed a similar pathway but was slower. Employing fluorescence polarization, we revealed the capability of the investigated peptides to increase the fluidity of DPPC domains as the underlying mechanism of transformation. Due to their tighter packing, sphingomyelin (SM) domains were not transformed. By combination, AFM observations, dynamic light scattering studies, and liposome leakage experiments indicated that bilayer integrity was not compromised by the peptides. Transformation of gel phase domains in SPB by CPPs represents a novel aspect in the discussion on uptake mechanisms of CPPs.     

Cell-penetrating peptides: a comparative membrane toxicity study

Cell-penetrating peptides (CPPs) constitute a new class of delivery vectors with high pharmaceutical potential. However, the abilities of these peptides to translocate through cell membranes can be accompanied by toxic effects resulting from membrane perturbation at higher peptide concentrations. Therefore, we investigated membrane toxicity of five peptides with well-documented cell-penetrating properties, pAntp(43-58), pTAT(48-60), pVEC(615-632), model amphipathic peptide (MAP), and transportan 10, on two human cancer cell lines, K562 (erythroleukemia) and MDA-MB-231 (breast cancer), as well as on immortalized aortic endothelial cells. We studied the effects of these five peptides on the leakage of lactate dehydrogenase and on the fluorescence of plasma membrane potentiometric dye bis-oxonol. In all cell lines, pAntp(43-58), pTAT(48-60), and pVEC(615-632) induced either no leakage or low leakage of lactate dehydrogenase, accompanied by modest changes in bis-oxonol fluorescence. MAP and transportan 10 caused significant leakage; in K562 and MDA-MB-231 cells, 40% of total lactate dehydrogenase leaked out during 10 min exposure to 10 microM of transportan 10 and MAP, accompanied by a significant increase in bis-oxonol fluorescence. However, none of the CPPs tested had a hemolytic effect on bovine erythrocytes comparable to mastoparan 7. The toxicity profiles presented in the current study are of importance when selecting CPPs for different applications.