Potential-dependent membrane permeabilization and mitochondrial aggregation caused by anticancer polyarginine-KLA peptides

The anticancer activity of the polycationic peptide (KLAKLAK)₂, as a possible mitochondria-damaging agent, named KLA (l-form) or kla (d-form), has been increased by the fusion with hepta-arginine cell delivery vectors r7 and R7 (peptides r7-kla and R7-KLA, respectively), as shown in the literature. We demonstrated that 3.6 μM r7-kla or R7-KLA, but not kla, caused significant permeabilization of the inner and the outer membranes of energized rat liver mitochondria. In addition, r7-kla or R7-KLA induced mitochondrial aggregation, thus causing the inhibition of metabolic activity. Potential-dependent mechanism of permeabilization of the inner mitochondrial membrane by these peptides was also observed for the plasma membrane of red blood cells. The obtained results suggest that polyarginine cell delivery vectors of anticancer polycationic peptides not only increase their direct potential-dependent permeabilization of biological membranes, but also create the capacity to cause aggregation of mitochondria, as a new mechanism of cytotoxic action of these peptides.     

S4(13)-PV cell-penetrating peptide induces physical and morphological changes in membrane-mimetic lipid systems and cell membranes: implications for cell internalization

The present work aims to gain insights into the role of peptide-lipid interactions in the mechanisms of cellular internalization and endosomal escape of the S4(13)-PV cell-penetrating peptide, which has been successfully used in our laboratory as a nucleic acid delivery system. A S4(13)-PV analogue, S4(13)-PVscr, displaying a scrambled amino acid sequence, deficient cell internalization and drug delivery inability, was used in this study for comparative purposes. Differential scanning calorimetry, fluorescence polarization and X-ray diffraction at small and wide angles techniques showed that both peptides interacted with anionic membranes composed of phosphatidylglycerol or a mixture of this lipid with phosphatidylethanolamine, increasing the lipid order, shifting the phase transition to higher temperatures and raising the correlation length between the bilayers. However, S4(13)-PVscr, in contrast to the wild-type peptide, did not promote lipid domain segregation and induced the formation of an inverted hexagonal lipid phase instead of a cubic phase in the lipid systems assayed. Electron microscopy showed that, as opposed to S4(13)-PVscr, the wild-type peptide induced the formation of a non-lamellar organization in membranes of HeLa cells. We concluded that lateral phase separation and destabilization of membrane lamellar structure without compromising membrane integrity are on the basis of the lipid-driven and receptor-independent mechanism of cell entry of S4(13)-PV peptide. Overall, our results can contribute to a better understanding of the role of peptide-lipid interactions in the mechanisms of cell-penetrating peptide membrane translocation, helping in the future design of more efficient cell-penetrating peptide-based drug delivery systems.     

Interaction studies of novel cell selective antimicrobial peptides with model membranes and E. coli ATCC 11775

Cationic antimicrobial peptides (CAMPs) are novel candidates for drug development. Here we describe design of six short and potent CAMPs (SA-1 to SA-6) based on a minimalist template of 12 residues H+HHG+HH+HH+NH2 (where H: hydrophobic amino acid and +: charged hydrophilic amino acid). Designed peptides exhibit good antibacterial activity in micro molar concentration range (1-32 μg/ml) and rapid clearance of Gram-positive and Gram-negative bacterial strains at concentrations higher than MIC. For elucidating mode of action of designed peptides various biophysical studies including CD and Trp fluorescence were performed using model membranes. Further based on activity, selectivity and membrane bound structure; modes of action of Trp rich peptide SA-3 and template based peptide SA-4 were compared. Calcein dye leakage and transmission electron microscopic studies with model membranes exhibited selective membrane active mode of action for peptide SA-3 and SA-4. Extending our work from model membranes to intact E. coli ATCC 11775 in scanning electron micrographs we could visualize different patterns of surface perturbation caused by peptide SA-3 and SA-4. Further at low concentration rapid translocation of FITC-tagged peptide SA-3 into the cytoplasm of E. coli cells without concomitant membrane perturbation indicates involvement of intracellular targeting mechanism as an alternate mode of action as was also evidenced in DNA retardation assay. For peptide SA-4 concentration dependent translocation into the bacterial cytoplasm along with membrane perturbation was observed. Establishment of a non specific membrane lytic mode of action of these peptides makes them suitable candidates for drug development.     

Potential efficacy of cell-penetrating peptides for nucleic acid and drug delivery in cancer

Cell penetrating peptides (CPPs) are short amphipathic and cationic peptides that are rapidly internalized across cell membranes. They can be used to deliver molecular cargo, such as imaging agents (fluorescent dyes and quantum dots), drugs, liposomes, peptide/protein, oligonucleotide/DNA/RNA, nanoparticles and bacteriophage into cells. The utilized CPP, attached cargo, concentration and cell type, all significantly affect the mechanism of internalization. The mechanism of cellular uptake and subsequent processing still remains controversial. It is now clear that CPP can mediate intracellular delivery via both endocytic and non-endocytic pathways. In addition, the orientation of the peptide and cargo and the type of linkage are likely important. In gene therapy, the designed cationic peptides must be able to 1) tightly condense DNA into small, compact particles; 2) target the condensate to specific cell surface receptors; 3) induce endosomal escape; and 4) target the DNA cargo to the nucleus for gene expression. The other studies have demonstrated that these small peptides can be conjugated to tumor homing peptides in order to achieve tumor-targeted delivery in vivo. On the other hand, one of the major aims in molecular cancer research is the development of new therapeutic strategies and compounds that target directly the genetic and biochemical agents of malignant transformation. For example, cell penetrating peptide aptamers might disrupt protein-protein interactions crucial for cancer cell growth or survival. In this review, we discuss potential functions of CPPs especially for drug and gene delivery in cancer and indicate their powerful promise for clinical efficacy.     

Measuring peptide translocation into large unilamellar vesicles

There is an active interest in peptides that readily cross cell membranes without the assistance of cell membrane receptors(1). Many of these are referred to as cell-penetrating peptides, which are frequently noted for their potential as drug delivery vectors(1-3). Moreover, there is increasing interest in antimicrobial peptides that operate via non-membrane lytic mechanisms(4,5), particularly those that cross bacterial membranes without causing cell lysis and kill cells by interfering with intracellular processes(6,7). In fact, authors have increasingly pointed out the relationship between cell-penetrating and antimicrobial peptides(1,8). A firm understanding of the process of membrane translocation and the relationship between peptide structure and its ability to translocate requires effective, reproducible assays for translocation. Several groups have proposed methods to measure translocation into large unilamellar lipid vesicles (LUVs)(9-13). LUVs serve as useful models for bacterial and eukaryotic cell membranes and are frequently used in peptide fluorescent studies(14,15). Here, we describe our application of the method first developed by Matsuzaki and co-workers to consider antimicrobial peptides, such as magainin and buforin II(16,17). In addition to providing our protocol for this method, we also present a straightforward approach to data analysis that quantifies translocation ability using this assay. The advantages of this translocation assay compared to others are that it has the potential to provide information about the rate of membrane translocation and does not require the addition of a fluorescent label, which can alter peptide properties(18), to tryptophan-containing peptides. Briefly, translocation ability into lipid vesicles is measured as a function of the Foster Resonance Energy Transfer (FRET) between native tryptophan residues and dansyl phosphatidylethanolamine when proteins are associated with the external LUV membrane (Figure 1). Cell-penetrating peptides are cleaved as they encounter uninhibited trypsin encapsulated with the LUVs, leading to disassociation from the LUV membrane and a drop in FRET signal. The drop in FRET signal observed for a translocating peptide is significantly greater than that observed for the same peptide when the LUVs contain both trypsin and trypsin inhibitor, or when a peptide that does not spontaneously cross lipid membranes is exposed to trypsin-containing LUVs. This change in fluorescence provides a direct quantification of peptide translocation over time.     

Cellular uptake of antisense morpholino oligomers conjugated to arginine-rich peptides

Although the sequence specificity, biostability, and low toxicity of PMO (phosphorodiamidate morpholino oligomers) make them good antisense agents to study gene function, their limited ability to cross cell membranes limits their use in cell culture. In this paper we show that conjugation to arginine-rich peptides significantly enhanced the cellular uptake of PMO. The factors that affect the conjugate's cellular uptake and its antisense activity toward a targeted mRNA were investigated. Factors studied include the number of arginines in the peptide, the choice of cross-linker, the peptide conjugation position, the length of the PMO, and the cell culture conditions. Delivery of PMO to the cell nucleus and cytosol required conjugation rather than complexation of peptides to PMO. R(9)F(2)C was best suited to deliver a PMO to its target RNA resulting in the strongest antisense effect. By simply adding the R(9)F(2)C-PMO conjugate into the cell culture medium at low microM concentration, missplicing of pre-mRNA was corrected. This particular peptide-conjugated PMO was more effective than the PMO conjugated to the transmembrane transport peptides of HIV-1 Tat protein, Drosophila antennapedia protein, or to peptides with fewer arginines. Length of PMO did not affect a peptide's delivery efficacy, but all other factors were important. R(9)F(2)C peptide provided a simple and efficient delivery of PMO to a RNA target. Conjugation of peptide to PMO enhances the opportunities to evaluate gene functions in cell cultures.     

Vesicles mimicking normal and cancer cell membranes exhibit differential responses to the cell-penetrating peptide Pep-1

The cell-penetrating peptide (CPP) Pep-1 presents a great potential in drug delivery due to its intrinsic property to cross plasma membrane. However, its mechanism of entry into the cell remains unresolved. In this study, we compare the selectivity of Pep-1 towards vesicles mimicking normal and cancer cell membranes. The interaction was performed in a wide range of peptide-to-lipid molar ratios using infrared (IR), fluorescence, scanning electron microscopy (SEM), thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) techniques. At low peptide concentration, fluorescence experiments show that lipid-phosphatidylserine (PS) seems to enable Pep-1 translocation into cancer cell membrane as evidenced by the blue shift of its maximal emission wavelength. DSC data show that Pep-1 induces segregation of lipids. At high peptide concentration, IR data indicate that the interaction of Pep-1 is relatively stronger with normal cell membrane than with cancer cell membrane through the phosphate groups, while the interaction is weaker with normal cell membrane than with cancer cell membrane through the carbonyl groups. TGA and DSC data reveal that vesicles of normal cell membrane are thermally more stable than vesicles of cancer cell membrane. This suggests that the additional lipid PS included in cancer cell membrane has a destabilizing effect on the membrane structure. SEM images reveal that Pep-1 form superstructures including spherical particles and fibrils in the presence of both model membranes. PS seems to enhance peptide transport across cellular membranes. The biophysical techniques in this study provide valuable insights into the properties of CPPs in drug delivery systems.     

Simultaneous membrane interaction of amphipathic peptide monomers,self-aggregates and cargo complexes detected by fluorescence correlation spectroscopy

Peptides able to translocate cell membranes while carrying macromolecular cargo, as cell-penetrating peptides (CPPs), can contribute to the field of drug delivery by enabling the transport of otherwise membrane impermeable molecules. Formation of non-covalent complexes between amphipathic peptides and oligonucleotides is driven by electrostatic and hydrophobic interactions. Here we investigate and quantify the coexistence of distinct molecular species in multiple equilibria, namely peptide monomer, peptide self-aggregates and peptide/oligonucleotide complexes. As a model for the complexes, we used a stearylated peptide from the PepFect family, PF14 and siRNA. PF14 has a cationic part and a lipid part, resembling some characteristics of cationic lipids. Fluorescence correlation spectroscopy (FCS) and fluorescence cross-correlation spectroscopy (FCCS) were used to detect distinct molecular entities in solution and at the plasma membrane of live cells. For that, we labeled the peptide with carboxyrhodamine 6G and the siRNA with Cyanine 5. We were able to detect fluorescent entities with diffusional properties characteristic of the peptide monomer as well as of peptide aggregates and peptide/oligonucleotide complexes. Strategies to avoid peptide adsorption to solid surfaces and self-aggregation were developed and allowed successful FCS measurements in solution and at the plasma membrane. The ratio between the detected molecular species was found to vary with pH, peptide concentration and the proximity to the plasma membrane. The present results suggest that the diverse cellular uptake mechanisms, often reported for amphipathic CPPs, might result from the synergistic effect of peptide monomers, self-aggregates and cargo complexes, distributed unevenly at the plasma membrane.     

Membrane interactions of peptides representing the polybasic regions of three Rho GTPases are sensitive to the distribution of arginine and lysine residues

Rho GTPases are a multifunctional family of proteins that are localized at cellular membranes via an isoprenyl group covalently linked to a C-terminal cysteine. Close to this primary site of membrane anchoring there is often found an additional polybasic region (PBR), which plays a secondary role in membrane binding and targeting of the complex. Here, peptides derived from the PBRs of the Rho family proteins Rac1 (K(183)KRKRK), TCL (K(198)KKKKR) and Cdc42 (P(182)KKSRR) were prepared with hexalysine (K(6)) and hexaarginine (R(6)) to study their interactions with multilamellar vesicles of phosphatidylglycerol (DOPG) and headgroup-deuterated dimyristoylphosphatidylcholine (DMPC-d(4)) using (2)H and (31)P NMR. The membranes retained their lamellar architecture after peptide binding, but the (2)H NMR line shapes for DMPC-d(4) indicated that the bound peptides altered the orientation of the choline headgroups, consistent with a change in membrane surface charge. Rac1 and TCL peptides appeared to affect the headgroup orientation similarly to K(6), although the perturbations were weaker and unlike those induced by the Cdc42 peptide and R(6). Magic-angle spinning (31)P NMR spectra of the membranes showed significant and selective broadening of the peak for DMPC after addition of the peptides, with R(6) and the Cdc42 peptide having the greatest effect. The selective broadening may be a consequence of the lipids separating into short-lived domains enriched in peptide-bound DOPG and peptide-free DMPC. These results illustrate that a complex relationship exists between the sequence of PBRs and their behaviour at membrane surfaces, which may have implications for the cellular functions and localization of Rho GTPases.     

Different membrane behaviour and cellular uptake of three basic arginine-rich peptides

Cell penetrating peptides (CPPs) are peptides displaying the ability to cross cell membranes and transport cargo molecules inside cells. Several uptake mechanisms (endocytic or direct translocation through the membrane) are being considered, but the interaction between the CPP and the cell membrane is certainly a preliminary key point to the entry of the peptide into the cell. In this study, we used three basic peptides: RL9 (RRLLRRLRR-NH(2)), RW9 (RRWWRRWRR-NH(2)) and R9 (RRRRRRRRR-NH(2)). While RW9 and R9 were internalised into wild type Chinese Hamster Ovary cells (CHO) and glycosaminoglycan-deficient CHO cells, at 4°C and 37°C, RL9 was not internalised into CHO cells. To better understand the differences between RW9, R9 and RL9 in terms of uptake, we studied the interaction of these peptides with model lipid membranes. The effect of the three peptides on the thermotropic phase behaviour of a zwitterionic lipid (DMPC) and an anionic lipid (DMPG) was investigated with differential scanning calorimetry (DSC). The presence of negative charges on the lipid headgroups appeared to be essential to trigger the peptide/lipid interaction. RW9 and R9 disturbed the main phase transition of DMPG, whereas RL9 did not induce significant effects. Isothermal titration calorimetry (ITC) allowed us to study the binding of these peptides to large unilamellar vesicles (LUVs). RW9 and R9 proved to have about ten fold more affinity for DSPG LUVs than RL9. With circular dichroism (CD) and NMR spectroscopy, the secondary structure of RL9, RW9 and R9 in aqueous buffer or lipid/detergent conditions was investigated. Additionally, we tested the antimicrobial activity of these peptides against Escherichia coli and Staphylococcus aureus, as CPPs and antimicrobial peptides are known to share several common characteristics. Only RW9 was found to be mildly bacteriostatic against E. coli. These studies helped us to get a better understanding as to why R9 and RW9 are able to cross the cell membrane while RL9 remains bound to the surface without entering the cell.     

抗菌肽BLFcin6与不同磷脂膜之间相互作用的分子动力学模拟研究

抗菌肽具有广谱抗菌特性,有望成为抗生素较好的替代产品.研究抗菌肽的抗菌机制,可以为新型抗菌肽的设计提供指导.无论抗菌肽采用哪种抗菌机制,其首先要稳定地吸附到细胞膜之上.因此,本文利用分子动力学模拟方法比较了抗菌小肽BLFcin6与5种不同细胞膜之间的相互作用.对这5种细胞膜而言,小肽会很快结合在POPG膜和DPPC-CHOL膜的表面,倾向于进入DPPC膜的疏水内部,与POPC膜和POPC-CHOL膜的接触很少.考察相互作用能,小肽与POPG膜的相互作用最强,主要是小肽与细胞膜亲水头部存在静电相互作用;小肽与DPPC膜的疏水尾部的相互作用较强,但受胆固醇影响,小肽只结合在DPPC-CHOL膜表面.在结合过程中,小肽N端的Arg会先结合到细胞膜上,静电相互作用在小肽锚定细胞膜的过程中起关键作用.以上研究从原子水平上解释了为什么BLFcin6小肽具有抗菌作用,哪些残基起关键作用,也为进一步开展BLFcin6小肽及其衍生小肽的研究奠定基础.     

Basic peptide system for efficient delivery of foreign genes

Certain peptides containing high percentage of cationic amino acids are known to efficiently translocate through the cell membrane. This principle was previously exploited for delivery of variety proteins. We had observed that various basic peptides of earlier studies, though not specifically use for gene delivery, contain DNA or RNA binding domains. In the present study, we reported on arginine peptides, which form DNA complexes that efficiently transfect various cell lines. The transfection abilities of the peptides were observed by green fluorescent protein (GFP) and beta-galactosidase gene expression in 293T, HeLa, Jurkat, and COS-7 cells. We found superior transfection activity of arginine peptides compared with commercially available efficient transfection agents. The expression of marker genes induced by arginine peptides was partially inhibited in the presence of heparan sulfate, chondroitin sulfate B and C, or both heparinase III and chondroitinase ABC. The transfection proficiency of these peptides was affected by endosomotropic reagent as well as low temperature (4 degrees C). Finally, we have investigated the potential of arginine peptides as a delivery agent for gene therapy, by attempting to deliver herpes simplex virus thymidine kinase (HSV-TK) gene into tumor cells. HSV-TK transfected tumor cells exhibited sensitivity to the antiviral drug ganciclovir (GCV), leading to cell death. Taken together, these data demonstrate that arginine peptide is proficient for transfection, indicating its potentially benefit to studies in gene therapy and gene delivery in a range of model organisms.     

Free energy analysis of membrane pore formation process in the presence of multiple melittin peptides

Understanding the molecular mechanism underlying pore formation in lipid membranes by antimicrobial peptides is of great importance in biological sciences as well as in drug design applications. Melittin has been widely studied as a pore forming peptide, though the molecular mechanism for pore formation is still illusive. We examined the free energy barrier for the creation of a pore in lipid membranes with and without multiple melittin peptides. It was found that six melittin peptides significantly stabilized a pore, though a small barrier (a few k_BT) for the formation still existed. With five melittin peptides or fewer, the pore formation barrier was much higher, though the established pore was in a local energy minimum. Although seven melittins effectively reduced the free energy barrier, a single melittin peptide left the pore after a long time MD simulation probably because of the overcrowded environment around the bilayer pore. Thus, it is highly selective for the number of melittin peptides to stabilize the membrane pore, as was also suggested by the line tension evaluations. The free energy cost required to insert a single melittin into the membrane is too high to explain the one-by-one insertion mechanism for pore formation, which also supports the collective melittin mechanism for pore formation.     

Functional characterization of an endosome-disruptive peptide and its application in cytosolic delivery of immunoliposome-entrapped proteins

Antibody-directed liposomes (immunoliposomes) are frequently used for targeted drug delivery. However, delivery of large biotherapeutic molecules (i.e. peptides, proteins, or nucleic acids) with immunoliposomes is often hampered by an inefficient cytosolic release of entrapped macromolecules after target cell binding and subsequent endocytosis of immunoliposomes. To enhance cytosolic drug delivery from immunoliposomes present inside endosomes, a pH-dependent fusogenic peptide (diINF-7) resembling the NH(2)-terminal domain of influenza virus hemagglutinin HA-2 subunit was used. Functional characterization of this dimeric peptide showed its ability to induce fusion between liposome membranes and leakage of liposome-entrapped compounds when exposed to low pH. In a second series of experiments, diINF-7 peptides were encapsulated in immunoliposomes to enhance the endosomal escape of diphtheria toxin A chain (DTA), which inhibits protein synthesis when delivered into the cytosol of target cells. Immunoliposomes targeted to the internalizing epidermal growth factor receptor on the surface of ovarian carcinoma cells (OVCAR-3) and containing encapsulated DTA did not show any cytotoxicity toward OVCAR-3 cells. Cytotoxicity was only observed when diINF-7 peptides and DTA were co-encapsulated in the immunoliposomes. Thus, diINF-7 peptides entrapped inside liposomes can greatly enhance cytosolic delivery of liposomal macromolecules by pH-dependent destabilization of endosomal membranes after cellular uptake of liposomes.     

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.     

Hydrophobic and electrostatic interactions between cell penetrating peptides and plasmid DNA are important for stable non‐covalent complexation and intracellular delivery

Cell penetrating peptides are useful tools for intracellular delivery of nucleic acids. Delivery of plasmid DNA, a large nucleic acid, poses a challenge for peptide mediated transport. The paper investigates and compares efficacy of five novel peptide designs for complexation of plasmid DNA and subsequent delivery into cells. The peptides were designed to contain reported DNA condensing agents and basic cell penetrating sequences, octa‐arginine (R₈) and CHK₆HC coupled to cell penetration accelerating peptides such as Bax inhibitory mutant peptide (KLPVM) and a peptide derived from the Kaposi fibroblast growth factor (kFGF) membrane translocating sequence. A tryptophan rich peptide, an analogue of Pep‐3, flanked with CH₃ on either ends was also a part of the study. The peptides were analysed for plasmid DNA complexation, protection of peptide–plasmid DNA complexes against DNase I, serum components and competitive ligands by simple agarose gel electrophoresis techniques. Hemolysis of rat red blood corpuscles (RBCs) in the presence of the peptides was used as a measure of peptide cytotoxicity. Plasmid DNA delivery through the designed peptides was evaluated in two cell lines, human cervical cancer cell line (HeLa) and (NIH/3 T3) mouse embryonic fibroblasts via expression of the secreted alkaline phosphatase (SEAP) reporter gene. The importance of hydrophobic sequences in addition to cationic sequences in peptides for non‐covalent plasmid DNA complexation and delivery has been illustrated. An alternative to the employment of fatty acid moieties for enhanced gene transfer has been proposed. Comparison of peptides for plasmid DNA complexation and delivery of peptide–plasmid DNA complexes to cells estimated by expression of a reporter gene, SEAP. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

Mechanism of interaction of different classes of cationic antimicrobial peptides with planar bilayers and with the cytoplasmic membrane of Escherichia coli.

Antimicrobial cationic peptides are prevalent throughout nature as part of the intrinsic defenses of most organisms, and have been proposed as a blueprint for the design of novel antimicrobial agents. They are known to interact with membranes, and it has been frequently proposed that this represents their antibacterial target. To see if this was a general mechanism of action, we studied the interaction, with model membranes and the cytoplasmic membrane of Escherichia coli, of 12 peptides representing all 4 structural classes of antimicrobial peptides. Planar lipid bilayer studies indicated that there was considerable variance in the interactions of the peptides with model phospholipid membranes, but generally both high concentrations of peptide and high transmembrane voltages (usually -180 mV) were required to observe conductance events (channels). The channels observed for most peptides varied widely in magnitude and duration. An assay was developed to measure the interaction with the Escherichia coli cytoplasmic membrane employing the membrane potential sensitive dye 3,5-dipropylthiacarbocyanine in the outer membrane barrier-defective E. coli strain DC2. It was demonstrated that individual peptides varied widely in their ability to depolarize the cytoplasmic membrane potential of E. coli, with certain peptides such as the loop peptide bactenecin and the alpha-helical peptide CP26 being unable to cause depolarization at the minimal inhibitory concentration (MIC), and others like gramicidin S causing maximal depolarization below the MIC. We discuss the mechanism of interaction with the cytoplasmic membrane in terms of the model of Matsuzaki et al. [(1998) Biochemistry 37, 15144-15153] and the possibility that the cytoplasmic membrane is not the target for some or even most cationic antimicrobial peptides.     

Cationic peptide-induced remodelling of model membranes: direct visualization by in situ atomic force microscopy

Our understanding of how antimicrobial and cell-penetrating peptides exert their action at cell membranes would benefit greatly from direct visualization of their modes of action and possible targets within the cell membrane. We previously described how the cationic antimicrobial peptide, indolicidin, interacted with mixed zwitterionic planar lipid bilayers as a function of both peptide concentration and lipid composition [Shaw, J.E. et al., 2006. J. Struct. Biol. 154 (1), 42-58]. In the present report, in situ atomic force microscopy was used to characterize the interactions between three families of cationic peptides: (1) tryptophan-rich antimicrobial peptides--indolicidin and two of its analogues, (2) an amphiphilic alpha-helical membranolytic peptide--melittin, and (3) an arginine-rich cell-penetrating peptide--Tat with phase-separated planar bilayers containing 1,2-dioleoyl-sn-glycerol-3-phosphocholine (DOPC)/1,2-distearoyl-sn-glycerol-3-phosphocholine (DSPC) or DOPC/N-stearoyl-D-erythro-sphingosylphosphorylcholine (SM)/cholesterol. We found that these cationic peptides all induced remodelling of the model membranes in a concentration, and family-dependent manner. At low peptide concentration, these cationic peptides, despite their different biological roles, all appeared to reduce the interfacial line tension at the domain boundary between the liquid-ordered and liquid-disordered domains. Only at high peptide concentration was the membrane remodelling induced by these peptides morphologically distinct among the three families. While the transformation caused by indolicidin and its analogues were structurally similar, the concentration required to initiate the transformation was strongly dependent on the hydrophobicity of the peptide. Our use of lipid compositions with no net charge minimized the electrostatic interactions between the cationic peptides and the model supported bilayers. These results suggest that peptides within the same functional family have a common mechanism of action, and that membrane insertion of short cationic peptides at low peptide concentration may also alter membrane structure through a common mechanism regardless of the peptide's origin.     

pH-triggered pore-forming peptides with strong composition-dependent membrane selectivity

Peptides that self-assemble into nanometer-sized pores in lipid bilayers could have utility in a variety of biotechnological and clinical applications if we can understand their physical chemical properties and learn to control their membrane selectivity. To empower such control, we have used synthetic molecular evolution to identify the pH-dependent delivery peptides, a family of peptides that assemble into macromolecule-sized pores in membranes at low peptide concentration but only at pH < ～6. Further advancements will also require better selectivity for specific membranes. Here, we determine the effect of anionic headgroups and bilayer thickness on the mechanism of action of the pH-dependent delivery peptides by measuring binding, secondary structure, and macromolecular poration. The peptide pHD15 partitions and folds equally well into zwitterionic and anionic membranes but is less potent at pore formation in phosphatidylserine-containing membranes. The peptide also binds and folds similarly in membranes of various thicknesses, but its ability to release macromolecules changes dramatically. It causes potent macromolecular poration in vesicles made from phosphatidylcholine with 14 carbon acyl chains, but macromolecular poration decreases sharply with increasing bilayer thickness and does not occur at any peptide concentration in fluid bilayers made from phosphatidylcholine lipids with 20-carbon acyl chains. The effects of headgroup and bilayer thickness on macromolecular poration cannot be accounted for by the amount of peptide bound but instead reflect an inherent selectivity of the peptide for inserting into the membrane-spanning pore state. Molecular dynamics simulations suggest that the effect of thickness is due to hydrophobic match/mismatch between the membrane-spanning peptide and the bilayer hydrocarbon. This remarkable degree of selectivity based on headgroup and especially bilayer thickness is unusual and suggests ways that pore-forming peptides with exquisite selectivity for specific membranes can be designed or evolved.     

Design of a pH-sensitive pore-forming peptide with improved performance.

GALA is a 30 residue synthetic peptide designed to interact with membranes in a pH-sensitive manner, with potential applications for intracellular drug and gene delivery. Upon reduction of the pH from neutral to acidic, GALA switches from random coil to alpha-helix, inserts into lipid bilayers, and forms oligomeric pores of defined size. Its simple sequence and well-characterized behavior make the peptide an excellent starting point to explore the effects of sequence on structure, pH sensitivity, and membrane affinity. We describe synthesis and characterization of two derivatives of GALA, termed GALAdel3E and YALA. GALAdel3E has a deletion of three centrally located glutamate residues from GALA, while YALA replaces one glutamate residue with the unusual amino acid 3,5-diiodotyrosine. Both derived peptides retain pH sensitivity, showing no ability to cause leakage of an encapsulated dye from unilamellar vesicles at pH 7.4 but substantial activity at pH 5. Unlike GALA, neither peptide undergoes a conformational change upon reduction of the pH, remaining alpha-helical throughout. Interestingly, the pH at which the peptides activate is shifted, with GALA becoming active at pH approximately 5.7, GALAdel3E at pH approximately 6.2, and YALA at pH approximately 6.7. Furthermore, the peptides GALAdel3E and YALA show improved activity compared with GALA for cholesterol-containing membranes, with YALA retaining the greatest activity. Improved activity in the presence of cholesterol and onset of activity in the critical range between pH 6 and 7 may make these peptides useful in applications requiring intracellular delivery of macromolecules, such as gene delivery or anti-cancer treatments.