Extracellular-Vesicle Catch-and-Release Isolation System Using a Net-Charge Invertible Curvature-Sensing Peptide.

Extracellular vesicles (EVs) carry various informative components, including signaling proteins, transcriptional regulators, lipids, and nucleic acids. These components are utilized for cell-cell communication between donor and recipient cells. EVs have shown great promise as pharmaceutical-targeting vesicles and have attracted the attention of researchers in the fields of biological and medical science because of their importance as diagnostic and prognostic markers. However, the isolation and purification of EVs from cell-cultured media remain challenging. Ultracentrifugation is the most widely used method, but it requires specialized and expensive equipment. In the present study, we proposed a novel methodology to isolate EVs using a simple and convenient method, i.e., an EV catch-and-release isolation system (EV-CaRiS) using a net-charge invertible curvature-sensing peptide (NIC). Curvature-sensing peptides recognize vesicles by binding to lipid-packing defects on highly curved membranes regardless of the expression levels of biomarkers. NIC was newly designed to reversibly capture and release EVs in a pH-dependent manner. NIC allowed us to achieve reproducible EV isolation from three human cell lines on resin using a batch method and single-particle imaging of EVs containing the ubiquitous exosome markers CD63 and CD81 by total internal reflection fluorescence microscopy (TIRFM). EV-CaRiS was demonstrated as a simple and convenient methodology for EV isolation, and NIC is promising for applications in the single-particle analysis of EVs.

Structural Dissection of Epsin-1 N-Terminal Helical Peptide: The Role of Hydrophobic Residues in Modulating Membrane Curvature.

Spatiotemporal structural alterations in cellular membranes are the hallmark of many vital processes. In these cellular events, the induction of local changes in membrane curvature often plays a pivotal role. Many amphiphilic peptides are able to modulate membrane curvature, but there is little information on specific structural factors that direct the curvature change. Epsin-1 is a representative protein thought to initiate invagination of the plasma membrane upon clathrin-coated vesicles formation. Its N-terminal helical segment (EpN18) plays a key role in inducing positive membrane curvature. This study aimed to elucidate the essential structural features of EpN18 in order to better understand general curvature-inducing mechanisms, and to design effective tools for rationally controlling membrane curvature. Structural dissection of peptides derived from EpN18 revealed the decisive contribution of hydrophobic residues to (i) enhancing membrane interactions, (ii) helix structuring, (iii) inducing positive membrane curvature, and (iv) loosening lipid packing. The strongest effect was obtained by substitution with leucine residues, as this EpN18 analog showed a marked ability to promote the influx of octa-arginine cell-penetrating peptides into living cells.

Synthesis and Properties of V-Shaped Xanthene Dyes with Tunable and Predictable Absorption and Emission Wavelengths.

V-shaped xanthene dyes capable of predicting absorption and emission wavelengths are described. These dyes were synthesized by bridging a xanthene ring and an aryl moiety of fluorescein through ether covalent bonds. These dyes showed longer absorption and emission wavelengths than those of the parent fluorescein. Furthermore, substituents introduced on the aryl moiety mainly affected the lowest unoccupied molecular orbital energy level of the molecule. Therefore, the Hammett substituent constants could be used to predict the absorption and emission wavelengths of the compound.

Split luciferase-based estimation of cytosolic cargo concentration delivered intracellularly via attenuated cationic amphiphilic lytic peptides.

Intracellular delivery of biomacromolecules is challenging as these molecules are taken up by cells and encapsulated into vesicular compartments called endosomes, and the fraction of molecules that are translocated to the cytosol are particularly important to obtain desired biological responses. This study aimed to estimate the cytosolic concentrations of intracellularly delivered peptides and proteins to aid the design of novel and effective biopharmaceutical delivery systems. To this end, we employed the split NanoLuc luciferase system, using the 11-residue HiBiT peptide segment as a probe for the delivered molecules in cells expressing the complementary LgBiT protein segment. The efficacy in cytosolic HiBiT delivery was determined by measuring the resultant luciferase activity when the HiBiT segment delivered into the cytosol forms a complex with LgBiT. Mean cytosolic HiBiT concentration was calculated using cell number and cell volume analysis. L17E and HAad peptides, developed in our laboratory for intracellular protein delivery, yielded approximately 6-fold cellular HiBiT concentrations than that obtained in their absence.

Influence of the Dabcyl group on the cellular uptake of cationic peptides: short oligoarginines as efficient cell-penetrating peptides.

Cell-penetrating peptides (CPPs) are promising delivery vehicles. These short peptides can transport wide range of cargos into cells, although their usage has often limitations. One of them is the endosomatic internalisation and thus the vesicular entrapment. Modifications which increases the direct delivery into the cytosol is highly researched area. Among the oligoarginines the longer ones (n > 6) show efficient internalisation and they are well-known members of CPPs. Herein, we describe the modification of tetra- and hexaarginine with (4-((4-(dimethylamino)phenyl)azo)benzoyl) (Dabcyl) group. This chromophore, which is often used in FRET system increased the internalisation of both peptides, and its effect was more outstanding in case of hexaarginine. The modified hexaarginine may enter into cells more effectively than octaarginine, and showed diffuse distribution besides vesicular transport already at low concentration. The attachment of Dabcyl group not only increases the cellular uptake of the cell-penetrating peptides but it may affect the mechanism of their internalisation. Their conjugates with antitumor drugs were studied on different cells and showed antitumor activity.

Membrane anchoring of a curvature-inducing peptide, EpN18, promotes membrane translocation of octaarginine.

EpN18 is a curvature-inducing peptide, which loosens lipid packing upon interaction with the cell membrane, and facilitates cell-membrane penetration by arginine-rich cell-penetrating peptides, including octaarginine (R8). In the present study, we conjugated the N-terminal of EpN18 with a pyrenebutyryl (pBu) moiety, which acts as an anchoring unit that increases membrane interactions. Enhanced lipid-packing loosening and cytosolic translocation of R8 were observed by the pBu anchoring of EpN18.

Design of the N-Terminus Substituted Curvature-Sensing Peptides That Exhibit Highly Sensitive Detection Ability of Bacterial Extracellular Vesicles.

Extracellular vesicles (EVs) have emerged as important targets in biological and medical studies because they are involved in diverse human diseases and bacterial pathogenesis. Although antibodies targeting the surface biomarkers are widely used to detect EVs, peptide-based curvature sensors are currently attracting an attention as a novel tool for marker-free EV detection techniques. We have previously created a curvature-sensing peptide, FAAV and applied it to develop a simple and rapid method for detection of bacterial EVs in cultured media. The method utilized the fluorescence/Förster resonance energy transfer (FRET) phenomenon to achieve the high sensitivity to changes in the EV amount. In the present study, to develop a practical and easy-to-use approach that can detect bacterial EVs by peptides alone, we designed novel curvature-sensing peptides, N-terminus-substituted FAAV (nFAAV) peptides. The nFAAV peptides exerted higher α-helix-stabilizing effects than FAAV upon binding to vesicles while maintaining a random coil structure in aqueous solution. One of the nFAAV peptides showed a superior binding affinity for bacterial EVs and detected changes in the EV amount with 5-fold higher sensitivity than FAAV even in the presence of the EV-secretory bacterial cells. We named nFAAV5, which exhibited the high ability to detect bacterial EVs, as an EV-sensing peptide. Our finding is that the coil-α-helix structural transition of the nFAAV peptides serve as a key structural factor for highly sensitive detection of bacterial EVs.

Metal Complex Lipids for Fluid-Fluid Phase Separation in Coassembled Phospholipid Membranes.

We demonstrate a fluid-fluid phase separation in 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) membranes using a metal complex lipid of type [Mn(L1)] (1; HL1=1-(2-hydroxybenzamide)-2-(2-hydroxy-3-formyl-5-hexadecyloxybenzylideneamino)ethane). Small amount of 1 produces two separated domains in DMPC, whose phase transition temperatures of lipids (Tc ) are both lower than that of the pristine DMPC. Variable temperature fluorescent microscopy for giant-unilamellar vesicles of DMPC/1 hybrids demonstrates that visible phase separations remain in fluid phases up to 37 °C, which is clearly over the Tc of DMPC. This provides a new dimension for the application of metal complex lipids toward controlling lipid distributions in fluid membranes.

Rational Design Principles of Attenuated Cationic Lytic Peptides for Intracellular Delivery of Biomacromolecules.

Intracellular delivery of bioactive macromolecules via endocytic pathways has utility in biotechnological and medicinal applications. Various endosomolytic peptides bearing glutamic acid (Glu) residues have been developed with the aim to achieve selective lysis of endosomal membranes without damaging cell membranes (plasma membranes) to release endosome-entrapped macromolecules and obtain their bioactivity. Glu residues on peptides are negatively charged in the extracellular medium, and substitution of this residue onto membrane-lytic peptides prevents its peptide-membrane interaction and its lytic activity. On the other hand, within endosomes, which have a reduced pH of ∼5, Glu is protonated, resulting in the reduction of the hydrophilicity of the peptide, unmasking its lytic activity. Despite this, a limited number of studies have elucidated the optimum positions for Glu substitution. This report investigated the positioning of Glu and the endosomolytic activities of cationic lytic peptides, ponericin-W3, and melittin. By cell-based assays, biophysical analyses, and molecular dynamics simulations, we found that analogues with Glu positioned on the borders between the hydrophobic and hydrophilic faces of the helical structures showed better performance than placing Glu within said faces.

Enhancing the activity of membrane remodeling epsin-peptide by trimerization.

Modulating the structural dynamics of biomembranes by inducing bilayer curvature and lipid packing defects has been highlighted as a practical tool to modify membrane-dependent cellular processes. Previously, we have reported on an amphipathic helical peptide derived from the N-terminal segment (residues 1-18, EpN18) of epsin-1, which can promote membrane remodeling including lipid packing defects in cell membranes. However, a high concentration is required to exhibit a pronounced effect. In this study, we demonstrate a significant increase in the membrane-remodeling effect of EpN18 by constructing a branched EpN18 homotrimer. Both monomer and trimer could enhance cell internalization of octaarginine (R8), a cell-penetrating peptide. The EpN18 trimer, however, promoted the uptake of R8 at an 80-fold lower concentration than the monomer. Analysis of the generalized polarization of a polarity-sensitive dye (di-4-ANEPPDHQ) revealed a higher efficacy of trimeric EpN18 in loosening the lipid packing in the cell membrane. Circular dichroism measurements in the presence of lipid vesicles showed that the EpN18 trimer has a higher α-helix content compared with the monomer. The stronger ability of the EpN18 trimer to impede negative bilayer curvature is also corroborated by solid-state 31P NMR spectroscopy. Hence, trimerizing peptides can be considered a promising approach for an exponential enhancement of their membrane-remodeling performance.

Optimizing Charge Switching in Membrane Lytic Peptides for Endosomal Release of Biomacromolecules.

Endocytic pathways are practical routes for the intracellular delivery of biomacromolecules. Along with this, effective strategies for endosomal cargo release into the cytosol are desired to achieve successful delivery. Focusing on compositional differences between the cell and endosomal membranes and the pH decrease within endosomes, we designed the lipid-sensitive and pH-responsive endosome-lytic peptide HAad. This peptide contains aminoadipic acid (Aad) residues, which serve as a safety catch for preferential permeabilization of endosomal membranes over cell membranes, and His-to-Ala substitutions enhance the endosomolytic activity. The ability of HAad to destabilize endosomal membranes was supported by model studies using large unilamellar vesicles (LUVs) and by increased intracellular delivery of biomacromolecules (including antibodies) into live cells. Cerebral ventricle injection of Cre recombinase with HAad led to Cre/loxP recombination in a mouse model, thus demonstrating potential applicability of HAad in vivo.

Pseudo-Membrane Jackets: Two-Dimensional Coordination Polymers Achieving Visible Phase Separation in Cell Membrane.

Cell membranes contain lateral systems that consist of various lipid compositions and actin cytoskeleton, providing two-dimensional (2D) platforms for chemical reactions. However, such complex 2D environments have not yet been used as a synthetic platform for artificial 2D nanomaterials. Herein, we demonstrate the direct synthesis of 2D coordination polymers (CPs) at the liquid-cell interface of the plasma membrane of living cells. The coordination-driven self-assembly of networking metal complex lipids produces cyanide-bridged CP layers with metal ions, enabling "pseudo-membrane jackets" that produce long-lived micro-domains with a size of 1-5 µm. The resultant artificial and visible phase separation systems remain stable even in the absence of actin skeletons in cells. Moreover, we show the cell application of the jackets by demonstrating the enhancement of cellular calcium response to ATP.

Loosening of Lipid Packing by Cell-Surface Recruitment of Amphiphilic Peptides by Coiled-Coil Tethering.

Lipid packing has a strong influence on the formation and structural dynamics of cell membranes. Techniques to modulate lipid packing may thus enable modification of cellular functions and events. An 18-residue amphiphilic helical peptide derived from the N-terminal segment of epsin-1 (EpN18) is reported to induce positive membrane curvature and to loosen lipid packing in the cell membrane. In this study, it is shown that EpN18, crosslinked to a leucine-zipper peptide K4, is recruited to the cell surface by interacting with a cell-surface-expressed E3 leucine-zipper segment. Cell-surface tethering markedly enhanced loosening of lipid packing, which led to the promotion of membrane translocation of octaarginine. The loosening of lipid packing by EpN18 was also confirmed by analyzing the generalized polarization value with a membrane-environment-sensitive dye, 2-hydroxy-3-{2-[(2-hydroxyethyl)dimethylamino]ethyl}-4-{2-[6-(dibutylamino)-2-naphthyl]ethenyl}pyridiniumdibromide (di-4-ANEPPDHQ). This approach thus shows promise for the control of lipid packing and related cellular events.

Dipicolylamine/Metal Complexes that Promote Direct Cell-Membrane Penetration of Octaarginine.

Marked promotion of membrane permeation of a cell-penetrating peptide, octaarginine (R8), was attained by attachment to a single 2,2'-dipicolylamine moiety (DPA-R8) that forms 1:1 complexes with metal ions. Studies using giant unilamellar vesicles demonstrated that DPA targets phospholipids and enhances R8 binding to the membranes in the presence of metal ions. While DPA/Zn(II) complex has been most frequently employed for chelate formation with phosphates, Ni(II) had the most prominent effect on the membrane binding and penetration of DPA-R8. Facile cytosolic distribution of DPA-R8 was also attained in a few minutes in the presence of Ni(II). Analysis of the cellular uptake methods of DPA-R8/Ni(II) suggested the involvement of direct permeation through cell membrane without the use of endocytosis. The applicability of this system to the intracellular delivery of bioactive compounds was exemplified using a peptidomimetic farnesyltransferase inhibitor, FTI277.

Development of a Membrane Curvature-Sensing Peptide Based on a Structure-Activity Correlation Study.

Membrane curvature formation is important for various biological processes such as cell motility, intracellular signal transmission, and cellular uptake of foreign substances. However, it remains still a challenging topic to visualize the membrane curvature formation on the cell membranes in real-time imaging. To develop and design membrane curvature-sensors, we focused on amphipathic helical peptides of proteins belonging to the Bin/Amphiphysin/Rvs (BAR) family as the starting point. BAR proteins individually have various characteristic structures that recognize different curvatures, and the derived peptides possess the potential to function as curvature sensors with a variety of recognition abilities. Peptide-based curvature sensors can have wide applications in biological research fields due to their small size, easy modification, and large production capability in comparison to protein-based sensors. In the present study, we found that an amphipathic peptide derived from sorting nexin1 (SNX1) has a curvature-recognition ability. The mutation studies of the initial peptide revealed a close correlation between the α-helicity and lipid binding ability of the peptides. In particular, the amino acids located on the hydrophobic face played a vital role in curvature recognition. The α-helix formation of the peptides was thought to serve to accommodate lipid-packing defects on the membrane surface and to maintain their binding to lipid vesicles. The structure-activity correlation found in this study have the potential to contribute to the design of peptide-based curvature sensors that will enable the capture of various life phenomena in cells.

Importance of Net Hydrophobicity in the Cellular Uptake of All-Hydrocarbon Stapled Peptides.

All-hydrocarbon stapled peptides make up a promising class of protein-protein interaction regulators; their potential therapeutic benefit arises because they have a high binding affinity and specificity for intracellular molecules. The cell permeation efficacy of these peptides is a critical determinant of their bioactivity. However, the factors that determine their cellular uptake remain an active area of research. In this study, we evaluated the effect of stapled (or cross-linked) formation on the cellular uptake of six known all-hydrocarbon stapled peptides. We found that the rate of cellular uptake of unstapled peptides (i.e., those bearing olefinic non-natural amino acids that are not subjected to olefin metathesis) was higher than that for the corresponding stapled peptides. Additionally, the insertion of these olefinic non-natural amino acids into peptide sequences significantly increased their rate of cellular uptake. According to the high-performance liquid chromatography retention times, the overall hydrophobicity of unstapled peptides was greater than that of stapled peptides, followed by that of the original peptides without olefinic non-natural amino acids. There was not a close correlation between helical content and the rate of cellular uptake of these peptides. Therefore, the increase in overall hydrophobicity resulting from the introduction of non-natural amino acids, rather than the structural stabilization resulting from staple formation, is the key driver promoting cellular uptake. Macropinocytosis, a form of fluid-phase endocytosis, was involved in the cellular uptake of all six peptides.

A pH-dependent charge reversal peptide for cancer targeting.

Naturally occurring cationic antimicrobial peptides exhibit not only antimicrobial activity, but also anticancer activity and are expected to be new weapons in cancer treatment. The selectivity for cancer cells over normal cells is at least partly due to the more negative surface of cancer cells. A lower pH in tumor tissue (pH 6.2-6.9) than that in normal tissues (pH 7.3-7.4) has also been utilized to develop anticancer agents. However, cytotoxicity against normal cells at physiological pH is often an issue. Furthermore, acidic regions can be found in some normal tissues such as the kidneys. Therefore, existing approaches to cancer targeting are not fully satisfactory. In this study, we designed a peptide, HE (GIHHWLHSAHEFGEHFVHHIMNS-amide), with a charge that reverses from -1.5 at pH 7.4 to +6 at pH 5.5 for cancer targeting at low pH based on the antimicrobial peptide magainin 2 by introducing 6 His, an additional Glu, and an amidated terminal. HE interacted with cancer-mimicking negatively charged liposomes in a pH-dependent fashion with a midpoint with a pH of 6.5 just above the membrane surface. The peptide killed human renal adenocarcinoma ACHN cells at pH 6.0, but not at pH 7.4, and was nontoxic against human normal glomerular mesangial cells even at this low pH. Thus, the novel peptide may be a promising lead peptide for cancer therapy, although this derivatization resulted in weakened cytotoxicity.

Stoichiometric analysis of oligomeric states of three class-A GPCRs, chemokine-CXCR4, dopamine-D2, and prostaglandin-EP1 receptors, on living cells.

G-protein-coupled receptors (GPCRs) form the largest family of transmembrane receptors, and their oligomerization has been suggested to be related to their functions. Despite extensive studies, their oligomeric states are highly controversial. One of the reasons is the overestimation of oligomerization by conventional methods. We recently established a stoichiometric analysis method for precisely determining the oligomeric state of membrane proteins on living cells with the combined use of the coiled-coil labeling method and a spectral imaging technique and showed that the prototypical class-A GPCR ß2 -adrenergic receptor (ß2 AR) did not form functional oligomers. In this study, we expanded our study to three well-studied class-A GPCRs: C-X-C chemokine receptor of stromal cell-derived factor-1α (CXCR4), dopamine receptor D2 short isotype (D2R), and prostaglandin E receptor subtype 1 (EP1R). We found that these receptors did not form constitutive homooligomers. The receptors exhibited calcium signaling upon agonist stimulation as monomers, although CXCR4 and EP1R gradually clustered after fast signaling. We conclude that homooligomerization is not necessary for the signal transductions of these four class-A GPCRs. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.

EVALUATION OF SHORT-TERM OUTCOMES OF INTRAVITREAL AFLIBERCEPT INJECTIONS FOR AGE-RELATED MACULAR DEGENERATION USING FOCAL MACULAR ELECTRORETINOGRAPHY.

PURPOSE: To evaluate the relationship between morphological changes and functional improvements assessed using focal macular electroretinograms after intravitreal aflibercept (IVA) injections in eyes with wet age-related macular degeneration. METHODS: The clinical records of 42 eyes of 42 consecutive patients with naive, wet age-related macular degeneration received 3 monthly IVA were reviewed. The best-corrected visual acuity, central foveal thickness, outer retinal thickness, inner retinal thickness at baseline and 1 month after each IVA, and focal macular electroretinograms at baseline and 1 month after the first and third IVA were compared. RESULTS: Best-corrected visual acuity was improved after the third IVA (P = 0.0091). Central foveal thickness and outer retinal thickness showed decreases after every IVA (P < 0.001, respectively). Inner retinal thickness showed a decrease after the second IVA (P = 0.002), after and third IVA (P = 0.001). On focal macular electroretinograms, a- and b-wave amplitudes showed increases after the third IVA (P = 0.0028, P = 0.0012, respectively). Significant correlations were observed between best-corrected visual acuity and central foveal thickness, a-wave amplitude and outer retinal thickness, and b-wave amplitude and inner retinal thickness changes after the third IVA. CONCLUSION: All parameters significantly recovered after three monthly IVA, with a correlation between functional improvements and morphological changes.

One-Year Outcomes of 1 + pro re nata versus 3 + pro re nata Intravitreal Aflibercept Injection for Neovascular Age-Related Macular Degeneration.

PURPOSE: We compared 1-year outcomes of 1 + pro re nata (PRN) versus 3 + PRN of intravitreal aflibercept injection (IAI) for age-related macular degeneration (AMD). METHODS: Forty-two eyes with naïve AMD received 3 + PRN IAI treatment and 47 eyes with naïve AMD received 1 + PRN IAI treatment. Visual acuity (VA), central retinal thickness (CRT), and central choroidal thickness (CCT) and number of administered IAIs during 12 months were compared. RESULTS: VAs improved, and CRTs reduced significantly at any given month from baseline in both groups (p < 0.01, respectively). CCT reduced significantly at 3 months in the 3 + PRN group (p = 0.024) but not in the 1 + PRN group. The 1 + PRN group received fewer injections than the 3 + PRN group (p < 0.01). CONCLUSIONS: Aflibercept leads to equivalent VA and morphologic retinal improvement without administering 3 injections.