Anti-HIV-1 Activity of pepRF1, a Proteolysis-Resistant CXCR4 Antagonist Derived from Dengue Virus Capsid Protein.

There is an urgent need for the development of new anti-HIV drugs that can complement existing medicines to be used against resistant strains. Here, we report the anti-HIV-1 peptide pepRF1, a human serum-resistant peptide derived from the Dengue virus capsid protein. In vitro, pepRF1 shows a 50% inhibitory concentration of 1.5 nM with a potential therapeutic window higher than 53 000. This peptide is specific for CXCR4-tropic strains, preventing viral entry into target cells by binding to the viral coreceptor CXCR4, acting as an antagonist of this receptor. pepRF1 is more effective than T20, the only peptide-based HIV-1 entry inhibitor approved, and excels in inhibiting a HIV-1 strain resistant to T20. Potentially, pepRF1 can be used alone or in combination with other anti-HIV drugs. Furthermore, one can also envisage its use as a novel therapeutic strategy for other CXCR4-related diseases.

Tumor Cell Attack by Crotalicidin (Ctn) and Its Fragment Ctn[15-34]: Insights into Their Dual Membranolytic and Intracellular Targeting Mechanism.

Crotalicidin (Ctn) and its fragment Ctn[15-34] are snake-venom-derived, cathelicidin-related peptides outstanding for their promising antimicrobial, antifungal, and antitumoral properties. In this study, we describe their membranolytic mechanisms as well as their putative interference with intracellular targets, both contributing to their antitumoral action against a pro-monocytic leukemia cell line. Initial flow cytometry assays demonstrated peptide ability to induce tumor cell membrane permeabilization and caspase-dependent apoptosis, without total activity reduction by serum proteases up to 24 h (Ctn) and 18 h (Ctn[15-34]). In addition, both Ctn and Ctn[15-34] showed preference for tumor cells rather than healthy cells, with selectivity ratios (tumoral vs healthy cells) of 17 and 7, respectively. Further microscopy and flow cytometry studies suggested their preferential accumulation in the cytoplasmic membrane and nucleus and proposed multiple predominant routes of peptide uptake, including direct entry and endocytosis. Affinity purification followed by proteomic identification experiments revealed both peptides to interact with proteins involved in DNA and protein metabolism, cell cycles, signal transduction, and/or programmed cell death, among others. These results suggest a putative role of Ctn and Ctn[15-34] to interact with key intracellular pathways, ultimately contributing to tumor cell death by necrosis/apoptosis. Altogether, this work proposes a dual mechanism underlying the antitumoral activity of Ctn and Ctn[15-34] and reinforces their potential as future therapeutic drugs.

New Potent Membrane-Targeting Antibacterial Peptides from Viral Capsid Proteins.

The increasing prevalence of multidrug-resistant bacteria urges the development of new antibacterial agents. With a broad spectrum activity, antimicrobial peptides have been considered potential antibacterial drug leads. Using bioinformatic tools we have previously shown that viral structural proteins are a rich source for new bioactive peptide sequences, namely antimicrobial and cell-penetrating peptides. Here, we test the efficacy and mechanism of action of the most promising peptides among those previously identified against both Gram-positive and Gram-negative bacteria. Two cell-penetrating peptides, vCPP 0769 and vCPP 2319, have high antibacterial activity against Staphylococcus aureus, MRSA, Escherichia coli, and Pseudomonas aeruginosa, being thus multifunctional. The antibacterial mechanism of action of the two most active viral protein-derived peptides, vAMP 059 and vCPP 2319, was studied in detail. Both peptides act on both Gram-positive S. aureus and Gram-negative P. aeruginosa, with bacterial cell death occurring within minutes. Also, these peptides cause bacterial membrane permeabilization and damage of the bacterial envelope of P. aeruginosa cells. Overall, the results show that structural viral proteins are an abundant source for membrane-active peptides sequences with strong antibacterial properties.

Mechanisms of Vesicular Stomatitis Virus Inactivation by Protoporphyrin IX, Zinc-Protoporphyrin IX, and Mesoporphyrin IX.

Virus resistance to antiviral therapies is an increasing concern that makes the development of broad-spectrum antiviral drugs urgent. Targeting of the viral envelope, a component shared by a large number of viruses, emerges as a promising strategy to overcome this problem. Natural and synthetic porphyrins are good candidates for antiviral development due to their relative hydrophobicity and pro-oxidant character. In the present work, we characterized the antiviral activities of protoprophyrin IX (PPIX), Zn-protoporphyrin IX (ZnPPIX), and mesoporphyrin IX (MPIX) against vesicular stomatitis virus (VSV) and evaluated the mechanisms involved in this activity. Treatment of VSV with PPIX, ZnPPIX, and MPIX promoted dose-dependent virus inactivation, which was potentiated by porphyrin photoactivation. All three porphyrins inserted into lipid vesicles and disturbed the viral membrane organization. In addition, the porphyrins also affected viral proteins, inducing VSV glycoprotein cross-linking, which was enhanced by porphyrin photoactivation. Virus incubation with sodium azide and α-tocopherol partially protected VSV from inactivation by porphyrins, suggesting that singlet oxygen (1O2) was the main reactive oxygen species produced by photoactivation of these molecules. Furthermore, 1O2 was detected by 9,10-dimethylanthracene oxidation in photoactivated porphyrin samples, reinforcing this hypothesis. These results reveal the potential therapeutic application of PPIX, ZnPPIX, and MPIX as good models for broad antiviral drug design.

Quantitative analysis of molecular partition towards lipid membranes using surface plasmon resonance.

Understanding the interplay between molecules and lipid membranes is fundamental when studying cellular and biotechnological phenomena. Partition between aqueous media and lipid membranes is key to the mechanism of action of many biomolecules and drugs. Quantifying membrane partition, through adequate and robust parameters, is thus essential. Surface Plasmon Resonance (SPR) is a powerful technique for studying 1:1 stoichiometric interactions but has limited application to lipid membrane partition data. We have developed and applied a novel mathematical model for SPR data treatment that enables determination of kinetic and equilibrium partition constants. The method uses two complementary fitting models for association and dissociation sensorgram data. The SPR partition data obtained for the antibody fragment F63, the HIV fusion inhibitor enfuvirtide, and the endogenous drug kyotorphin towards POPC membranes were compared against data from independent techniques. The comprehensive kinetic and partition models were applied to the membrane interaction data of HRC4, a measles virus entry inhibitor peptide, revealing its increased affinity for, and retention in, cholesterol-rich membranes. Overall, our work extends the application of SPR beyond the realm of 1:1 stoichiometric ligand-receptor binding into a new and immense field of applications: the interaction of solutes such as biomolecules and drugs with lipids.

Bioorthogonal Strategy for Bioprocessing of Specific-Site-Functionalized Enveloped Influenza-Virus-Like Particles.

Virus-like particles (VLPs) constitute a promising platform in vaccine development and targeted drug delivery. To date, most applications use simple nonenveloped VLPs as human papillomavirus or hepatitis B vaccines, even though the envelope is known to be critical to retain the native protein folding and biological function. Here, we present tagged enveloped VLPs (TagE-VLPs) as a valuable strategy for the downstream processing and monitoring of the in vivo production of specific-site-functionalized enveloped influenza VLPs. This two-step procedure allows bioorthogonal functionalization of azide-tagged nascent influenza type A hemagglutinin proteins in the envelope of VLPs through a strain-promoted [3 + 2] alkyne-azide cycloaddition reaction. Importantly, labeling does not influence VLP production and allows for construction of functionalized VLPs without deleterious effects on their biological function. Refined discrimination and separation between VLP and baculovirus, the major impurity of the process, is achieved when this technique is combined with flow cytometry analysis, as demonstrated by atomic force microscopy. TagE-VLPs is a versatile tool broadly applicable to the production, monitoring, and purification of functionalized enveloped VLPs for vaccine design trial runs, targeted drug delivery, and molecular imaging.

Rethinking the capsid proteins of enveloped viruses: multifunctionality from genome packaging to genome transfection.

Regardless of the debate on whether there is a place for viruses in the tree of life, it is consensual that they co-evolve with their hosts under the pressure of genome minimization. The abundance of multifunctional viral structural proteins is a consequence of this pressure. The molecular key to multifunctionality is the existence of intrinsically disordered domains together with ordered domains in the same protein. Capsid proteins, the hallmark of viruses, are not exceptions because they have coexisting ordered and disordered domains that are crucial for multifunctionality. It is also frequent to find supercharged proteins (i.e. proteins for which the net charge per unit molecular mass is > +0.75/kDa) among viral capsid proteins. All flaviviruses having annotated proteins in the ExPASy Viralzone database have supercharged capsid proteins. Moreover, cell-penetrating sequences/domains are frequent in viral proteins, even when they are not supercharged. Altogether, the findings strongly suggest that the ability to translocate membranes was acquired, conserved and optimized throughout the evolution of some viral proteins as part of their multifunctionality. The fitness of capsid proteins to translocate membranes carrying genomes was experimentally demonstrated with dengue virus capsid protein. This protein is potentially able to help the fusion process and translocate the RNA genome across the hemifused membrane formed by the viral envelope and the endosomal membrane. In addition, one of the cell-penetrating domains of the capsid protein also has antibacterial activity. This may be reminiscent of parasitic bacteria-bacteria competition for the same host and shed light on the origins of enveloped viruses.

Shifting gear in antimicrobial and anticancer peptides biophysical studies: from vesicles to cells.

Despite the intensive study on the mechanism of action of membrane-active molecules such as antimicrobial and anticancer peptides, most of the biophysical work has been performed using artificial model systems, mainly lipid vesicles. The use of these systems allows full control of the experimental parameters, and to obtain molecular-level detail on the action of peptides, the correlation with biological action is intangible. Recently, several biophysical methodologies have been translated to studies using bacterial and cancer cells. Here, we review biophysical studies on the mechanism of action of antimicrobial and anticancer peptides performed directly on cells. The data in these studies allow to correlate vesicle-based and cell-based studies and fill the vesicle-cell interdisciplinary gap.

Apoptotic human neutrophil peptide-1 anti-tumor activity revealed by cellular biomechanics.

Cancer remains a major cause of morbidity and mortality worldwide. Although progress has been made regarding chemotherapeutic agents, new therapies that combine increased selectivity and efficacy with low resistance are still needed. In the search for new anticancer agents, therapies based on biologically active peptides, in particular, antimicrobial peptides (AMPs), have attracted attention for their decreased resistance development and low cytotoxicity. Many AMPs have proved to be tumoricidal agents against human cancer cells, but their mode of action is still controversial. The existence of common properties shared by the membranes of bacteria and tumor cells points to similar lipid-targeting mechanisms in both cases. On the other hand, anticancer peptides (ACPs) also induce apoptosis and inhibit angiogenesis. Human neutrophil peptide-1 (HNP-1) is an endogenous AMP that has been implicated in different cellular phenomena such as tumor proliferation. The presence of HNP-1 in the serum/plasma of oncologic patients turns this peptide into a potential tumor biomarker. The present work reveals the different effects of HNP-1 on the biophysical and nanomechanical properties of solid and hematological tumor cells. Studies on cellular morphology, cellular stiffness, and membrane ultrastructure and charge using atomic force microscopy (AFM) and zeta potential measurements show a preferential binding of HNP-1 to solid tumor cells from human prostate adenocarcinoma when compared to human leukemia cells. AFM also reveals induction of apoptosis with cellular membrane defects at very low peptide concentrations. Understanding ACPs mode(s) of action will certainly open innovative pathways for drug development in cancer treatment.

Correlation between membrane translocation and analgesic efficacy in kyotorphin derivatives.

Amidated kyotorphin (L-Tyr-L-Arg-NH2; KTP-NH2) causes analgesia when systemically administered. The lipophilic ibuprofen-conjugated derivative of KTP-NH2 has improved analgesic efficacy. However, fast degradation by peptidases impacts negatively in the pharmacodynamics of these drugs. In this work, selected derivatives of KTP and KTP-NH2 were synthesized to combine lipophilicity and resistance to enzymatic degradation. Eight novel structural modifications were tested for the potential to transverse lipid membranes and to evaluate their efficacy in vivo. The rationale behind the design of the pool of the eight selected molecules consisted in the addition of individual group at the N-terminus, namely the tert-butyloxycarbonyl (Boc), γ-aminobutyric acid (GABA), acetyl, butanoyl, and propanoyl or in the substitution of the tyrosine residue by an indole moiety and in the replacement of the peptidic bond by a urea-like bond in some cases. All the drugs used in the study are intrinsically fluorescent, which enables the use of spectrofluorimetry to sample the drugs in the permeation assays. The results show that the BOC and indolyl derivatives of KTP-NH2 have maximal ability to permeate membranes with concomitant maximal analgesic power. Overall, the results demonstrate that membrane permeation is correlated with analgesic efficacy. However, this is not the only factor accounting for analgesia. KTP-NH2 for instance has low passive permeation but is known to have central action. In this case, hypothetical transcytosis over the blood-brain barrier seems to depend on dipeptide transporters.

The mechanisms and quantification of the selective permeability in transport across biological barriers: the example of kyotorphin.

This paper addresses the mechanisms behind selective endothelial permeability and their regulations. The singular properties of each of the seven blood-tissues barriers. Then, it further revisits the physical, quantitative meaning of permeability, and the way it should be measured based on sound physical chemistry reasoning and methodologies. Despite the relevance of permeability studies one often comes across inaccurate determinations, mostly from oversimplified data analyses. To worsen matters, the exact meaning of permeability is being lost along with this loss of accuracy. The importance of proper permeability calculation is illustrated with a family of derivatives of kyotorphin, an analgesic dipeptide.

Nucleic acid delivery by cell penetrating peptides derived from dengue virus capsid protein: design and mechanism of action.

Cell penetrating peptides (CPPs) can be used as drug delivery systems for different therapeutic molecules. In this work two novel CPPs, pepR and pepM, designed from two domains of the dengue virus (DENV) capsid protein, were studied for their ability to deliver nucleic acids into cells as non-covalently bound cargo. Translocation studies were performed by confocal microscopy in HepG2, BHK and HEK cell lineages, astrocytes and peripheral blood mononuclear cells. Combined studies in HepG2 cells, astrocytes and BHK cells, at 4 and 37 °C or using specific endocytosis inhibitors, revealed that pepR and pepM use distinct internalization routes: pepM translocates lipid membranes directly, while pepR uses an endocytic pathway. To confirm these results, a methodology was developed to monitor the translocation kinetics of both peptides by real-time flow cytometry. Kinetic constants were determined, and the amount of nucleic acids delivered was estimated. Additional studies were performed in order to understand the molecular bases of the peptide-mediated translocation. Peptide-nucleic acid and peptide-lipid membrane interactions were studied quantitatively based on the intrinsic fluorescence of the peptides. pepR and pepM bound ssDNA to the same extent. Partition studies revealed that both peptides bind preferentially to anionic lipid membranes, adopting an α-helical conformation. However, fluorescence quenching studies suggest that pepM is deeply inserted into the lipid bilayer, in contrast with pepR. Moreover, only pepM is able to promote the fusion and aggregation of vesicles composed of zwitterionic lipids. Altogether, the results show that DENV capsid protein derived peptides serve as good templates for novel CPP-based nucleic acid delivery strategies, defining different routes for cell entry.

Translocating the blood-brain barrier using electrostatics.

Mammalian cell membranes regulate homeostasis, protein activity, and cell signaling. The charge at the membrane surface has been correlated with these key events. Although mammalian cells are known to be slightly anionic, quantitative information on the membrane charge and the importance of electrostatic interactions in pharmacokinetics and pharmacodynamics remain elusive. Recently, we reported for the first time that brain endothelial cells (EC) are more negatively charged than human umbilical cord cells, using zeta-potential measurements by dynamic light scattering. Here, we hypothesize that anionicity is a key feature of the blood-brain barrier (BBB) and contributes to select which compounds cross into the brain. For the sake of comparison, we also studied the membrane surface charge of blood components-red blood cells (RBC), platelets, and peripheral blood mononuclear cells (PBMC). To further quantitatively correlate the negative zeta-potential values with membrane charge density, model membranes with different percentages of anionic lipids were also evaluated. From all the cells tested, brain cell membranes are the most anionic and those having their lipids mostly exposed, which explains why lipophilic cationic compounds are more prone to cross the blood-brain barrier.

Using zeta-potential measurements to quantify peptide partition to lipid membranes.

Many cellular phenomena occur on the biomembranes. There are plenty of molecules (natural or xenobiotics) that interact directly or partially with the cell membrane. Biomolecules, such as several peptides (e.g., antimicrobial peptides) and proteins, exert their effects at the cell membrane level. This feature makes necessary investigating their interactions with lipids to clarify their mechanisms of action and side effects necessary. The determination of molecular lipid/water partition constants (K ( p )) is frequently used to quantify the extension of the interaction. The determination of this parameter has been achieved by using different methodologies, such as UV-Vis absorption spectrophotometry, fluorescence spectroscopy and ζ-potential measurements. In this work, we derived and tested a mathematical model to determine the K ( p ) from ζ-potential data. The values obtained with this method were compared with those obtained by fluorescence spectroscopy, which is a regular technique used to quantify the interaction of intrinsically fluorescent peptides with selected biomembrane model systems. Two antimicrobial peptides (BP100 and pepR) were evaluated by this new method. The results obtained by this new methodology show that ζ-potential is a powerful technique to quantify peptide/lipid interactions of a wide variety of charged molecules, overcoming some of the limitations inherent to other techniques, such as the need for fluorescent labeling.