Acid‐activated nonviral peptide vector for gene delivery

Nonviral vector–based gene therapy is a promising strategy for treating a myriad of diseases. Cell‐penetrating peptides are gaining increasing attention as vectors for nucleic acid delivery. However, most studies have focused more on the transfection efficiency of these vectors than on their specificity and toxicity. To obtain ideal vectors with high efficiency and safety, we constructed the vector stearyl‐TH by attaching a stearyl moiety to the N‐terminus of the acid‐activated cell penetrating peptide TH in this study. Under acidic conditions, stearyl‐TH could bind to and condense plasmids into nanoparticle complexes, which displayed significantly enhanced cellular uptake and transfection efficiencies. In contrast, stearyl‐TH lost the capacities of DNA binding and transfection at physiological pH. More importantly, stearyl‐TH and the complexes formed by stearyl‐TH and plasmids displayed no obvious toxicity at physiological pH. Consequently, the high transfection efficiency under acidic conditions and low toxicity make stearyl‐TH a potential nucleic acid delivery vector for gene therapy.     

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.     

Use of locked nucleic acid oligonucleotides to add functionality to plasmid DNA

The available reagents for the attachment of functional moieties to plasmid DNA are limiting. Most reagents bind plasmid DNA in a non-sequence- specific manner, with undefined stoichiometry, and affect DNA charge and delivery properties or involve chemical modifications that abolish gene expression. The design and ability of oligonucleotides (ODNs) containing locked nucleic acids (LNAs) to bind supercoiled, double-stranded plasmid DNA in a sequence-specific manner are described for the first time. The main mechanism for LNA ODNs binding plasmid DNA is demonstrated to be by strand displacement. LNA ODNs are more stably bound to plasmid DNA than similar peptide nucleic acid (PNA) ‘clamps’ for procedures such as particle-mediated DNA delivery (gene gun). It is shown that LNA ODNs remain associated with plasmid DNA after cationic lipid-mediated transfection into mammalian cells. LNA ODNs can bind to DNA in a sequence-specific manner so that binding does not interfere with plasmid conformation or gene expression. Attachment of CpG-based immune adjuvants to plasmid by ‘hybrid’ phosphorothioate–LNA ODNs induces tumour necrosis factor-α production in the macrophage cell line RAW264.7. This observation exemplifies an important new, controllable methodology for adding functionality to plasmids for gene delivery and DNA vaccination.     

Medicinal chemistry of plasmid DNA with peptide nucleic acids: A new strategy for gene therapy

In this chapter, we describe an approach using a peptide nucleic acid (PNA) clamp to directly and irreversibly modify plasmid DNA, without affecting either its supercoiled conformation or its ability to be efficiently transcribed. This strategy enables investigators to `functionalize' their gene of interest by direct coupling of ligands (fluorophores, peptide, proteins, sugars or oligonucleotides) to plasmid DNA. This approach provides versatile tools to study the mechanisms of gene delivery and to circumvent some of the main obstacles of synthetic gene delivery systems, such as specific targeting and efficient delivery. The proof-of-principal of PNA-dependent gene chemistry (PDGC) was demonstrated with a fluorescently labeled PNA that allowed generation of a highly fluorescent preparation of plasmid DNA that was functionally and conformationally intact. Fluorescent-PNA/DNA was used to identify critical parameters involved in naked DNA and non-viral gene delivery technology. The greatest potential of PDGC lies in the ability to attach specific ligands (e.g., peptides, proteins) to the plasmid DNA in order to overcome cellular barriers of non-viral gene delivery systems. In this regard, specific examples of ligands coupled to DNA are described and their effect on increasing the efficacy of gene therapy is presented.     

Medicinal chemistry of plasmid DNA with peptide nucleic acids: A new strategy for gene therapy

Summary In this chapter, we describe an approach using a peptide nucleic acid (PNA) clamp to directly and irreversibly modify plasmid DNA, without affecting either its supercoiled conformation or its ability to be efficiently transcribed. This strategy enables investigators to 'functionalize' their gene of interest by direct coupling of ligands (fluorophores, peptide, proteins, sugars or oligonucleotides) to plasmid DNA. This approach provides versatile tools to study the mechanisms of gene delivery and to circumvent some of the main obstacles of synthetic gene delivery systems, such as specific targeting and efficient delivery. The proof-of-principal of PNA-dependent gene chemistry (PDGC) was demonstrated with a fluorescently labeled PNA that allowed generation of a highly fluorescent preparation of plasmid DNA that was functionally and conformationally intact. Fluorescent-PNA/DNA was used to identify critical parameters involved in naked DNA and non-viral gene delivery technology. The greatest potential of PDGC lies in the ability to attach specific ligands (e.g., peptides, proteins) to the plasmid DNA in order to overcome cellular barriers of non-viral gene delivery systems. In this regard, specific examples of ligands coupled to DNA are described and their effect on increasing the efficacy of gene therapy is presented.     

Peptide-functionalized poly(ethylene glycol) star polymers: DNA delivery vehicles with multivalent molecular architecture

Exploring the development of nonviral nucleic acid delivery vectors with progressive, specific, and novel designs in molecular architecture is a fundamental way to investigate how aspects of chemical and physical structure impact the transfection process. In this study, macromolecules comprised of a four-arm star poly(ethylene glycol) and termini modified with one of five different heparin binding peptides have been investigated for their ability to bind, compact, and deliver DNA to mammalian cells in vitro. These new delivery vectors combine a PEG-derived stabilizing moiety with peptides that exhibit unique cell-surface binding ability in a molecular architecture that permits multivalent presentation of the cationic peptides. Five peptide sequences of varying heparin binding affinity were studied; each was found to sufficiently bind heparin for biological application. Additionally, the macromolecules were able to bind and compact DNA into particles of proper size for endocytosis. In biological studies, the PEG-star peptides displayed a range of toxicity and transfection efficiency dependent on the peptide identity. The vectors equipped with peptides of highest heparin binding affinity were found to bind DNA tightly, increase levels of cellular internalization, and display the most promising transfection qualities. Our results suggest heparin binding peptides with specific sequences hold more potential than nonspecific cationic polymers to optimize transfection efficiency while maintaining cell viability. Furthermore, the built-in multivalency of these macromolecules may allow simultaneous binding of both DNA at the core of the polyplex and heparan sulfate on the surface of the cell. This scheme may facilitate a bridging transport mechanism, tethering DNA to the surface of the cell and subsequently ushering therapeutic nucleic acids into the cell. This multivalent star shape is therefore a promising architectural feature that may be exploited in the design of future polycationic gene delivery vectors.     

A physicochemical approach for predicting the effectiveness of peptide-based gene delivery systems for use in plasmid-based gene therapy.

Novel synthetic peptides, based on carrier peptide analogs (YKAKnWK) and an amphipathic peptide (GLFEALLELLESLWELLLEA), have been formulated with DNA plasmids to create peptide-based gene delivery systems. The carrier peptides are used to condense plasmids into nanoparticles with a hydrodynamic diameter (DH) ranging from 40 to 200 nm, which are sterically stable for over 100 h. Size and morphology of the carrier peptide/plasmid complex have been determined by photon correlation spectroscopy (PCS) and transmission electron microscopy (TEM), respectively. The amphipathic peptide is used as a pH-sensitive lytic agent to facilitate release of the plasmid from endosomes after endocytosis of the peptide/plasmid complex. Hemolysis assays have shown that the amphipathic peptide destabilizes lipid bilayers at low pH, mimicking the properties of viral fusogenic peptides. However, circular dichroism studies show that unlike the viral fusion peptides, this amphipathic peptide loses some of its alpha-helical structure at low pH in the presence of liposomes. The peptide-based gene delivery systems were tested for transfection efficiency in a variety of cell lines, including 14-day C2C12 mouse myotubes, using gene expression systems containing the beta-galactosidase reporter gene. Transfection data demonstrate a correlation between in vitro transfection efficiency and the combination of several physical properties of the peptide/plasmid complexes, including 1) DNA dose, 2) the zeta potential of the particle, 3) the requirement of both lytic and carrier peptides, and 4) the number of lysine residues associated with the carrier peptide. Transfection data on 14-day C2C12 myotubes utilizing the therapeutic human growth hormone gene formulated in an optimal peptide gene delivery system show an increase in gene expression over time, with a maximum in protein levels at 96 h (approximately 18 ng/ml).     

Bombesin/oligoarginine fusion peptides for gastrin releasing peptide receptor (GRPR) targeted gene delivery

The development of non-viral gene delivery systems, with the capacity to overcome most of the biological barriers facing gene delivery, is challenging. We have developed peptide-based, multicomponent, non-viral delivery systems, incorporating: a bombesin peptide ligand (BBN(6–14)), to selectively target the gastrin releasing peptide receptor (GRPR); oligoarginine peptides (hexa- (R₆) and nona-arginine (R₉)), for plasmid DNA (pDNA) condensation; and GALA, to facilitate endosome escape. The uptake and endosome escape efficiency of bombesin/oligoarginine and bombesin/oligoarginine/GALA fusion peptides for oligonucleotide delivery was evaluated in terms of their complex size, cellular uptake, endosome escape, and cellular toxicity. Complex size and cell uptake studies demonstrated that the nona-arginine/bombesin delivery system was more efficient at condensing and delivering pDNA into PC-3 prostate cancer cells compared to the hexa-arginine/bombesin delivery system. Further, competition with free bombesin peptide, and comparative uptake studies in Caco-2 cells, which express GRPR at a lower level, suggested that GRPR contributes to the targeted uptake of this system. The addition of GALA into the nona-arginine/bombesin-based system further increased the pDNA cellular uptake at all tested N/P ratios; facilitated endosomal pDNA release; and had limited effects on cell viability. In conclusion, the delivery system combining BBN(6–14) with nona-arginine and GALA had optimal characteristics for the delivery of pDNA into the GRPR overexpressing cell line PC-3.     

Medicinal chemistry of plasmid DNA with peptide nucleic acids: A new strategy for gene therapy

Summary In this chapter, we describe an approach using a peptide nucleic acid (PNA) clamp to directly and irreversibly modify plasmid DNA, without affecting either its supercoiled conformation or its ability to be efficiently transcribed. This strategy enables investigators to functionalize their gene of interest by direct coupling of ligands (fluorophores, peptide, proteins, sugars or oligonucleotides) to plasmid DNA. This approach provides versatile tools to study the mechanisms of gene delivery and to circumvent some of the main obstacles of synthetic gene delivery systems, such as specific targeting and efficient delivery. The proof-of-principal of PNA-dependent gene chemistry (PDGC) was demonstrated with a fluorescently labeled PNA that allowed generation of a highly fluorescent preparation of plasmid DNA that was functionally and conformationally intact. Fluorescent-PNA/DNA was used to identify critical parameters involved in naked DNA and non-viral gene delivery technology. The greatest potential of PDGC lies in the ability to attach specific ligands (e.g., peptides, proteins) to the plasmid DNA in order to overcome cellular barriers of non-viral gene delivery systems. In this regard, specific examples of ligands coupled to DNA are described and their effect on increasing the efficacy of gene therapy is presented     

Investigation of the sequence and length dependence for cell-penetrating prenylated peptides

Cell penetrating peptides are useful delivery tools for introducing molecules of interest into cells. A new class of cell penetrating molecules has been recently reported—cell penetrating, prenylated peptides. In this study a series of such peptides was synthesized to examine the relationship between peptide sequence and level of peptide internalization and to probe their mechanism of internalization. This study revealed that prenylated peptides internalize via a non-endocytotic pathway regardless of sequence. Sequence length and identity was found to play a role in peptide uptake but prenylated sequences as short as two amino acids were found to exhibit significant cell penetrating properties.     

Gene Delivery to Tobacco Root Cells with Single-Walled Carbon Nanotubes and Cell-Penetrating Fusogenic Peptides

Development of efficient, easy, and safe gene delivery methods is of great interest in the field of plant biotechnology. Considering the limitations of the usual transfection methods (such as transgene size and plant type), several new techniques have been tested for replacement. The success of some biological and synthetic nanostructures such as cell-penetrating peptides and carbon nanotubes in transferring macromolecules (proteins and nucleic acids) into mammalian cells provoked us to assess the ability of an engineered chimeric peptide and also arginine functionalized single-walled carbon nanotube in gene delivery to intact tobacco (Nicotiana tabacum var. Virginia) root cells. It was suggested that the engineered peptide with its special cationic and hydrophobic domains and the arginine functionalized single-walled carbon nanotube due to its nano-cylindrical shape can pass plant cell barriers while plasmid DNA (which codes green fluorescent protein) has been condensed on them. The success of gene delivery to tobacco root cells was confirmed by fluorescence microscopy and western blotting analysis.     

A poly(ethylene) glycolylated peptide for ocular delivery compacts DNA into nanoparticles for gene delivery to post‐mitotic tissues in vivo

Background

We have previously shown that a novel synthetic peptide for ocular delivery (POD) can efficiently compact DNA and deliver it to cells in vitro. This observation prompted us to develop use of POD as a nonviral vector in vivo.

Methods

POD peptide was modified using poly(ethylene) glycol (PEG‐POD) and used to compact DNA into nanoparticles that were then analysed using electron microscopy, dynamic light scattering, and fluorescent labeling. Transfection efficiency and localization were determined 48 h post‐injection into the subretinal space of the mouse eye using luciferase and LacZ, respectively. Efficiency of ocular transfection was compared to two other PEGylated peptides: PEG‐TAT and PEG‐CK30.

Results

PEG‐POD can compact DNA and form discrete nanoparticles of approximately 136 nm that can penetrate and transduce the retinal pigment epithelium (RPE) in vivo. PEG‐POD significantly increased expression of plasmid DNA by 215‐fold, PEG‐TAT by 56.52‐fold, and PEG‐CK30 by 24.73‐fold relative to DNA injected alone. In all cases β‐galactosidase was observed primarily in the RPE layer after subretinal injection. Electrophysiological analyses of PEG‐POD transduced retina indicates an absence of PEG‐POD‐mediated toxicity. PEG‐POD can protect plasmid DNA from DNaseI digestion, resulting in significant transfection of the lung after intravenous injection in mice.

Conclusions

PEG‐POD was found to significantly increase gene delivery relative to both DNA alone and other pegylated peptides. These findings highlight the use of pegylated peptides, and specifically PEG‐POD, as novel gene delivery vectors. Copyright © 2009 John Wiley & Sons, Ltd.     

Imaging in solution of (Lys)(16)-containing bifunctional synthetic peptide/DNA nanoparticles for gene delivery

The physical properties of non-viral vector/DNA nanoparticles in physiological aqueous solution are poorly understood. A Fluid Particle Image Analyser (FPIA), normally used for analysis of industrial and environmental fluids, was used to visualise individual (Lys)(16)-containing peptide/DNA particles. Eight (Lys)(16)-containing synthetic peptides were used to generate peptide/DNA particles at a constant + to - charge ratio of 2.8:1 with 10 microg/ml of plasmid DNA in phosphate buffered saline. Dynamic Light Scattering (DLS) and gene delivery studies were also performed. We present the first images of non-viral vector/DNA nanoparticles in physiological aqueous solution, together with precise measurements of individual particle size and shape in solution and, for the first time, an accurate measure of particle number. Particle size and shape, particle number, and efficiency for gene delivery varied markedly with different peptides. Under standard conditions for in vitro gene delivery, we estimate approximately 60 peptide/DNA nanoparticles per target cell, each containing approximately 70,000 plasmids. This novel capacity to image individual vector/DNA nanoparticles in solution and to count them accurately will enable a more precise assessment of non-viral gene delivery systems, and a more quantitative interpretation of gene delivery experiments.     

Arginine-rich,cell penetrating peptide–anti-microRNA complexes decrease glioblastoma migration potential

MicroRNAs (miRNAs) are a class of gene regulators originating from non-coding endogenous RNAs. Altered expression, both up- and down-regulation, of miRNAs plays important roles in many human diseases. Correcting miRNA dysregulation by either inhibiting or restoring miRNA function may provide therapeutic benefit. However, efficient, nontoxic miRNA delivery systems are in need. Cell penetrating peptides (CPPs) have been widely exploited for protein, DNA, and RNA delivery. Few have examined CPP transfection efficiency with single stranded anti-miRNA. The R₈ peptide condensed both siRNA and anti-miRNA. Greater than 50% of cells had anti-miRNA/R₈ complexes associated and in these cells 68% of anti-miRNA escapes the endosome/lysosome. Single-stranded antisense miR-21 inhibitor (anti-miR-21) administered using the R₈ peptide elicited efficient downstream gene upregulation. Glioblastoma cell migration was inhibited by 25% compared to the negative control group. To our knowledge, this is the first demonstration of miRNA modulation with anti-miR-21/R₈ complexes, which has laid the groundwork for further exploring octaarginine as intracellular anti-miRNAs carrier.     

Exogenous and cell surface glycosaminoglycans alter DNA delivery efficiency of arginine and lysine homopeptides in distinctly different ways

Glycosaminoglycans (GAGs) expressed ubiquitously on the cell surface are known to interact with a variety of ligands to mediate different cellular processes. However, their role in the internalization of cationic gene delivery vectors such as liposomes, polymers, and peptides is still ambiguous and seems to be controlled by multiple factors. In this report, taking peptides as model systems, we show that peptide chemistry is one of the key factors that determine the dependence on cell surface glycosaminoglycans for cellular internalization and gene delivery. Arginine peptides and their complexes with plasmid DNA show efficient uptake and functional gene transfer independent of the cell surface GAGs. On the other hand, lysine peptides and complexes primarily enter through a GAG-dependent pathway. The peptide-DNA complexes also show differential interaction with soluble GAGs. In the presence of exogenous GAGs under certain conditions, arginine peptide-DNA complexes show increased transfection efficiency that is not observed with lysine. This is attributed to a change in the complex nature that ensures better protection of the compacted DNA in the case of arginine complexes, whereas the lysine complexes get destabilized under these conditions. The presence of a GAG coating also ensures better cell association of arginine complexes, resulting in increased uptake. Our results indicate that the role of both the cell surface and exogenous glycosaminoglycans in gene delivery is controlled by the nature of the peptide and its complex with DNA.     

A potent new class of reductively activated peptide gene delivery agents

A new class of peptide gene delivery agents were developed by inserting multiple cysteine residues into short (dp 20) synthetic peptides. Substitution of one to four cysteine residues for lysine residues in Cys-Trp-Lys(18) resulted in low molecular weight DNA condensing peptides that spontaneously oxidize after binding to plasmid DNA to form interpeptide disulfide bonds. The stability of cross-linked peptide DNA condensates increased in proportion to the number of cysteines incorporated into the peptide. Disulfide bond formation led to a decrease in particle size relative to control peptide DNA condensates and prevented dissociation of peptide DNA condensates in concentrated sodium chloride. Cross-linked peptide DNA condensates were 5-60-fold more potent at mediating gene expression in HepG2 and COS 7 cells relative to uncross-linked peptide DNA condensates. The enhanced gene expression was dependent on the number of cysteine residues incorporated, with a peptide containing two cysteines mediating maximal gene expression. Cross-linking peptides caused elevated gene expression without increasing DNA uptake by cells, suggesting a mechanism involving intracellular release of DNA triggered by disulfide bond reduction. The results establish cross-linking peptides as a novel class of potent gene delivery agents that enhance gene expression through a new mechanism of action.     

Crotamine mediates gene delivery into cells through the binding to heparan sulfate proteoglycans

Recently we have shown that crotamine, a toxin from the South American rattlesnake Crotalus durissus terrificus venom, belongs to the family of cell-penetrating peptides. Moreover, crotamine was demonstrated to be a marker of centrioles, of cell cycle, and of actively proliferating cells. Herein we show that this toxin at non-toxic concentrations is also capable of binding electrostatically to plasmid DNA forming DNA-peptide complexes whose stabilities overcome the need for chemical conjugation for carrying nucleic acids into cells. Interestingly, crotamine demonstrates cell specificity and targeted delivery of plasmid DNA into actively proliferating cells both in vitro and in vivo, which distinguishes crotamine from other known natural cell-penetrating peptides. The mechanism of crotamine penetration and cargo delivery into cells was also investigated, showing the involvement of heparan sulfate proteoglycans in the uptake phase, which is followed by endocytosis and peptide accumulation within the acidic endosomal vesicles. Finally, the permeabilization of endosomal membranes induced by crotamine results in the leakage of the vesicles contents to the cell cytosol.     

ZEBRA cell‐penetrating peptide as an efficient delivery system in Candida albicans

There is increasing interest in drug delivery systems, such as nanoparticles, liposomes, and cell‐penetrating peptides, for the development of new antimicrobial treatments. In this study, we investigated the transduction capacity of a carrier peptide derived from the Epstein–Barr virus ZEBRA protein in the pathogenic fungus Candida albicans. ZEBRA‐minimal domain (MD) was able to cross the cell wall and cell membrane, delivering eGFP to the cytoplasm. Uptake into up to 70% of the cells was observed within two hours, without toxicity. This new delivery system could be used in C. albicans as a carrier for different biological molecules including peptides, proteins, and nucleic acids. Thereby, in antifungal therapy, MD may carry promising bioactive fungal inhibitors that otherwise penetrate poorly into the cells. Furthermore, MD will be of interest for deciphering molecular pathways involving cell‐cycle control in yeast or signaling pathways. Short interfering peptides could be internalized using MD, providing new tools for the inhibition of metabolic or signaling cascades essential for the growth and virulence of C. albicans, such as yeast‐to‐hyphae transition, cell wall remodeling, stress signaling and antifungal resistance. These findings create new possibilities for the internalization of cargo molecules, with applications for both treatment and functional analyses.